The Delta, The Ramp, The Stretch and The Duck #1

I gave a guest lecture at Birkbeck College, of the University of London on the evening of 22nd February 2017 in the evening, as part of the Energy and Climate Change module. I titled it, “Renewable Gas for Energy Storage : Scaling up the ‘Gas Battery’ to balance Wind and Solar Power and provide Low Carbon Heat and Transport”.

The basic concept is that since wind and solar power are variable in output, there has to be some support from other energy technologies. Some talk of batteries to store electrical energy as a chemical potential, and when they talk of batteries they think of large Lithium ion piles, or flow batteries, or other forms of liquid electrolyte with cathodes and anodes. When I talk about batteries, I think of electrical energy stored in the form of a gas. This gas battery doesn’t need expensive metal cathodes or anodes, and it doesn’t need an acid liquid electrolyte to operate. Gas that is synthesised from excess solar or wind power can be a fuel that can be used in chemical reactions, such as combustion, or burning, to generate electricity and heat when desired at some point in the future. It could be burned in a gas turbine, a gas boiler or a fuel cell, or in a vehicle engine. Or instead, a chemically inert gas can be stored under pressure, and this compressed gas can also be used to generate power on demand at a later date by harnessing energy from decompression. Another option would be holding a chemically reactive gas under pressure, allowing two stages of energy recovery.

As expected, the Birkbeck audience was very diverse, and had different social and educational backgrounds, and so there was little that could be assumed as common knowledge, especially since the topic was energy, which is normally only an interest for engineers, or at a stretch, economists.

I decided when preparing that I would attempt to use symbolism as a tool to build a narrative in the presentation. A bold move, perhaps, but I found it created an emblematic thread that ran through the slides quite nicely, and helped me tell the story. I used Mathematical and Physical notation, but I didn’t do any Mathematics or Physics.

I introduced the first concept : the Delta, or change. I explained this delta was not the same as a river delta, which gave me the excuse to show a fabulous night sky image of the Nile Delta taken from the International Space Station. I demonstrated the triangle shape that emerges from charting data that changes over time, and calculating its gradient, such as the temperature of the Earth’s surface.

I explained that the change in temperature of the Earth’s surface over the recent decades is an important metric to consider, not just in terms of scale, but in terms of speed. I showed that this rate of change appears in all the independent data sets.

I then went on to explain that the overall trend in the change in the temperature of the Earth’s surface is not the only phenomenon. Within regions, and within years and seasons, even between months and days, there are smaller scale changes that may not look like the overall delta. A lot of these changes give the appearance of cyclic phenomena, and they can have a periodicity of up to several decades, for example, “oscillations” in the oceans.

These discrete deltas and cycles could, to a casual observer, mask underlying trends, especially as the deltas can be larger than the trends; so climatologists look at a large set of measurements of all kinds, and have shown that some deltas are one way only, and are not cycling.

Teasing out the trends in all of the observations is a major enterprise that has been accomplished by thousands of scientists who have reported to the IPCC, the Intergovernmental Panel on Climate Change, part of the UNFCCC, the United Nations Framework Convention on Climate Change. The Fifth Assessment Report is the most comprehensive yet, and shows that global warming is almost certainly ramping up – in other words, global warming is getting faster, or accelerating.

Many projections for the future of temperature changes at the Earth’s surface have been done, with the overall view that temperatures are likely to carry on rising for hundreds of years without an aggressive approach to curtail net greenhouse gas emissions to the atmosphere – principally carbon dioxide (CO2), methane (CH4) and nitrous oxide (N2O).

From observations, it is clear that global warming causes climate change, and that the rate of temperature change is linked to the rate of climate change. In symbols, this reads : delta T for temperature over t for time leads to, or implies, a delta C for climate over t for time. The fact that global warming and its consequential climate change are able to continue worsening under the current emissions profile means that climate change is going to affect humanity for a long stretch. It also means that efforts to rein in emissions will also need to extend over time.

I finished this first section of my presentation by showing a list of what I call “Solution Principles” :-

1. Delays embed and extend the problem, making it harder to solve. So don’t delay.

2. Solve the problem at least as fast as creating it.

3. For maximum efficiency, minimum cost, and maximum speed, re-deploy agents of the problem in its solution.

In other words, make use of the existing energy, transport, agriculture, construction and chemical industries in approaching answers to the imperative to address global warming and climate change.

JODI Oil and BP #7

I both love and loathe Geography at the same time. I squirm at the irregularities – not the Slartibartfastian squiggly coastlines – but the way that people of differing cultures, languages and political or religious adherences refuse to occupy territory neatly, and deny being categorised properly. Actually, no, that’s just a joke. I love diversity, and migration, and long may culture continue to evolve. I find the differing mental geographies of people intriguing – such as the rift between the climate change science community and those few shrill shills resisting climate change science; for some reason often the very same people ardently opposed to the deployment of renewable energy. How to communicate across psychological boundaries remains an ongoing pursuit that can be quite involving and rewarding sometimes, as the entrenched antis diminish in number, because of defections based on facts and logic. One day, I sense, sense will prevail, and that feels good.

So I like divergence and richness in culture, and I like the progress in communicating science. What I don’t like is trying to map things where there is so much temporal flux. The constantly rearranging list of Membership of the European Union, for one good and pertinent example; the disputes over territory names, sovereignty and belonginess. When it comes to Energy, things get even more difficult to map, as much data is proprietary (legally bound to a private corporation) or a matter of national security (so secret, not even the actual governments know it); or mythical (data invented on a whim, or guessed at, or out of date). And then you get Views – the different views of different organisations about which category of whatever whichever parties or materials belong to. In my struggle to try to understand petroleum crude oil production figures, I realised that different organiations have different ways of grouping countries, and even have different countries in similar-sounding groups.

So I decided that as a first step towards eliminating categorisation overlaps or omissions, I should establish my own geography which was flexible enough to accommodate the Views of others, and permit me to compare their data more knowingly. Here are my first versions :-

1. Country Regional Grouping
I have given up to three levels of geographical detail, and an alternative grouping for most of the main land masses. Here it is in Excel spreadsheet format (.XLS). And here it is as a Comma-Delimited text file (.CSV).

2. Country Regional Comparison
I have compared the definitions of territorial regions between the following organisations and agencies : JODI (Joint Organisations Data Initiative), BP plc (the international company formerly known as British Petroleum), OPEC (the Organization of Petroleum Exporting Countries), EIA (United States of America, Department of Energy, Energy Information Administration), IEA (International Energy Agency of the OECD Organisation for Economic Co-operation and Development) and the United Nations (UN). Here it is as an Excel spreadsheet (.XLS). And here it is as a Comma-Delimited text file (.CSV).

There are some differences. Surprisingly few, in fact, if you only consider countries with significant oil production. I did find quite a lot of spelling mistakes, however, even in documentation that I assume was partially machine-generated.

The result is that I can be fairly confident that if I separate out data for China, Mexico, Israel and Turkey and a few other less significant countries when I compare data sources, any large divergence in numbers will have to be down to the different ways that people count oil rather than the way they categorise territories.

Fields of Diesel Generators

Recently, I had a very helpful telephone conversation with somebody I shall call Ben – because that’s his name, obviously, so there’s no point in trying to camoflage that fact. It was a very positive conversation, with lots of personal energy from both parties – just the sort of constructive engagement I like.

Amongst a range of other things, we were batting about ideas for what could constitute a business model or economic case for the development of Renewable Gas production – whether Renewable Hydrogen or Renewable Methane. Our wander through the highways and byways of energy markets and energy policy led us to this sore point – that the National Grid is likely to resort to “fields of diesel generators” for some of its emergency backup for the power grid in the next few years – if new gas-fired power plants don’t get built. Various acronyms you might find in this space include STOR and BM.

Now, diesel is a very dirty fuel – so dirty that it appears to be impossible to build catalytic exhaust filters for diesel road vehicles that meet any of the air pollution standards and keep up fuel consumption performance. It’s not just VW that have had trouble meeting intention with faction – all vehicle manufacturers have difficulties balancing all the requirements demanded of them. Perhaps it’s time to admit that we need to ditch the diesel fuel itself, rather than vainly try to square the circle.

The last thing we really need is diesel being used as the fuel to prop up the thin margins in the power generation network – burned in essentially open cycle plant – incurring dirty emissions and a massive waste of heat energy. Maybe this is where the petrorefiners of Great Britain could provide a Renewable Gas alternative. Building new plant or reconfiguring existing plant for Renewable Gas production would obviously entail capital investment, which would create a premium price on initial operations. However, in the event of the National Grid requiring emergency electricity generation backup, the traded prices for that power would be high – which means that slightly more expensive Renewable Gas could find a niche use which didn’t undermine the normal economics of the market.

If there could be a policy mandate – a requirement that Renewable Gas is used in open cycle grid-balancing generation – for example when the wind dies down and the sun sets – then we could have fields of Renewable Gas generators and keep the overall grid carbon emissions lower than they would otherwise have been.

Both Ben and I enjoyed this concept and shared a cackle or two – a simple narrative that could be adopted very easily if the right people got it.

Renewable Gas – that’s the craic.

The Great Policy Reset

Everything in the UK world of energy hit a kind of slow-moving nightmare when the Department of Energy and Climate Change stopped replying to emails a few months ago, claiming they were officially ordered to focus on the “Spending Review” – as known as “The Cuts” – as ordered by George Osborne, Chancellor of Her Majesty’s Treasury.

We now know that this purdah will be terminated on 25th November 2015, when various public announcements will be made, and whatever surprises are in store, one thing is now for certain : all grapevines have been repeating this one word regarding British energy policy : “reset”.

Some are calling it a “soft reset”. Some are predicting the demise of the entire Electricity Market Reform, and all its instruments – which would include the Capacity Auction and the Contracts for Difference – which would almost inevitably throw the new nuclear power ambition into a deep dark forgettery hole.

A report back from a whispering colleague regarding the Energy Utilities Forum at the House of Lords on 4th November 2015 included these items of interest :-

“…the cost of battery power has dropped to 10% of its value of a few years ago. National Grid has a tender out for micro-second response back up products – everyone assumes this is aimed at batteries but they are agnostic … There will be what is called a “soft reset” in the energy markets announced by the government in the next few weeks – no one knows what this means but obviously yet more tinkering with regulations … On the basis that diesel fuel to Afghanistan is the most expensive in the world (true), it has to be flown in, it has been seriously proposed to fly in Small Modular Nuclear reactors to generate power. What planet are these people living on I wonder ? … A lot more inter connectors are being planned to UK from Germany, Belgium Holland and Norway I think taking it up to 12 GWe … ”

Alistair Phillips-Davies, the CEO of SSE (Scottish and Southern Energy), took part in a panel discussion at Energy Live News on 5th November 2015, in which he said that he was expecing a “reset” on the Electricity Market Reform (EMR), and that the UK Government were apparently focussing on consumers and robust carbon pricing. One view expressed was that the EMR could be moved away from market mechanisms. In other discussions, it was mentioned that the EMR Capacity Market Auction had focussed too much on energy supply, and that the second round would see a wider range of participants – including those offering demand side solutions.

Energy efficiency, and electricity demand profile flattening, were still vital to get progress on, as the power grid is going to be more efficient if it can operate within a narrower band of demand – say 30 to 40 GW daily, rather than the currently daily swing of 20 to 50 GW. There was talk of offering changing flexible, personal tariffs to smooth out the 5pm 17:00 power demand peak, as price signalling is likely to be the only way to make this happen, and comments were made about how many computer geeks would be needed to analyse all the power consumption data.

The question was asked whether the smart meter rollout could have the same demand smoothing effect as the Economy 7 tariff had in the past.

The view was expressed that the capacity market had not provided enough by way of long-term price signals – particularly for investment in low carbon energy. One question raised during the day was whether it wouldn’t be better just to set a Europe-wide price on carbon and then let markets and the energy industry decide what to put in place ?

So, in what ways could the British Government “reset” the Electricity Market Reform instruments in order to get improved results – better for pocket, planet and energy provision ? This is what I think :-

1. Keep the Capacity Mechanism for gas

The Capacity Mechanism was originally designed to keep efficient gas-fired power plants (combined cycle gas turbine, or CCGT) from closing, and to make sure that new ones were built. In the current power generation portfolio, more renewable energy, and the drive to push coal-fired power plants to their limits before they need to be closed, has meant that gas-fired generation has been sidelined, kept for infrequent use. This has damaged the economics of CCGT, both to build and to operate. This phenomenon has been seen all across Europe, and the Capacity Market was supposed to fix this. However, the auction was opened to all current power generators as well as investors in new plant, so inevitably some of the cash that was meant for gas has been snaffled up by coal and nuclear.

2. Deflate strike prices after maximum lead time to generation

No Contracts for Difference should be agreed without specifying a maximum lead time to initial generation. There is no good reason why nuclear power plants, for example, that are anticipated to take longer than 5 years to build and start generating should be promised fixed power prices – indexed to inflation. If they take longer than that to build, the power prices should be degressed for every year they are late, which should provide an incentive to complete the projects on time. These projects with their long lead times and uncertain completion dates are hogging all the potential funds for investment, and this is leading to inflexibility in planning.

3. Offer Negative Contracts for Difference

To try to re-establish a proper buildings insulation programme of works, projects should be offered an incentive in the form of contracts-for-energy-savings – in other words, aggregated heat savings from any insulation project should be offered an investment reward related to the size of the savings. This will not be rewarding energy production, but energy use reduction. Any tempering of gas demand will improve the UK’s balance of payments and lead to a healthier economy.

4. Abandon all ambition for carbon pricing

Trends in energy prices are likely to hold surprises for some decades to come. To attempt to set a price on carbon, as an aid to incentivising low carbon energy investment is likely to fail to set an appropriate investment differential in this environment of general energy pricing volatility. That is : the carbon price would be a market signal lost in a sea of other effects. Added to which, carbon costs are likely to be passed on to energy consumers before they would affect the investment decisions of energy companies.

A Partial Meeting of Engineering Minds

So I met somebody last week, at their invitation, to talk a little bit about my research into Renewable Gas.

I can’t say who it was, as I didn’t get their permission to do so. I can probably (caveat emptor) safely say that they are a fairly significant player in the energy engineering sector.

I think they were trying to assess whether my work was a bankable asset yet, but I think they quickly realised that I am nowhere near a full proposal for a Renewable Gas system.

Although there were some technologies and options over which we had a meeting of minds, I was quite disappointed by their opinions in connection with a number of energy projects in the United Kingdom.

Click to Read More !

Nuclear Power Is Not An Energy Policy

The British Government do not have an energy policy. They may think they have one, and they may regularly tell us that they have one, but in reality, they don’t. There are a number of elements of regulatory work and market intervention that they are engaged with, but none of these by itself is significant enough to count as a policy for energy. Moreover, all of these elements taken together do not add up to energy security, energy efficiency, decarbonisation and affordable energy.

What it takes to have an energy policy is a clear understanding of what is a realistic strategy for reinvestment in energy after the dry years of privatisation, and a focus on energy efficiency, and getting sufficient low carbon energy built to meet the Carbon Budget on time. Current British Government ambitions on energy are not realistic, will not attract sufficient investment, will not promote increased energy efficiency and will not achieve the right scale and speed of decarbonisation.

I’m going to break down my critique into a series of small chunks. The first one is a quick look at the numbers and outcomes arising from the British Government’s obsessive promotion of nuclear power, a fantasy science fiction that is out of reach, not least because the industry is dog-tired and motheaten.

Click to Read More !

Why Shell is Wrong

So, some people do not understand why I am opposed to the proposal for a price on carbon put forward by Royal Dutch Shell and their oil and gas company confederates.

Those who have been following developments in climate change policy and the energy sector know that the oil and gas companies have been proposing a price on carbon for decades; and yet little has been achieved in cutting carbon dioxide emissions, even though carbon markets and taxes have been instituted in several regions.

Supporters of pricing carbon dioxide emissions urge the “give it time” approach, believing that continuing down the road of tweaking the price of energy in the global economy will cause a significant change in the types of resources being extracted.

My view is that economic policy and the strengthening of carbon markets and cross-border carbon taxes cannot provide a framework for timely and major shifts in the carbon intensity of energy resources, and here’s a brief analysis of why.

1.   A price on carbon shifts the locus of action on to the energy consumer and investor

A price on carbon could be expected to alter the profitability of certain fossil fuel mining, drilling and processing operations. For example, the carbon dioxide emissions of a “tank of gas” from a well-to-wheel or mine-to-wheel perspective, could be made to show up in the price on the fuel station forecourt pump. Leaving aside the question of how the carbon tax or unit price would be applied and redistributed for the moment, a price on carbon dioxide emissions could result in fuel A being more expensive than fuel B at the point of sale. Fuel A could expect to fall in popularity, and its sales could falter, and this could filter its effect back up the chain of production, and have implications on the capital expenditure on the production of Fuel A, and the confidence of the investors in investing in Fuel A, and so the oil and gas company would pull out of Fuel A.

However, the business decisions of the oil and gas company are assumed to be dependent on the consumer and the investor. By bowing to the might god of unit price, Shell and its confederates are essentially arguing that they will act only when the energy consumers and energy investors act. There are problems with this declaration of “we only do what we are told by the market” position. What if the unit price of Fuel A is only marginally affected by the price on carbon ? What if Fuel A is regarded as a superior product because of its premium price or other marketing factors ? This situation actually exists – the sales of petroleum oil-based gasoline and diesel are very healthy, despite the fact that running a car on Natural Gas, biogas or electricity could be far cheaper. Apart from the fact that so many motor cars in the global fleet have liquid fuel-oriented engines, what else is keeping people purchasing oil-based fuels when they are frequently more costly than the alternative options ?

And what about investment ? Fuel A might become more costly to produce with a price on carbon, but it will also be more expensive when it is sold, and this could create an extra margin of profit for the producers of Fuel A, and they could then return higher dividends to their shareholders. Why should investors stop holding stocks in Fuel A when their rates of return are higher ?

If neither consumers nor investors are going to change their practice because Fuel A becomes more costly than Fuel B because of a price on carbon, then the oil and gas company are not going to transition out of Fuel A resources.

For Shell to urge a price on carbon therefore, is a delegation of responsibility for change to other actors. This is irresponsible. Shell needs to lead on emissions reduction, not insist that other people change.

2.   A price on carbon will not change overall prices or purchasing decsions

In economic theory, choices about products, goods and services are based on key factors such as trust in the supplier, confidence in the product, availability and sustainability of the service, and, of course, the price. Price is a major determinant in most markets, and artificially altering the price of a vital commodity will certainly alter purchasing decisions – unless, that is, the price of the commodity in question increases across the board. If all the players in the field start offering a more expensive product, for example, because of supply chain issues felt across the market, then consumers will not change their choices.

Now consider the global markets in energy. Upwards of 80% of all energy consumed in the global economy is fossil fuel-based. Putting a price on carbon will raise the prices of energy pretty much universally. There will not be enough cleaner, greener product to purchase, so most purchasing decisions will remain the same. Price differentiation in the energy market will not be established by asserting a price on carbon.

A key part of Shell’s argument is that price differentiation will occur because of a price on carbon, and that this will drive behaviour change, and yet there is nothing to suggest it could do that effectively.

3.   A price on carbon will not enable Carbon Capture and Storage

Athough a key part of Shell’s argument about a price on carbon is the rationale that it would stimulate the growth in Carbon Capture and Storage (CCS), it seems unlikely that the world will ever agree to a price on carbon that would be sufficient to stimulate significant levels of CCS. A price on carbon will be deemed to be high enough when it creates a difference in the marginal extra production cost of a unit of one energy resource compared to another. A carbon price can only be argued for on the basis of this optimisation process – after all – a carbon price will be expected to be cost-efficient, and not punitive to markets. In other words, carbon prices will be tolerated if they tickle the final cost of energy, but not if they mangle with it. However, CCS could imply the use of 20% to 45% extra energy consumption at a facility or plant. In other words, CCS would create a parasitic load on energy resources that is not slim enough to be supported by a cost-optimal carbon price.

Some argue that the technology for CCS is improving, and that the parasitic load of CCS at installations could be reduced to around 10% to 15% extra energy consumption. However, it is hard to imagine a price on carbon that would pay even for this. And additionally, CCS will continue to require higher levels of energy consumption which is highly inefficient in the use of resources.

Shell’s argument that CCS is vital, and that a price on carbon can support CCS, is invalidated by this simple analysis.

4.   Shell needs to be fully engaged in energy transition

Calling for a price on carbon diverts attention from the fact that Shell itself needs to transition out of fossil fuels in order for the world to decarbonise its energy.

Shell rightly says that they should stick to their “core capabilities” – in other words geology and chemistry, instead of wind power and solar power. However, they need to demonstrate that they are willing to act within their central business activities.

Prior to the explosion in the exploitation of deep geological hydrocarbon resources for liquid and gas fuels, there was an energy economy that used coal and chemistry to manufacture gas and liquid fuels. Manufactured gas could still replace Natural Gas, if there are climate, economic or technological limits to how much Natural Gas can be resourced or safely deployed. Of course, to meet climate policy goals, coal chemistry would need to be replaced by biomass chemistry, and significant development of Renewable Hydrogen technologies.

Within its own production facilities, Shell has the answers to meet this challenge. Instead of telling the rest of the world to change its economy and its behaviour, Shell should take up the baton of transition, and perfect its production of low carbon manufactured gas.

The Great Transition to Gas

Hello, hello; what have we here then ? Royal Dutch Shell buying out BG Group (formerly known as British Gas). Is this the start of the great transition out of petroleum oil into gas fuels ?

Volatile crude petroleum oil commodity prices over the last decade have played some undoubted havoc with oil and gas company strategy. High crude prices have pushed the choice of refinery feedstocks towards cheap heavy and immature gunk; influenced decisions about the choices for new petrorefineries and caused ripples of panic amongst trade and transport chiefs : you can’t keep the engine of globalisation ticking over if the key fuel is getting considerably more expensive, and you can’t meet your carbon budgets without restricting supplies.

Low crude commodity prices have surely caused oil and gas corporation leaders to break out into the proverbial sweat. Heavy oil, deep oil, and complicated oil suddenly become unprofitable to mine, drill and pump. Because the economic balance of refinery shifts. Because low commodity prices must translate into low end user refined product prices.

There maybe isn’t an ideal commodity price for crude oil. All the while, as crude oil commodity prices jump around like a medieval flea, the price of Natural Gas, and the gassy “light ends” of slightly unconventional and deep crude oil, stay quite cheap to produce and cheap to use. It’s a shame that there are so many vehicles on the road/sea/rails that use liquid fuels…all this is very likely to change.

Shell appear to be consolidating their future gas business by buying out the competition. Hurrah for common sense ! The next stage of their evolution, after the transition of all oil applications to gas, will be to ramp up Renewable Gas production : low carbon gas supplies will decarbonise every part of the economy, from power generation, to transport, to heating, to industrial chemistry.

This is a viable low carbon solution – to accelerate the use of renewable electricity – wind power and solar principally – and at the same time, transition the oil and gas companies to become gas companies, and thence to Renewable Gas companies.

UKERC : Gas by Design

Today I attended a meeting of minds.

It’s clear to me that the near-term and mid-term future for energy in the United Kingdom and the European Union will best be centred on Natural Gas and Renewable Electricity, and now the UK Energy Research Centre has modelled essentially the same scenario. This can become a common narrative amongst all parties – the policy people, the economists, the technologists, the non-governmental groups, as long as some key long-term de-carbonisation and energy security objectives are built into the plan.

The researchers wanted to emphasise from their report that the use of Natural Gas should not be a default option in the case that other strategies fail – they want to see a planned transition to a de-carbonised energy system using Natural Gas by design, as a bridge in that transition. Most of the people in the room found they could largely agree with this. Me, too. My only caveat was that when the researchers spoke about Gas-CCS – Natural Gas-fired power generation with Carbon Capture and Storage attached, my choice would be Gas-CCU – Natural Gas-fired power generation with Carbon Capture and Re-utilisation – carbon recycling – which will eventually lead to much lower emissions gas supply at source.

What follows is a transcription of my poorly-written notes at the meeting, so you cannot accept them as verbatim.

Jim Watson, UKERC = [JW]
Christophe McGlade, University College London (UCL) = [CM]
Mike Bradshaw, Warwick Business School = [MB]

[JW] Thanks to Matt Aylott. Live Tweeting #FutureOfGas. Clearly gas is very very important. It’s never out of the news. The media all want to talk about fracking… If we want to meet the 2 degrees Celsius target of the United Nations Framework Convention on Climate Change, how much can gas be a part of this ? Is Natural Gas a bridge – how long a ride will that gas bridge be ?

[CM] Gas as a bridge ? There is healthy debate about the Natural Gas contribution to climate change [via the carbon dioxide emissions from burning Natural Gas, and also about how much less in emissions there is from burning Natural Gas compared to burning coal]. The IPCC said that “fuel switching” from coal to gas would offer emissions benefits, but some research, notably McJeon et al. (2014) made statements that switching to Natural Gas cannot confer emissions benefits. Until recently, there have not been many disaggregated assessments on gas as a bridge. We have used TIAM-UCL. The world is divided into 16 regions. The “climate module” seeks to constrain the global temperature rise to 2 degrees Celsius. One of the outcomes from our model was that export volumes [from all countries] would be severaly impacted by maintaining the price indexation between oil and gas. [Reading from chart on the screen : exports would peak in 2040s]. Another outcome was that gas consumption is not radically affected by different gas market structures. However, the over indexation to the oil price may destroy gas export markets. Total exports of natural gas are higher under the 2 degrees Celsius scenario compared to the 4 degrees Celsius scenario – particularly LNG [Liquefied Natural Gas]. A global climate deal will support gas exports. There will be a higher gas consumption under a 2 degrees Celsius deal compared to unconstrained scenario [leading to a 4 degrees Celsius global temperature rise]. The results of our modelling indicate that gas acts as a bridge fuel out to 2035 [?] in both absolute and relative terms. There is 15% greater gas consumption in the 2 degrees Celsius global warming scenario than in the 4 degrees Celsius global warming scenario. Part of the reason is that under the 4 degrees Celsius scenario, Compressed Natural Gas vehicles are popular, but a lot less useful under the 2 degrees Celsius scenario [where hydrogen and other fuels are brought into play].

There are multiple caveats on these outcomes. The bridging period is strictly time-limited. Some sectors need to sharply reduce consumption [such as building heating by Natural Gas boilers, which can be achieved by mass insulation projects]. Coal must be curtailed, but coal-for-gas substitution alone is not sufficient. Need a convincing narrative about how coal can be curtailed. In an absence of a global binding climate deal we will get consumption increases in both coal and gas. In the model, gas is offsetting 15% of coal by 2020, and 85% by 2030. With Carbon Capture and Storage (CCS), gas’s role is drastically reduced – after 2025 dropping by 2% a year [of permitted gas use]. Not all regions of the world can use gas as a bridge. [Reading from the chart : with CCS, gas is a strong bridging fuel in the China, EU, India, Japan and South Korea regions, but without CCS, gas is only strong in China. With CCS, gas’s bridging role is good in Australasia, ODA presumably “Offical Development Assistance” countries and USA. Without CCS, gas is good for Africa, Australasia, EU, India, Japan, South Korea, ODA and USA.]

In the UK, despite the current reliance on coal, there is little scope to use it as a transition fuel. Gas is unlikely to be removed from UK energy system by 2050.

[Question from the floor] The logic of gas price indexation with the oil price ?

[CM] If maintain oil indexation, exports will reduce as countries turn more towards indigenous at-home production of gas for their domestic demand. This would not be completely counter-balanced by higher oil and therefore gas prices, which should stimulate more exports.

[Point from the floor] This assumes logical behaviour…

[Question from the floor] [Question about Carbon Capture and Storage (CCS)]

[CM] The model does anticipate more CCS – which permits some extra coal consumption [at the end of the modelling period]. Gas-CCS [gas-fired power generation with CCS attached] is always going to generate less emissions than coal-CCS [coal-fired power generation with CCS attached] – so the model prefers gas-CCS.

[to be continued…]

Contracts for Difference Risks

The UK Government’s Electricity Market Reform (EMR) is a moving feast, or “trough”, if you are of the opinion that any state subsidy is a subsidy too far. My, how people complained and complained about the Renewables Obligation (RO), perhaps one of the world’s best stimuli for pushing forward wind power development. Yes, some rich engineering firms and rich landowners got richer on the back of the RO. What do you expect ? The wealthy always leverage their capital. But at least the RO has produced some exceptional wind power generation numbers. In the period 2017 to 2018 however, the RO is set to be staged down and replaced by several elements in the EMR, most notably, the CfD or Contracts for Difference, otherwise affectionately and quite inaccurately described as the FiT CfD – Feed-in Tariff Contracts for Difference.

The basic plan for the CfD is to guarantee to new electricity generators, or old generators building new plant, a definite price on power sold, in order to ensure they can get debt and equity invested in their projects. However, this is a huge state intervention and potentially entirely scuppers the efforts to create a market in electricity. More dangerously, although the CfD is supposed to encourage the freeing up of capital to support new energy investment, it might fail in that, at least in the short-term, and it may even fail to make capital cheaper. This is due to the new kinds of risk associated with the CfD – particularly because of the long lead time from auction to allocation, and the cap on allocations. The CfD is designed to create project failures, it seems.

I recently attended an event hosted at the Queen Elizabeth II Conference Centre in Westminster in London, called Energy4PowerLive 2014 and managed by GMP. The first session I attended was in the RenewablesLive 2014 stream, and featured a panel discussion between Andrew Buglass from Royal Bank of Scotland (RBS), Philip Bazin of Triodos and Steve Hunter, Investment Director of Low Carbon.

What follows is not verbatim, and is based on my handwritten notes, and my handwriting is appalling, so that sometimes, even I cannot read it.

[ Andrew Buglass, Managing Director and Head of Energy, Royal Bank of Scotland (RBS) : “Financing CfD projects – initial impressions from a lender” ]

[You may have an interest in the actions of] RBS [heckle from the audience, “We own it !”]. We built our first renewable energy project in 1991 – an onshore wind turbine. Now we [have helped] finance 9 gigawatts of renewable energy. I have 15 minutes – only possible to scratch the surface of CfDs [Contracts for Difference – a subsidy under the UK Government Department of Energy and Climate Change (DECC) Electricity Market Reform (EMR))]. The EMR journey has been a very long one – four years. We have offered advice to the government – about the bankability of the policy. DECC have a different policy perspective – they are going over here [in this direction] whether or not… [Their aim was to] encourage new sources of investment debt and equity, [currently] not here in the UK. […] Matt Hancock, new [energy] minister […] £115 [billion ?] […]. Half of £100 billion needed by end of decade. The EMR framework is [intended] to bring in new sources of debt and equity – its ability to track that into the market. I’m not going to review whether the EMR will be successful. It’s a “Nought to Sixty” question [reference to how quickly it takes for cars to accelerate], how quickly is capital going to be delivered [getting up and running]. There will be a big step up in terms of work […] how are different counterparties [countersigning parties in the CfD contracts] responding ? Now is the time to deliver on the [practical economics] for those to decide whether to invest or not. Need to engage the ratings agencies – getting debt from bond markets – to convince Standard and Poor etc to convince […] The first projects are going to take a long time – cutting their teeth. Cost, availability, terms of debt. The risks that will [come into play] :

A. OFFTAKE RISK – BASIS RISK
[At the start of the EMR discussions] we highlighted that small generators found it hard to get PPAS [Power Purchase Agreements]. With the CfDs “lender of last resort” “offtaker of last resort” […] may support less strong balance sheets for PPAs. Great – because we need a lot more liquidity in PPAs. [However] the basis risks on the strike price compared to the reference price – if this is [changed, different] – a concern about whether they might be matching in the middle [and so conferring no benefit to having arranged the CfD]].

B. WHOLESALE PRICE RISK
In offshore wind – wild – the economics of generating. In onshore wind power, the wholesale price has less of a way to fall [because of many years of learning and maturing of supply chains etc].

C. INDEX INFLATION RISK
The CfDs are to be linked to CPI [Consumer Price Index] rather than the RPI [Retail Price Index]. This may seem like a not very important difference – but at the moment you cannot hedge against the CPI. […] we recommend RPI – linked to lock in. Can’t do that with CPI.

D. FORCE MAJEURE RISK
[Risk] especially during construction. The CfD does not pick up during construction – need to see [how this pans out].

E. CHANGE IN LAW (CIL) RISK
Twenty pages of the CIL clause – doesn’t seem to give you much protection – what is a “foreseeable change in law” ? Unless you’re a big utility you will not have been tracking [policy and legislation] for the last ten years. Big risk ? In the RO [Renewables Obligation], CIL risk was set to the offtaker. Law firms are going to really agonise [over this in the CfD].

F. LIFETIME MANAGEMENT RISK
Risk relating to managing CfD contract during its lifetime. There is a risk from the termination of a CfD – more than in the RO. May need to do more work to keep lender involved to manage termination risk.

Leads to a gloomy approach – in banking paying back on time is good – anything else is bad.

The EMR has cross-party support, but this is the most interventionist approach since the CEGB (Central Electricity Generating Board market). The politicians are saying “no, no, we’d never change anything” – from three parties. It would help if there were a public statement on that (I get calls about “too many turbines”). Initial projects will probably take longer to start than [under] RO. Collectively fund pragmatic solutions.

[ Philip Bazin, Head Project Finance Team, Triodos Bank : “Financing CfD projects – initial impressions from a different bank” ]

Triodos was established in 1980, and started in the UK in 1995 with the acquisition of Mercury […] Our portfolio in the UK is still relatively small. Over a third of the £500 million is in renewable energy. Our investment […] basis of positive social and environmental outcomes. […] Core lending of £1 to £15 million finance […] construction […] and up to 15 years [on loan repayment]. Smaller developers – best fit. The bank is almost becoming part of the supply chain in the bidding process. Give a forward fixed rate of interest. We’ve had to think about how we provide this derivative. Discussions with PPA providers. Feeling that most a lot of new players. The whole rush around CfD was quite unhelpful. We haven’t been engaging with any bidders for this round [of CfDs]. Our customers are small generators or community groups. Smaller projects are risk-averse and would [probably] use the RO instead of the CfD [for now]. These markets are going to find this new structure [offputting]. Not ideal if you’re a professional investor. [Andrew has explained the risks well] The biggest one for me is the risk of failing to achieve your LONGSTOP DATE [failure to start electricity generation by an agreed date], which would risk a termination [of the CfD subsidy agreement. This would destroy the economics of the whole project and therefore the investment]. What protections do you have as a sub-contractor ? Another point is about wayleaves. [If you can’t get your wayleaves in time…] Fundamentally, the [CfD] mechanism is bankable. [However] in trying to fix a problem it [may] have created a total mess. Don’t know if more capital will be going into projects.

[ Steve Hunter, Investment Director, Low Carbon : “CfDs from an equity perspective” ]

[Our business is in] Solar PV, Onshore wind, CSP in the Mediterranean area. We get there when project developer is doing land deals. We have a cradle-to-grave perspective. Land planning and grid access are major risks [and the guarantee of biomass feedstock for a biomass project]. The WHOLESALE POWER PRICE RISK – someone needs to take it. Your view depends on your equity horizon. For us, the two big changes [from the RO] are the introduction of the ALLOCATION RISK and the removal of the power price risk. Don’t know the budget for allocation. Only know one month before the [CfD] auction ! The government has not released [a budget] for “emerging technology”. Timing : doesn’t really work for solar. The idea of CfD versus RO for solar will not work. [It’s all down to the project lifecycle] – you could be waiting 14 or 15 months for a CfD allocation after making a bid, but grid connection deals are now closing in [at around 12 months – if you do not take up your grid connection permission, you will lose it]. At the moment there is no competition between technologies. Is there enough CfD set aside for offshore wind projects ? Yes. If CfDs are intended to deliver technology-neutral [energy mix] – it doesn’t yet. The REFERENCE PRICES for me are the significant risk. This is entirely new for CfDs. Because the CfD intended to bring lower cost of capital – there is an implication for return [on investment] to the investor. Government will set [the reference prices]. Government just released [for some technologies] – decreased [in a forward period]. The Government may have a very different view on forward power prices… These reference prices come out of the air [there seems to be no basis for them]. When is final not final ? When it comes from DECC. If consider 2018/2019 September, the tightest budget, you could afford 1,000 MW of offshore, [if there is a change in the reference price] you could only afford 700 MW. In the TEC Register from National Grid – download this – there is 1,000 to 1,200 MG in the pipeline onshore. If I was a wind developer with [grid] connection dates after the end of the RO, you can bet I’ve already bid [for a CfD allocation] already. The political risk of changing the RO. May be a small amount of solar – but anyway it’s too expensive. If the CfD is only to support onshore wind power – is it achieving its goals ? There will almost certainly be some modification [to the CfD or the reference prices ?]. Transparency ? Oversupply ? [Oversight ?] of setting reference prices. Increase in frequency of the CfD auction would be helpful. Would give developers more time to bid. Technologies like solar PV that could deliver large savings… If no large solar is built… They could put a minimum in [for the subsidy allocated to each technology] – more positive. CfD represents long-term support. If the industry drives down the cost of renewable energy, CfD gives us an infill fix on revenue. It will give that certainty to get debt [and equity] in. It may be the support mechanism we need in the long-term. It could be the support mechanism we need for renewable energy…

Who Likes Beer ?

First, Christian Figueres speaks at St Paul’s Cathedral, and then there’s a debate, and questions, and somebody says Capitalism needs to be reformed or we’re not going to get any proper change. Half the people in the room sigh. “The last thing we need now is an obsessive compulsive revolutionary Marxist”, I hear somebody thinking.

Then, no surprise, Prince Charles comes out in favour of compassionate capitalism. That’s kind of like asking people to be nice to puppies, and about as realistic call for change as wanting the Moon to be actually made of cheese. As if focusing all our efforts and energy on repairing an already-breaking machine of trade with its destructive exploitation of resources and labour is going to stop climate change. Really. What actually needs to happen is that we address carbon emissions. If we cannot measure a reduction in carbon dioxide emissions, or count new trees, we are getting nowhere, fast. The Holy Economy can go hang if we don’t address Climate Change, and it will, because Climate Change is already sucking the lifeblood out of production and trade.

The non-governmental organisations – the charities, aid and development agencies and the like, do not know how to deal with climate change. They cannot simply utilise their tools of guilt to prise coins from peoples’ clenched hands and put the money towards something helpful. Well, they can, and they do, and you better watch out for more poor, starving African type campaigning, because programmes for adaptation to climate change are important, and I’ve never said they’re not, but they don’t address mitigation – the preventing of climate change. Well, some can, such as the project for smokeless, efficient ovens, but that’s not the point here. The point is that Christian Aid, for example, calling on us all to be “Hungry for Justice” isn’t addressing the central problem – the mass use of fossil fuels and deforestation in the name of economic development.

People are talking in hushed, reverential tones about Make Climate History. The way that Make Poverty History worked was a bunch of parliamentary people, and government people, sat down together and worked out how to get shows of public support for the government’s calls to the G8. The appeal to the masses was principally divided into two kinds – messages calling for people to support the government, and messages calling for people to urge, shout, rail, demonstrate to the government that they wanted these things. So, if you were in the first group you were showing support for what you thought was a good thing, and if you were in the second group, you were using all your righteous anger to force the government to take up the cause of the poor. The NGOs merely repeated these messages out on the wires. People spent a lot of time and energy on taking these messages out to various communities, who then spent a lot of time and energy on public meetings, letter writing, postcard signing, rallying, marching, talking to their democratic representatives. But all of that activity was actually useless. The relationships that counted were the relationships between the governments, not between the governments and their NGOs. The NGOs were used to propagate a government initiative.

And now, they’re doing it again with climate change. Various parts of government, who have actually understood the science, and the economics, can see how it is in the best interests of the United Kingdom, and the European Union, of which we are a closely-connected part, to adopt strong carbon control policies. But they’re not content just to get on with it. No, they want all the politically active types to make a show of support. And so the communications begin. Apparently open consultative meetings are convened, but the agenda is already decided, and the messaging already written for you.

It reminds me of what happened with the Climate Marches. A truly independent strongly critical movement centred around the Campaign against Climate Change organised a demonstration of protest every year in London, leading people either from or to the American Embassy, as the USA was the most recalcitrant on taking action to control greenhouse gas emissions. This was an effective display of public feeling, as it irritated and scratched and annoyed. So it had to go. So, I Count was born, a project of Stop Climate Chaos. They organised events sometimes on the very same day as the Campaign against Climate Change, and their inclusive hippy message was all lovehearts and flowers and we wouldn’t hurt a fly type calls for change. In the run up to the Copenhagen Conference of the Parties (COP) of the United Nations Framework Convention on Climate Change (UNFCCC) Kyoto Protocol in late 2009, all the NGOs were pushing for energy to be concentrated on its outcome, but nobody who joined in the vigils, the pilgrimages or the marches had any chance to make a real input. We were just the feather boa on the cake. We were even ejected from the building.

All this energy expended was a complete waste of time. With climate change, the relationships that count are between the governments and the energy industry. The NGOs may rant and rail in their toothless, fangless, clawless way about energy industry infelicity, ignominy, ignorance and inflexibility, but the energy industry only cares about NGOs if they show any sign of rebellious insubordination, which might upset their shareholders.

The governments know what they need to do – they need to improve their relationships with their energy industries to come to an agreement about decarbonising the energy supply – ask them in the most non-nonsense, unavoidable, sisterly/brotherly way to diversify out of fossil fuels. It really doesn’t matter what the NGOs say or do.

Current climate change campaigning to the masses is analagous to walking into a student party and shouting above the noise, sorry, music, “Hands up, who likes beer ?” You might get some token drunken waves out of that, but nothing more.

People, I predict, are less likely to join in with a hunger strike than they are to like beer. And even if I did join the Climate Fast, it wouldn’t make a blind bit of difference to energy company behaviour or government policy.

Look, I’ve done my share of climate change actions. I’ve cut my personal energy use, I’ve given up ironing and vacuuming, for example. I’ve installed solar panels. I use the bus. I’ve taken part in the Great Scheme of Voluntary Behaviour Change – I, the energy consumer have shown my willingness to consume less and produce less greenhouse gas emissions. Now it’s time for other people to act.

Given half a chance, most of the British people would vote for climate – a decent, hardworking, sunshine-and-rain and rather moderate climate – and none of this extremist storms, floods and droughts scenario we’ve been suffering recently.

Yes, and more British people want renewable energy than voted in their Local Elections.

So why doesn’t the UK Government just get on with it – institute the proper Carbon Budget at home, continue to ask for decent decarbonisation targets abroad, and leave all the compassionate caring people to devote themselves to causes that they stand a chance of impacting ?

On Not Setting The Proper Tone

So, I turned up for a national Climate Change campaigning and lobbying day some years ago. I had offered to steward at the event. My attire concerned one of those close to the organising team. After all, there were Members of Parliament due to attend, and Gentlemen and Ladies of the Press. “I don’t think it’s quite setting the right tone.” she commented.

Well, I want to know what the right tone is, exactly. And I don’t think anybody else does, either. How do we make change happen ? Really ?

I’ve just received another email missive from The Climate Coalition asking me to Tweet tomorrow about the Carbon Budget.

“As you may remember, back in 2011 we successfully fought for the government to deliver on its climate targets by adopting the Committee on Climate Change’s (CCC) recommendations on the 4th Carbon Budget…”

I mean, that’s a bit of a claim to start with. I very much doubt that anything that the Climate Coalition (or Stop Climate Chaos, as they were known in 2011) did had any bearing on the UK Government’s policy- or decision-making.

“…That decision is currently up for review and we need to make sure the government sticks to the ambition it showed 3 years ago, starting with a Twitter love in this Thursday.”

I beg your pardon ? How can The Climate Coalition make sure the UK Government does anything ? By Tweeting ? OK, so The Climate Coalition is an umbrella organisation of over 40 organisations, ostensibly representing over 11 million people, but it doesn’t have any real political weight, or any serious influence with The Treasury, who are normally the ones resisting the development of the green economy.

“…We’ve heard rumours that this is currently being negotiated in government, with at least some arguing for weaker targets. We don’t know yet which way it’ll go, so David Cameron and Nick Clegg might just need a bit of support from us to make the right decision and stick to our current targets…”

So this is what it’s all about – a show of support for the UK Government !

So, tell me, why should I join in, exactly ? I won’t be having any kind of genuine impact. It’s just a token flag-waving exercise.

I know I’m not setting the right tone, here. I’m challenging the proposals for action from one of the country’s largest collective groups with a clear position about climate change. But that’s because it’s a washout – there is nothing to be gained by responding to this appeal to Tweet.

I mean, if they called for the whole 11 million people to do something actually meaningful, like withdraw their labour for one hour a day, or refuse to use household appliances for 8 hours a week, or all demand a meeting with the fossil fuel producing companies asking them what their plan is to decarbonise the energy supply, then I suppose that might be something worth trying.

But Tweeting ? In support of a Government decision that they ought to make anyway based on the existing Climate Change Law and the science ? Why would they need me to join in with them on that ?

This Too Will Fail

I will probably fail to make myself understood, yet again, but here goes…

The reasons the United Nations Climate Change process is failing are :-

1.   The wrong people are being asked to shoulder responsibility

It is a well-rumoured possibility that the fossil fuel industry makes sure it has sympathisers and lobbyists at the United Nations Framework Convention on Climate Change (UNFCCC) conferences. It is only natural that they should want to monitor proceedings, and influence outcomes. But interventions by the energy sector has a much wider scope. Delegates from the countries with national oil and gas companies are key actors at UNFCCC conferences. Their national interests are closely bound to their fossil fuel exports. Many other countries understand their national interest is bound to the success of energy sector companies operating within their borders. Still others have governments with energy policy virtually dictated by international energy corporations. Yet when the UNFCCC discusses climate change, the only obligations discussed are those of nations – the parties to any treaty are the governments and regimes of the world. The UNFCCC does not hold oil and gas (and coal) companies to account. BP and Shell (and Exxon and Chevron and Total and GDF Suez and Eni and so on) are not asked to make undertakings at the annual climate talks. Governments are hoped to forge a treaty, but this treaty will create no leverage for change; no framework of accountability amongst those who produce oil, gas and coal.

2.   The right people are not in the room

It’s all very well for Governments to commit to a treaty, but they cannot implement it. Yes, their citizens can make a certain amount of changes, and reduce their carbon emissions through controlling their energy consumption and their material acquisitions. But that’s not the whole story. Energy has to be decarbonised at source. There are technological solutions to climate change, and they require the deployment of renewable energy systems. The people who can implement renewable energy schemes should be part of the UNFCCC process; the engineering companies who make wind turbines, solar photovoltaic panels, the people who can build Renewable Gas systems. Companies such as Siemens, GE, Alstom. Energy engineering project companies. Chemical engineering companies.

3.   The economists are still in the building

In the United Kingdom (what will we call it if Scotland becomes independent ? And what will the word “British” then mean ?) the Parliament passed the Climate Change Act. But this legislation is meaningless without a means to implement the Carbon Budgets it institutes. The British example is just a minor parallel to the UNFCCC situation – how can a global climate treaty be made to work ? Most of the notions the economists have put forward so far to incentivise energy demand reduction and stimulate low carbon energy production have failed to achieve much. Carbon trading ! Carbon pricing ! All rather ineffective. Plus, there’s the residual notion of different treatment for developed and developing nations, which is a road to nowhere.

4.   Unilateral action is frowned upon

Apparently, since Climate Change is a global problem, we all have to act in a united fashion to solve it. But that’s too hard to ask, at least to start with. When countries or regions take it upon themselves to act independently, the policy community seem to counsel against it. There are a few exceptions, such as the C40 process, where individual cities are praised for independent action, but as soon as the European Community sets up something that looks like a border tax on carbon, that’s a no-no. Everybody is asked to be part of a global process, but it’s almost too hard to get anything done within this framework.

5.   Civil Society is hamstrung and tongue-tied

There is very little that people groups can achieve within the UNFCCC process, because there is a disconnect between the negotiations and practical action. The framework of the treaty discussions does not encompass the real change makers. The UNFCCC does not build the foundation for the architecture of a new green economy, because it only addresses itself to garnering commitments from parties that cannot fulfill them. Civil Society ask for an egg sandwich and they are given a sandy eggshell. If Civil Society groups call for technology, they are given a carbon credit framework. If they call for differential investment strategies that can discredit carbon dependency, they are given an opportunity to put money into the global adaptation fund.

Positively Against Negative Campaigning

How to organise a political campaign around Climate Change : ask a group of well-fed, well-meaning, Guardian-reading, philanthropic do-gooders into the room to adopt the lowest common denominator action plan. Now, as a well-fed, well-meaning, Guardian-reading (well, sometimes), philanthropic do-gooder myself, I can expect to be invited to attend such meetings on a regular basis. And always, I find myself frustrated by the outcomes : the same insipid (but with well-designed artwork) calls to our publics and networks to support something with an email registration, a signed postcard, a fistful of dollars, a visit to a public meeting of no consequence, or a letter to our democratic representative. No output except maybe some numbers. Numbers to support a government decision, perhaps, or numbers to indicate what kind of messaging people need in future.

I mean, with the Fair Trade campaign, at least there was some kind of real outcome. Trade Justice advocates manned stall tables at churches, local venues, public events, and got money flowing to the international co-operatives, building up the trade, making the projects happen, providing schooling and health and aspirations in the target countries. But compare that to the Make Poverty History campaign which was largely run to support a vain top-level political attempt to garner international funding promises for social, health and economic development. Too big to succeed. No direct line between supporting the campaign and actually supporting the targets. Passing round the hat to developed, industrialised countries for a fund to support change in developing, over-exploited countries just isn’t going to work. Lord Nicholas Stern tried to ask for $100 billion a year by 2020 for Climate Change adaptation. This has skidded to a halt, as far as I know. The economic upheavals, don’t you know ?

And here we are again. The United Nations Framework Convention on Climate Change (UNFCCC), which launched the Intergovernmental Panel on Climate Change (IPCC) reports on climate change, oh, so, long, ago, through the person of its most charismatic and approachable Executive Secretary, Christiana Figueres, is calling for support for a global Climate Change treaty in 2015. Elements of this treaty, being drafted this year, will, no doubt, use the policy memes of the past – passing round the titfer begging for a couple of billion squid for poor, hungry people suffering from floods and droughts; proposing some kind of carbon pricing/taxing/trading scheme to conjure accounting bean solutions; trying to implement an agreement around parts per million by volume of atmospheric carbon dioxide; trying to divide the carbon cake between the rich and the poor.

Somehow, we believe, that being united around this proposed treaty, few of which have any control over the contents of, will bring us progress.

What can any of us do to really have input into the building of a viable future ? Christiana – for she is now known frequently only by her first name – has called for numbers – a measure of support for the United Nations process. She has also let it be known that if there is a substantial number of people who, with their organisations, take their investments out of fossil fuels, then this could contribute to the mood of the moment. Those who are advocating divestment are yet small in number, and I fear that they will continue to be marginal, partly because of the language that is being used.

First of all, there are the Carbon Disclosers. Their approach is to conjure a spectre of the “Carbon Bubble” – making a case that investments in carbon dioxide-rich enterprises could well end up being stranded by their assets, either because of wrong assumptions about viable remaining resources of fossil fuels, or because of wrong assumptions about the inability of governments to institute carbon pricing. Well, obviously, governments will find it hard to implement effective carbon pricing, because governments are in bed with the energy industry. Politically, governments need to keep big industry sweet. No surprise there. And it’s in everybody’s interests if Emperor Oil and Prince Regent Natural Gas are still wearing clothes. In the minds of the energy industry, we still have a good four decades of healthy fossil fuel assets. Royal Dutch Shell’s CEO can therefore confidently say at a public AGM that There Is No Carbon Bubble. The Carbon Discloser language is not working, it seems, as any kind of convincer, except to a small core of the concerned.

And then there are the Carbon Voices. These are the people reached by email campaigns who have no real idea how to do anything practical to affect change on carbon dioxide emissions, but they have been touched by the message of the risks of climate change and they want to be seen to be supporting action, although it’s not clear what action will, or indeed can, be taken. Well-designed brochures printed on stiff recycled paper with non-toxic inks will pour through their doors and Inboxes. Tick it. Send it back. Sign it. Send it on. Maybe even send some cash to support the campaign. This language is not achieving anything except guilt.

And then there are the Carbon Divestors. These are extremely small marginal voices who are taking a firm stand on where their organisations invest their capital. The language is utterly dated. The fossil fuel industry are evil, apparently, and investing in fossil fuels is immoral. It is negative campaigning, and I don’t think it stands a chance of making real change. It will not achieve its goal of being prophetic in nature – bearing witness to the future – because of the non-inclusive language. Carbon Voices reached by Carbon Divestor messages will in the main refuse to respond, I feel.

Political action on Climate Change, and by that I mean real action based on solid decisions, often taken by individuals or small groups, has so far been under-the-radar, under-the-counter, much like the Fair Trade campaign was until it burst forth into the glorious day of social acceptability and supermarket supply chains. You have the cyclists, the Transition Towners, the solar power enthusiasts. Yet to get real, significant, economic-scale transition, you need Energy Change – that is, a total transformation of the energy supply and use systems. It’s all very well for a small group of Methodist churches to pull their pension funds from investments in BP and Shell, but it’s another thing entirely to engage BP and Shell in an action plan to diversify out of petroleum oil and Natural Gas.

Here below are my email words in my feeble attempt to challenge the brain of Britain’s charitable campaigns on what exactly is intended for the rallying cry leading up to Paris 2015. I can pretty much guarantee you won’t like it – but you have to remember – I’m not breaking ranks, I’m trying to get beyond the Climate Change campaigning and lobbying that is currently in play, which I regard as ineffective. I don’t expect a miraculous breakthrough in communication, the least I can do is sow the seed of an alternative. I expect I could be dis-invited from the NGO party, but it doesn’t appear to be a really open forum, merely a token consultation to build up energy for a plan already decided. If so, there are probably more important things I could be doing with my time than wasting hours and hours and so much effort on somebody else’s insipid and vapid agenda.

I expect people might find that attitude upsetting. If so, you know, I still love you all, but you need to do better.


[…]

A lot of campaigning over the last 30 years has been very negative and divisive, and frequently ends in psychological stalemate. Those who are cast as the Bad Guys cannot respond to the campaigning because they cannot admit to their supporters/employees/shareholders that the campaigners are “right”. Joe Average cannot support a negative campaign as there is no apparent way to make change happen by being so oppositional, and because the ask is too difficult, impractical, insupportable. [Or there is simply too much confusion or cognitive dissonance.]

One of the things that was brought back from the […] working group breakout on […] to the plenary feedback session was that there should be some positive things about this campaign on future-appropriate investment. I think […] mentioned the obvious one of saying effectively “we are backing out of these investments in order to invest in things that are more in line with our values” – with the implicit encouragement for fossil fuel companies to demonstrate that they can be in line with our values and that they are moving towards that. There was some discussion that there are no bulk Good Guy investment funds, that people couldn’t move investments in bulk, although some said there are. […] mentioned Ethex.

Clearly fossil fuel production companies are going to find it hard to switch from oil and gas to renewable electricity, so that’s not a doable we can ask them for. Several large fossil fuel companies, such as BP, have tried doing wind and solar power, but they have either shuttered those business units, or not let them replace their fossil fuel activities.

[…] asked if the [divestment] campaign included a call for CCS – Carbon Capture and Storage – and […] referred to […] which showed where CCS is listed in a box on indicators of a “good” fossil fuel energy company.

I questioned whether the fossil fuel companies really want to do CCS – and that they have simply been waiting for government subsidies or demonstration funds to do it. (And anyway, you can’t do CCS on a car.)

I think I said in the meeting that fossil fuel producer companies can save themselves and save the planet by adopting Renewable Gas – so methods for Carbon Capture and Utilisation (CCU) or “carbon recycling”. Plus, they could be making low carbon gas by using biomass inputs. Most of the kit they need is already widely installed at petrorefineries. So – they get to keep producing gas and oil, but it’s renewably and sustainably sourced with low net carbon dioxide emissions. That could be turned into a positive, collaborative ask, I reckon, because we could all invest in that, the fossil fuel companies and their shareholders.

Anyway, I hope you did record something urging a call to positive action and positive engagement, because we need the co-operation of the fossil fuel companies to make appropriate levels of change to the energy system. Either that, or they go out of business and we face social turmoil.

If you don’t understand why this is relevant, that’s OK. If you don’t understand why a straight negative campaign is a turn-off to many people (including those in the fossil fuel industry), well, I could role play that with you. If you don’t understand what I’m talking about when I talk about Renewable Gas, come and talk to me about it again in 5 years, when it should be common knowledge. If you don’t understand why I am encouraging positive collaboration, when negative campaigning is so popular and marketable to your core segments, then I will resort to the definition of insanity – which is to keep doing the same things, expecting a different result.

I’m sick and tired of negative campaigning. Isn’t there a more productive thing to be doing ?

There are no enemies. There are no enemies. There are no enemies.

——-

As far as I understand the situation, both the […] and […] campaigns are negative. They don’t appear to offer any positive routes out of the problem that could engage the fossil fuel companies in taking up the baton of Energy Change. If that is indeed the main focus of […] and […] efforts, then I fear they will fail. Their work will simply be a repeat of the negative campaigning of the last 30 years – a small niche group will take up now-digital placards and deploy righteous, holy social media anger, and that will be all.

Since you understand this problem, then I would suggest you could spend more time and trouble helping them to see a new way. You are, after all, a communications expert. And so you know that even Adolf Hitler used positive, convening, gathering techniques of propaganda to create power – and reserved the negative campaigning for easily-marginalised vulnerable groups to pile the bile and blame on.

Have a nicer day,

—–

The important thing as far as I understand it is that the “campaigning” organisations need to offer well-researched alternatives, instead of just complaining about the way things are. And these well-researched alternatives should not just be the token sops flung at the NGOs and UN by the fossil fuel companies. What do I mean ?

Well, let’s take Carbon Capture and Storage (CCS). The injection of carbon dioxide into old oil and gas caverns was originally proposed for Enhanced Oil Recovery (EOR) – that is – getting more oil and gas out the ground by pumping gas down there – a bit like fracking, but with gas instead of liquid. The idea was that the expense of CCS would be compensated for by the new production of oil and gas – however, the CCS EOR effect has shown to be only temporary. So now the major oil and gas companies say they support carbon pricing (either by taxation or trading), to make CCS move forward. States and federations have given them money to do it. I think the evidence shows that carbon pricing cannot be implemented at a sufficiently high level to incentivise CCS, therefore CCS is a non-answer. Why has […] not investigated this ? CCS is a meme, but not necessarily part of the carbon dioxide solution. Not even the UNFCCC IPCC reports reckon that much CCS can be done before 2040. So, why does CCS appear in the […] criteria for a “good” fossil fuel company ? Because it’s sufficiently weak as a proposal, and sufficiently far enough ahead that the fossil fuel companies can claim they are “capture ready”, and in the Good Book, but in reality are doing nothing.

Non-starters don’t just appear from fossil fuel companies. From my point of view, another example of running at and latching on to things that cannot help was the support of the GDR – Greenhouse Development Rights, of which there has been severe critique in policy circles, but the NGOs just wrote it into their policy proposals without thinking about it. There is no way that the emissions budgets set out in the GDR policy could ever get put into practice. For a start, there is no real economic reason to divide the world into developing and developed nations (Kyoto [Protocol]’s Annex I and Annex II).

If you give me some links, I’m going to look over your […] and think about it.

I think that if a campaign really wants to get anywhere with fossil fuel companies, instead of being shunted into a siding, it needs to know properly what the zero carbon transition pathways really are. Unequal partners do not make for a productive engagement, I reckon.

—–

I’m sorry to say that this still appears to be negative campaigning – fossil fuel companies are “bad”; and we need to pull our money out of fossil fuel companies and put it in other “good” companies. Where’s the collective, co-operative effort undertaken with the fossil fuel companies ? What’s your proposal for helping to support them in evolving ? Do you know how they can technologically transition from using fossil fuels to non-fossil fuels ? And how are you communicating that with them ?

——

They call me the “Paradigm Buster”. I’m not sure if “the group” is open to even just peeking into that kind of approach, let alone “exploring” it. The action points on the corporate agenda could so easily slip back into the methods and styles of the past. Identify a suffering group. Build a theory of justice. Demand reparation. Make Poverty History clearly had its victims and its saviours. Climate change, in my view, requires a far different treatment. Polar bears cannot substitute for starving African children. And not even when climate change makes African children starve, can they inspire the kind of action that climate change demands. A boycott campaign without a genuine alternative will only touch a small demographic. Whatever “the group” agrees to do, I want it to succeed, but by rehashing the campaigning strategies and psychology of the past, I fear it will fail. Even by adopting the most recent thinking on change, such as Common Cause, [it] is not going to surmount the difficulties of trying to base calls to action on the basis of us-and-them thinking – polar thinking – the good guys versus the bad guys – the body politic David versus the fossil fuel company Goliath. By challenging this, I risk alienation, but I am bound to adhere to what I see as the truth. Climate change is not like any other disaster, aid or emergency campaign. You can’t just put your money in the [collecting tin] and pray the problem will go away with the help of the right agencies. Complaining about the “Carbon Bubble” and pulling your savings from fossil fuels is not going to re-orient the oil and gas companies. The routes to effective change require a much more comprehensive structure of actions. And far more engagement that agreeing to be a flag waver for whichever Government policy is on the table. I suppose it’s too much to ask to see some representation from the energy industry in “the group”, or at least […] leaders who still believe in the fossil fuel narratives, to take into account their agenda and their perspective, and a readiness to try positive collaborative change with all the relevant stakeholders ?


All Kinds of Gas

Amongst the chink-clink of wine glasses at yesterday evening’s Open Cities Green Sky Thinking Max Fordham event, I find myself supping a high ball orange juice with an engineer who does energy retrofits – more precisely – heat retrofits. “Yeah. Drilling holes in Grade I Listed walls for the District Heating pipework is quite nervewracking, as you can imagine. When they said they wanted to put an energy centre deep underneath the building, I asked them, “Where are you going to put the flue ?””

Our attention turns to heat metering. We discuss cases we know of where people have installed metering underground on new developments and fitted them with Internet gateways and then found that as the rest of the buildings get completed, the meter can no longer speak to the world. The problems of radio-meets-thick-concrete and radio-in-a-steel-cage. We agree that anybody installing a remote wifi type communications system on metering should be obliged in the contract to re-commission it every year.

And then we move on to shale gas. “The United States of America could become fuel-independent within ten years”, says my correspondent. I fake yawn. It really is tragic how some people believe lies that big. “There’s no way that’s going to happen !”, I assert.

“Look,” I say, (jumping over the thorny question of Albertan syncrude, which is technically Canadian, not American), “The only reason there’s been strong growth in shale gas production is because there was a huge burst in shale gas drilling, and now it’s been shown to be uneconomic, the boom has busted. Even the Energy Information Administration is not predicting strong growth in shale gas. They’re looking at growth in coalbed methane, after some years. And the Arctic.” “The Arctic ?”, chimes in Party Number 3. “Yes,” I clarify, “Brought to you in association with Canada. Shale gas is a non-starter in Europe. I always think back to the USGS. They estimate that the total resource in the whole of Europe is a whole order of magnitude, that is, ten times smaller than it is in Northern America.” “And I should have thought you couldn’t have the same kind of drilling in Europe because of the population density ?”, chips in Party Number 3. “They’re going to be drilling a lot of empty holes,” I add, “the “sweet spot” problem means they’re only likely to have good production in a few areas. And I’m not a geologist, but there’s the stratigraphy and the kind of shale we have here – it’s just not the same as in the USA.” Parties Number 2 and 3 look vaguely amenable to this line of argument. “And the problems that we think we know about are not the real problems,” I out-on-a-limbed. “The shale gas drillers will probably give up on hydraulic fracturing of low density shale formations, which will appease the environmentalists, but then they will go for drilling coal lenses and seams inside and alongside the shales, where there’s potential for high volumes of free gas just waiting to pop out. And that could cause serious problems if the pressures are high – subsidence, and so on. Even then, I cannot see how production could be very high, and it’s going to take some time for it to come on-stream…” “…about 10 years,” says Party Number 2.

“Just think about who is going for shale gas in the UK,” I ventured, “Not the big boys. They’ve stood back and let the little guys come in to drill for shale gas. I mean, BP did a bunch of onshore seismic surveys in the 1950s, after which they went drilling offshore in the North Sea, so I think that says it all, really. They know there’s not much gas on land.” There were some raised eyebrows, as if to say, well, perhaps seismic surveys are better these days, but there was agreement that shale gas will come on slowly.

“I don’t think shale gas can contribute to energy security for at least a decade,” I claimed, “even if there’s anything really there. Shale gas is not going to answer the problems of the loss of nuclear generation, or the problems of gas-fired generation becoming uneconomic because of the strong growth in renewables.” There was a nodding of heads.

“I think,” I said, “We should forget subsidies. UK plc ought to purchase a couple of CCGTS [Combined Cycle Gas Turbine electricity generation units]. That will guarantee they stay running to load balance the power grid when we need them to. Although the UK’s Capacity Mechanism plan is in line with the European Union’s plans for supporting gas-fired generation, it’s not achieving anything yet.” I added that we needed to continue building as much wind power as possible, as it’s quick to put in place. I quite liked my radical little proposal for energy security, and the people I was talking with did not object.

There was some discussion about Green Party policy on the ownership of energy utilities, and how energy and transport networks are basically in the hands of the State, but then Party Number 2 said, “What we really need is consistency of policy. We need an Energy Bill that doesn’t get gutted by a change of administration. I might need to vote Conservative, because Labour would mess around with policy.” “I don’t know,” I said, “it’s going to get messed with whoever is in power. All those people at DECC working on the Electricity Market Reform – they all disappeared. Says something, doesn’t it ?”

I spoke to Parties Number 2 and 3 about my research into the potential for low carbon gas. “Basically, making gas as a kind of energy storage ?”, queried Party Number 2. I agreed, but omitted to tell him about Germany’s Power-to-Gas Strategy. We agreed that it would be at least a decade before much could come of these technologies, so it wouldn’t contribute immediately to energy security. “But then,” I said, “We have to look at the other end of this transition, and how the big gas producers are going to move towards Renewable Gas. They could be making decisions now that make more of the gas they get out of the ground. They have all the know-how to build kit to make use of the carbon dioxide that is often present in sour conventional reserves, and turn it into fuel, by reacting it with Renewable Hydrogen. If they did that, they could be building sustainability into their business models, as they could transition to making Renewable Gas as the Natural Gas runs down.”

I asked Parties Number 2 and 3 who they thought would be the first movers on Renewable Gas. We agreed that companies such as GE, Siemens, Alstom, the big engineering groups, who are building gas turbines that are tolerant to a mix of gases, are in prime position to develop closed-loop Renewable Gas systems for power generation – recycling the carbon dioxide. But it will probably take the influence of the shareholders of companies like BP, who will be arguing for evidence that BP are not going to go out of business owing to fossil fuel depletion, to roll out Renewable Gas widely. “We’ve all got our pensions invested in them”, admitted Party Number 2, arguing for BP to gain the ability to sustain itself as well as the planet.

David MacKay : Heating London

I took some notes from remarks made by Professor David MacKay, the UK Government’s Chief Scientific Advisor, yesterday, 1st May 2014, at an event entitled “How Will We Heat London ?”, held by Max Fordhams as part of the Green Sky Thinking, Open City week. I don’t claim to have recorded his words perfectly, but I hope I’ve captured the gist.


[David MacKay] : [Agreeing with others on the panel – energy] demand reduction is really important. [We have to compensate for the] “rebound effect”, though [where people start spending money on new energy services if they reduce their demand for their current energy services].

SAP is an inaccurate tool and not suitable for the uses we put it too :-
http://www.eden.gov.uk/planning-and-development/building-control/building-control-guidance-notes/sap-calculations-explained/
http://www.dimplex.co.uk/products/renewable_solutions/building_regulations_part_l.htm

Things seem to be under-performing [for example, Combined Heat and Power and District Heating schemes]. It would be great to have data. A need for engineering expertise to get in.

I’m not a Chartered Engineer, but I’m able to talk to engineers. I know a kilowatt from a kilowatt hour [ (Laughter from the room) ]. We’ve [squeezed] a number of engineers into DECC [the Department of Energy and Climate Change].

I’m an advocate of Heat Pumps, but the data [we have received from demonstration projects] didn’t look very good. We hired two engineers and asked them to do the forensic analysis. The heat pumps were fine, but the systems were being wrongly installed or used.

Now we have a Heat Network team in DECC – led by an engineer. We’ve published a Heat Strategy. I got to write the first three pages and included an exergy graph.

[I say to colleagues] please don’t confuse electricity with energy – heat is different. We need not just a green fluffy solution, not just roll out CHP [Combined Heat and Power] [without guidance on design and operation].

Sources of optimism ? Hopefully some of the examples will be available – but they’re not in the shop at the moment.

For example, the SunUp Heat Battery – works by having a series of chambers of Phase Change Materials, about the size of a fridge that you would use to store heat, made by electricity during the day, for use at night, and meet the demand of one home. [Comment from Paul Clegg, Senior Partner at Feilden Clegg Bradley Studios : I first heard about Phase Change Materials back in the 1940s ? 1950s ? And nothing’s come of it yet. ] Why is that a good idea ? Well, if you have a heat pump and a good control system, you can use electricity when it’s cheapest… This is being trialled in 10 homes.

Micro-CHP – [of those already trialled] definitely some are hopeless, with low temperature and low electricity production they are just glorified boilers with a figleaf of power.

Maybe Fuel Cells are going to deliver – power at 50% efficiency [of conversion] – maybe we’ll see a Fuel Cell Micro-Combined Heat and Power unit ?

Maybe there will be hybrid systems – like the combination of a heat pump and a gas boiler – with suitable controls could lop off peaks of demand (both in power and gas).

We have designed the 2050 Pathways Calculator as a tool in DECC. It was to see how to meet the Carbon Budget. You can use it as an energy security calculator if you want. We have helped China, Korea and others to write their own calculators.

A lot of people think CHP is green and fluffy as it is decentralised, but if you’re using Natural Gas, that’s still a Fossil Fuel. If you want to run CHP on biomass, you will need laaaaaarge amounts of land. You can’t make it all add up with CHP. You would need many Wales’-worth of bioenergy or similar ways to make it work.

Maybe we should carry on using boilers and power with low carbon gas – perhaps with electrolysis [A “yay !” from the audience. Well, me, actually]. Hydrogen – the the 2050 Calculator there is no way to put it back into the beginning of the diagram – but it could provide low carbon heat, industry and transport. At the moment we can only put Hydrogen into Transport [in the 2050 Calculator. If we had staff in DECC to do that… It’s Open Source, so if any of you would like to volunteer…

Plan A of DECC was to convert the UK to using lots of electricity [from nuclear power and other low carbon technologies, to move to a low carbon economy], using heat pumps at the consumer end, but there’s a problem in winter [Bill Watts of Max Fordham had already shown a National Grid or Ofgem chart of electricity demand and gas demand over the year, day by day. Electricity demand (in blue) fluctuates a little, but it pretty regular over the year. Gas demand (in red) however, fluctuates a lot, and is perhaps 6 to 10 times larger in winter than in summer.]

If [you abandon Plan A – “electrification of everything”] and do it the other way, you will need a large amount of Hydrogen, and a large Hydrogen store. Electrolysers are expensive, but we are doing/have done a feasibility study with ITM Power – to show the cost of electrolysers versus the cost of your wind turbines [My comment : but you’re going to need your wind turbines to run your electrolysers with their “spare” or “curtailed” kilowatt hours.]

[David Mackay, in questions from the floor] We can glue together [some elements]. Maybe the coming smart controls will help…can help save a load of energy. PassivSystems – control such things as your return temperature [in your Communal or District Heating]…instead of suing your heat provider [a reference to James Gallagher who has problems with his communal heating system at Parkside SE10], maybe you could use smart controls…

[Question] Isn’t using smart controls like putting a Pirelli tyre on a Ford Cortina ? Legacy of poor CHP/DH systems…

[David MacKay in response to the question of insulation] If insulation were enormously expensve, we wouldn’t have to be so enthusastic about it…We need a well-targeted research programme looking at deep retrofitting, instead of letting it all [heat] out.

[Adrian Gault, Committee on Climate Change] We need an effective Government programme to deliver that. Don’t have it in the Green Deal. We did have it [in the previous programmes of CERT and CESP], but since they were cancelled in favour of the Green Deal, it’s gone off a cliff [levels of insulation installations]. We would like to see an initiative on low cost insulation expanded. The Green Deal is not producing a response.

[Bill Watts, Max Fordham] Agree that energy efficiency won’t run on its own. But it’s difficult to do. Not talking about automatons/automation. Need a lot of pressure on this.

[Adrian Gault] Maybe a street-by-street approach…

[Michael Trousdell, Arup] Maybe a rule like you can’t sell a house unless you’ve had the insulation done…

[Peter Clegg] … We can do heat recovery – scavenging the heat from power stations, but we must also de-carbonise the energy supply – this is a key part of the jigsaw.

Fiefdom of Information

Sigh. I think I’m going to need to start sending out Freedom of Information requests… Several cups of tea later…


To: Information Rights Unit, Department for Business, Innovation & Skills, 5th Floor, Victoria 3, 1 Victoria Street, London SW1H OET

28th April 2014

Request to the Department of Energy and Climate Change

Re: Policy and Strategy for North Sea Natural Gas Fields Depletion

Dear Madam / Sir,

I researching the history of the development of the gas industry in the United Kingdom, and some of the parallel evolution of the industry in the United States of America and mainland Europe.

In looking at the period of the mid- to late- 1960s, and the British decision to transition from manufactured gas to Natural Gas supplies, I have been able to answer some of my questions, but not all of them, so far.

From a variety of sources, I have been able to determine that there were contingency plans to provide substitutes for Natural Gas, either to solve technical problems in the grid conversion away from town gas, or to compensate should North Sea Natural Gas production growth be sluggish, or demand growth higher than anticipated.

Technologies included the enriching of “lean” hydrogen-rich synthesis gas (reformed from a range of light hydrocarbons, by-products of the petroleum refining industry); Synthetic Natural Gas (SNG) and methane-“rich” gas making processes; and simple mixtures of light hydrocarbons with air.

In the National Archives Cmd/Cmnd/Command document 3438 “Fuel Policy. Presented to Parliament by the Minister of Power Nov 1967”, I found discussion on how North Sea gas fields could best be exploited, and about expected depletion rates, and that this could promote further exploration and discovery.

In a range of books and papers of the time, I have found some discussion about options to increase imports of Natural Gas, either by the shipping of Liquified Natural Gas (LNG) or by pipeline from The Netherlands.

Current British policy in respect of Natural Gas supplies appears to rest on “pipeline diplomacy”, ensuring imports through continued co-operation with partner supplier countries and international organisations.

I remain unclear about what official technological or structural strategy may exist to bridge the gap between depleting North Sea Natural Gas supplies and continued strong demand, in the event of failure of this policy.

It is clear from my research into early gas field development that depletion is inevitable, and that although some production can be restored with various techniques, that eventually wells become uneconomic, no matter what the size of the original gas field.

To my mind, it seems unthinkable that the depletion of the North Sea gas fields was unanticipated, and yet I have yet to find comprehensive policy statements that cover this eventuality and answer its needs.

Under the Freedom of Information Act (2000), I am requesting information to answer the following questions :-

1.   At the time of European exploration for Natural Gas in the period 1948 to 1965, and the British conversion from manufactured gas to Natural Gas, in the period 1966 to 1977, what was HM Government’s policy to compensate for the eventual depletion of the North Sea gas fields ?

2.   What negotiations and agreements were made between HM Government and the nationalised gas industry between 1948 and 1986; and between HM Government and the privatised gas industry between 1986 and today regarding the projections of decline in gas production from the UK Continental Shelf, and any compensating strategy, such as the development of unconventional gas resources, such as shale gas ?

3.   Is there any policy or strategy to restore the SNG (Synthetic Natural Gas) production capacity of the UK in the event of a longstanding crisis emerging, for example from a sharp rise in imported Natural Gas costs or geopolitical upheaval ?

4.   Has HM Government any plan to acquire the Intellectual Property rights to SNG production technology, whether from British Gas/Centrica or any other private enterprise, especially for the slagging version of the Lurgi gasifier technology ?

5.   Has HM Government any stated policy intention to launch new research and development into, or pilot demonstrations of, SNG ?

6.   Does HM Government have any clearly-defined policy on the production and use of manufactured gas of any type ? If so, please can I know references for the documents ?

7.   Does HM Government anticipate that manufactured gas production could need to increase in order to support the production of synthetic liquid vehicle fuels; and if so, which technologies are to be considered ?

Thank you for your attention to my request for information.

Regards,

jo.

On Having to Start Somewhere

In the last few weeks I have heard a lot of noble but futile hopes on the subject of carbon dioxide emissions control.

People always seem to want to project too far into the future and lay out their wonder solution – something that is just too advanced enough to be attainable through any of the means we currently have at our disposal. It is impossible to imagine how the gulf can be bridged between the configuration of things today and their chosen future solutions.

Naive civil servants strongly believe in a massive programme of new nuclear power. Head-in-the-clouds climate change consultants and engineers who should know otherwise believe in widespread Carbon Capture and Storage or CCS. MBA students believe in carbon pricing, with carbon trading, or a flat carbon tax. Social engineers believe in significant reductions in energy intensity and energy consumer behaviour change, and economists believe in huge cost reductions for all forms of renewable electricity generation.

To make any progress at all, we need to start where we are. Our economic system has strong emissions-dependent components that can easily be projected to fight off contenders. The thing is, you can’t take a whole layer of bricks out of a Jenga stack without severe degradation of its stability. You need to work with the stack as it is, with all the balances and stresses that already exist. It is too hard to attempt to change everything at once, and the glowing ethereal light of the future is just too ghostly to snatch a hold of without a firm grasp on an appropriate practical rather than spiritual guide.

Here’s part of an email exchange in which I strive for pragmatism in the face of what I perceive as a lack of realism.


To: Jo

I read your article with interest. You have focused on energy, whereas I
tend to focus on total resource. CCS does make sense and should be pushed
forward with real drive as existing power stations can be cleaned up with it
and enjoy a much longer life. Establishing CCS is cheaper than building new
nuclear and uses far less resources. Furthermore, CCS should be used on new
gas and biomass plants in the future.

What we are lacking at the moment is any politician with vision in this
space. Through a combination of boiler upgrades, insulation, appliance
upgrades and behaviour change, it is straight forward to halve domestic
energy use. Businesses are starting to make real headway with energy
savings. We can therefore maintain a current total energy demand for the
foreseeable future.

To service this demand, we should continue to eke out every last effective
joule from the current generating stock by adding cleansing kit to the dirty
performers. While this is being done, we can continue to develop renewable
energy and localised systems which can help to reduce the base load
requirement even further.

From an operational perspective, CCS has stagnated over the last 8 years, so
a test plant needs to be put in place as soon as possible.

The biggest issue for me is that, through political meddling and the
unintended consequences of ill-thought out subsidies, the market has been
skewed in such a way that the probability of a black-out next year is very
high indeed.

Green gas is invisible in many people’s thinking, but the latest House of
Lords Report highlighted its potential.

Vested interests are winning hands down in the stand-off with the big
picture!


From: Jo

What is the title of the House of Lords report to which you refer ?

Sadly, I am old enough to remember Carbon Capture and Storage (CCS)
the first time the notion went around the block, so I’d say that
progress has been thin for 30 years rather than 8.

Original proposals for CCS included sequestration at the bottom of the
ocean, which have only recently been ruled out as the study of global
ocean circulation has discovered more complex looping of deep and
shallower waters that originally modelled – the carbon dioxide would
come back up to the surface waters eventually…

The only way, I believe, that CCS can be made to work is by creating a
value stream from the actual carbon dioxide, and I don’t mean Enhanced
Oil Recovery (EOR).

And I also definitely do not mean carbon dioxide emissions pricing,
taxation or credit trading. The forces against an
investment-influencing carbon price are strong, if you analyse the
games going on in the various economic system components. I do not
believe that a strong carbon price can be asserted when major economic
components are locked into carbon – such as the major energy producers
and suppliers, and some parts of industry, and transport.

Also, carbon pricing is designed to be cost-efficient, as markets will
always find the lowest marginal pricing for any externality in fines
or charges – which is essentially what carbon dioxide emissions are.
The EU Emissions Trading Scheme was bound to deliver a low carbon
price – that’s exactly what the economists predicted in modelling
carbon pricing.

I cannot see that a carbon price could be imposed that was more than
5% of the base commodity trade price. At those levels, the carbon
price is just an irritation to pass on to end consumers.

The main problem is that charging for emissions does not alter
investment decisions. Just like fines for pollution do not change the
risks for future pollution. I think that we should stop believing in
negative charging and start backing positive investment in the energy
transition.

You write “You have focused on energy, whereas I tend to focus on
total resource.” I assume you mean the infrastructure and trading
systems. My understanding leads me to expect that in the current
continuing economic stress, solutions to the energy crisis will indeed
need to re-use existing plant and infrastructure, which is why I
think that Renewable Gas is a viable option for decarbonising total
energy supply – it slots right in to substitute for Natural Gas.

My way to “eke out every last effective joule from the current
generating stock” is to clean up the fuel, rather than battle
thermodynamics and capture the carbon dioxide that comes out the back
end. Although I also recommend carbon recycling to reduce the need for
input feedstock.

I completely agree that energy efficiency – cutting energy demand
through insulation and so on – is essential. But there needs to be a
fundamental change in the way that profits are made in the energy
sector before this will happen in a significant way. Currently it
remains in the best interests of energy production and supply
companies to produce and supply as much energy as they can, as they
have a duty to their shareholders to return a profit through high
sales of their primary products.

“Vested interests” have every right under legally-binding trade
agreements to maximise their profits through the highest possible
sales in a market that is virtually a monopoly. I don’t think this can
be challenged, not even by climate change science. I think the way
forward is to change the commodities upon which the energy sector
thrives. If products from the energy sector include insulation and
other kinds of efficiency, and if the energy sector companies can
continue to make sales of these products, then they can reasonably be
expected to sell less energy. I’m suggesting that energy reduction
services need to have a lease component.

Although Alistair Buchanan formerly of Ofgem is right about the
electricity generation margins slipping really low in the next few
winters, there are STOR contracts that National Grid have been working
on, which should keep the lights on, unless Russia turn off the gas
taps, which is something nobody can do anything much about – not BP,
nor our diplomatic corps, the GECF (the gas OPEC), nor the WTO.


Failing Narratives : Carbon Culprits

In the last few weeks I have attended a number of well-intentioned meetings on advances in the field of carbon dioxide emissions mitigation. My overall impression is that there are several failing narratives to be encountered if you make even the shallowest foray into the murky mix of politics and energy engineering.

As somebody rightly pointed out, no capitalist worth their share price is going to spend real money in the current economic environment on new kit, even if they have asset class status – so all advances will necessarily be driven by public subsidies – in fact, significant technological advance has only ever been accomplished by state support.

Disturbingly, free money is also being demanded to roll out decades-old low carbon energy technology – nuclear power, wind power, green gas, solar photovoltaics – so it seems to me the only way we will ever get appropriate levels of renewable energy deployment is by directed, positive public investment.

More to the point, we are now in an era where nobody at all is prepared to spend any serious money without a lucrative slap on the back, and reasons beyond reasons are being deployed to justify this position. For example, the gas-fired power plant operators make claims that the increase in wind power is threatening their profitability, so they are refusing to built new electricity generation capacity without generous handouts. This will be the Capacity Mechanism, and will keep gas power plants from being mothballed. Yes, there is data to support their complaint, but it does still seem like whinging and special pleading.

And the UK Government’s drooling and desperate fixation with new nuclear power has thrown the European Commission into a tizzy about the fizzy promises of “strike price” guaranteed sales returns for the future atomic electricity generation.

But here, I want to contrast two other energy-polity dialogues – one for developing an invaluable energy resource, and the other about throwing money down a hole.

First, let’s take the white elephant. Royal Dutch Shell has for many years been lobbying for state financial support to pump carbon dioxide down holes in the ground. Various oil and gas industry engineers have been selling this idea to governments, federal and sub-federal for decades, and even acted as consultants to the Civil Society process on emissions control – you just need to read the United Nations’ IPCC Climate Change Assessment Report and Special Report output to detect the filigree of a trace of geoengineering fingers scratching their meaning into global intention. Let us take your nasty, noxious carbon dioxide, they whisper suggestively, and push it down a hole, out of sight and out of accounting mind, but don’t forget to slip us a huge cheque for doing so. You know, they add, we could even do it cost-effectively, by producing more oil and gas from emptying wells, resulting from pumping the carbon dioxide into them. Enhanced Oil Recovery – or EOR – would of course mean that some of the carbon dioxide pumped underground would in effect come out again in the form of the flue gas from the combustion of new fossil fuels, but anyway…

And governments love being seen to be doing something, anything, really, about climate change, as long as it’s not too complicated, and involves big players who should be trustworthy. So, you get the Peterhead project picking up a fat cheque for a trial of Carbon Capture and Storage (CCS) in Scotland, and the sidestep hint that if Scotland decides to become independent, this project money could be lost…But this project doesn’t involve much of anything that is really new. The power station that will be used is a liability that ought to be closing now, really, according to some. And the trial will only last for ten years. There will be no EOR – at least – not in the public statements, but this plan could lead the way.

All of this is like pushing a fat kid up a shiny slide. Once Government take their greasy Treasury hands off the project, the whole narrative will fail, falling to an ignominious muddy end. This perhaps explains the underlying desperation of many – CCS is the only major engineering response to emissions that many people can think of – because they cannot imagine burning less fossil fuels. So this wobbling effigy has to be kept on the top of the pedestal. And so I have enjoyed two identical Shell presentations on the theme of the Peterhead project in as many weeks. CCS must be obeyed.

But, all the same, it’s big money. And glaring yellow and red photo opps. You can’t miss it. And then, at the other end of the scale of subsidies, is biogas. With currently low production volumes, and complexities attached to its utilisation, anaerobically digesting wastes of all kinds and capturing the gas for use as a fuel, is a kind of token technology to many, only justified because methane is a much stronger greenhouse gas than carbon dioxide, so it needs to be burned.

The subsidy arrangements for many renewable energy technologies are in flux. Subsidies for green gas will be reconsidered and reformulated in April, and will probably experience a degression – a hand taken off the tiller of driving energy change.

At an evening biogas briefing given by Rushlight this week, I could almost smell a whiff of despair and disappointment in the levels of official support for green gas. It was freely admitted that not all the planned projects around the country will see completion, not only because of the prevailing economic climate, but because of the vagaries of feedstock availability, and the complexity of gas cleaning regulations.

There was light in the tunnel, though, even if the end had not been reached – a new Quality Protocol for upgrading biogas to biomethane, for injection into the gas grid, has been established. You won’t find it on the official UK Goverment website, apparently, as it has fallen through the cracks of the rebranding to gov.uk, but here it is, and it’s from the Environment Agency, so it’s official :-

http://www.greengas.org.uk/pdf/biomethane-qp.pdf

http://www.r-e-a.net/news/rea-welcomes-environment-agencys-updated-anaerobic-digestion-quality-protocol

http://adbiogas.co.uk/2014/01/30/biomethane-qp-could-boost-renewable-gas-to-grid-market/
http://adbiogas.co.uk/2014/01/30/biomethane-quality-protocol-published/

Here’s some background :-

http://www.environment-agency.gov.uk/aboutus/wfo/epow/124111.aspx

To get some picture of the mess that British green energy policy is in, all you need do is take a glance at Germany and Denmark, where green gas is considered the “third leg of the stool”, stabilising renewable energy supply with easily-stored low carbon gas, to balance out the peaks and troughs in wind power and solar power provision.

Green gas should not be considered a nice-to-have minor addition to the solutions portfolio in my view. The potential to de-carbonise the energy gas supply is huge, and the UK are missing a trick here – the big money is being ladled onto the “incumbents” – the big energy companies who want to carry on burning fossil fuels but sweep their emissions under the North Sea salt cavern carpet with CCS, whilst the beer change is being reluctantly handed out as a guilt offering to people seeking genuinely low carbon energy production.

Seriously – where the exoplanet are we at ?

The General Lightness of Carbon Pricing

I was at a very interesting meeting this morning, entitled “Next Steps for Carbon Capture and Storage in the UK”, hosted by the Westminster Energy, Environment and Transport Forum :-

http://www.westminsterforumprojects.co.uk/forums/event.php?eid=713
http://www.westminsterforumprojects.co.uk/forums/agenda/CCS-2014-agenda.pdf

During the proceedings, there were liberal doses of hints at that the Chancellor of the Exchequer is about to freeze the Carbon Price Floor – the central functioning carbon pricing policy in the UK (since the EU Emissions Trading Scheme “isn’t working”).

All of the more expensive low carbon energy technologies rely on a progressively heavier price for carbon emissions to make their solutions more attractive.

Where does this leave the prospects for Carbon Capture and Storage in the 2030s ? Initial technology-launching subsidies will have been dropped, and the Contracts for Difference will have been ground down into obscurity. So how will CCS keep afloat ? It’s always going to remain more expensive than other technology options to prevent atmospheric carbon dioxide emissions, so it needs some prop.

What CCS needs is some Added Value. It will come partly from EOR – Enhanced Oil Recovery, as pumping carbon dioxide down depleting oil and gas fields will help stimulate a few percent of extra production.

But what will really make the difference is using carbon dioxide to make new fuel. That’s the wonder of Renewable Gas – it will be able to provide a valued product for capturing carbon dioxide.

This wasn’t talked about this morning. The paradigm is still “filter out the CO2 and flush it down a hole”. But it won’t stay that way forever. Sooner or later, somebody’s going to start mining carbon dioxide from CCS projects to make new chemicals and gas fuels. Then, who cares if there’s negative charging for emissions ? Or at what price ? The return on investment in carbon capture will simply bypass assumptions about needing to create a carbon market or set a carbon tax.

Gain in Transmission #2

Here is further email exchange with Professor Richard Sears, following on from a previous web log post.


From: Richard A. Sears
Date: 24 February 2014
To: Jo Abbess
Subject: Question from your TED talk

Jo,

I was looking back over older emails and saw that I had never responded to your note. It arrived as I was headed to MIT to teach for a week and then it got lost. Sorry about that.

Some interesting questions. I don’t know anybody working specifically on wind power to gas options. At one time Shell had a project in Iceland using geothermal to make hydrogen. Don’t know what its status is but if you search on hydrogen and Iceland on the Shell website I’m sure there’s something. If the Germans have power to gas as a real policy option I’d poke around the web for information on who their research partners are for this.

Here are a couple of high level thoughts. Not to discourage you because real progress comes from asking new questions, but there are some physical fundamentals that are important.

Direct air capture of anything using current technology is prohibitively expensive to do at scale for energy. More energy will be expended in capture and synthesis than the fuels would yield.

Gaseous fuels are problematic on their own. Gas doesn’t travel well and is difficult to contain at high energy densities as that means compressing or liquefying it. That doesn’t make anything impossible, but it raises many questions about infrastructure and energy balance. If we take the energy content of a barrel of oil as 1.0, then a barrel of liquefied natural gas is about 0.6, compressed natural gas which is typically at about 3600psi is around 0.3, and a barrel (as a measure of volume equal to 42 US gallons) of natural gas at room temperature and pressure is about 0.0015 (+/-). Also there’s a real challenge in storing and transporting gasses as fuel at scale, particularly motor fuel to replace gasoline and diesel.

While there is some spare wind power potential that doesn’t get utilized because of how the grid must be managed, I expect it is a modest amount of energy compared to what we use today in liquid fuels. I think what that means is that while possible, it’s more likely to happen in niche local markets and applications rather than at national or global scales.

If you haven’t seen it, a nice reference on the potential of various forms of sustainable energy is available free and online here. http://www.withouthotair.com/

Hope some of this helps.

Rich

Richard A. Sears
Consulting Professor
Department of Energy Resources Engineering
Stanford University


From: Jo Abbess
Date: 24 February 2014
To: Richard A. Sears

Dear Richard,

Many thanks for getting back to me. Responses are nice – even if they
are months late. As they say – better late than never, although with
climate change, late action will definitely be unwise, according to an
increasing number of people.

I have indeed seen the website, and bought and spilled coffee on the
book of Professor David MacKay’s “Sustainable Energy Without The Hot
Air” project. It is legendary. However, I have checked and he has only
covered alternative gas in a couple of paragraphs – in notes. By
contrast, he spent a long chapter discussing how to filter uranium out
of seawater and other nuclear pursuits.

Yet as a colleague of mine, who knows David better than I do, said to
me this morning, his fascination with nuclear power is rather naive,
and his belief in the success of Generation III and Generation IV
lacks evidence. Plus, if we get several large carbon dioxide
sequestration projects working in the UK – Carbon Capture and Storage
(CCS) – such as the Drax pipeline (which other companies will also
join) and the Shell Peterhead demonstration, announced today, then we
won’t need new nuclear power to meet our 4th Carbon Budget – and maybe
not even the 5th, either (to be negotiated in 2016, I hear) :-

http://www.heraldscotland.com/politics/referendum-news/peterhead-confirmed-for-carbon-capture-sitebut-its-not-a-bribe-says-ed-dave.1393232825

We don’t need to bury this carbon, however; we just need to recycle
it. And the number of ways to make Renewable Hydrogen, and
energy-efficiently methanate carbon monoxide and carbon dioxide with
hydrogen, is increasing. People are already making calculations on how
much “curtailed” or spare wind power is likely to be available for
making gas in 10 years’ time, and if solar power in the UK is
cranked/ramped up, then there will be lots of juicy cost-free power
ours for the taking – especially during summer nights.

Direct Air Capture of carbon dioxide is a nonsensical proposition.
Besides being wrong in terms of the arrow of entropy, it also has the
knock-on effect of causing carbon dioxide to come back out of the
ocean to re-equilibrate. I recently read a paper by climate scientists
that estimated that whatever carbon dioxide you take out of the air,
you will need to do almost all of it again.

Instead of uranium, we should be harvesting carbon dioxide from the
oceans, and using it to make gaseous and liquid fuels.

Gaseous fuels and electricity complement each other very well –
particularly in storage and grid balancing terms – there are many
provisions for the twins of gas and power in standards, laws, policies
and elsewhere. Regardless of the limitations of gas, there is a huge
infrastructure already in place that can store, pipe and use it, plus
it is multi-functional – you can make power, heat, other fuels and
chemicals from gas. In addition, you can make gas from a range of
resources and feedstocks and processing streams – the key quartet of
chemical gas species keep turning up : hydrogen, methane, carbon
monoxide and carbon dioxide – whether you are looking at the exhaust
from combustion, Natural Gas, industrial furnace producer gas,
biological decomposition, just about everywhere – the same four gases.

Energy transition must include large amounts of renewable electricity
– because wind and solar power are quick to build yet long nuclear
power lead times might get extended in poor economic conditions. The
sun does not always shine and the wind does not always blow (and the
tide is not always in high flux). Since demand profiles will never be
able to match supply profiles exactly, there will always be spare
power capacity that grids cannot use. So Power to Gas becomes the
optimal solution. At least until there are ways to produce Renewable
Hydrogen at plants that use process heat from other parts of the
Renewable Gas toolkit. So the aims are to recycle carbon dioxide from
gas combustion to make more gas, and recycle gas production process
heat to make hydrogen to use in the gas production process, and make
the whole lot as thermally balanced as possible. Yes. We can do that.
Lower the inputs of fresh carbon of any form, and lower the energy
requirements to make manufactured gas.

I met somebody working with Jacobs who was involved in the Carbon
Recycling project in Iceland. Intriguing, but an order of magnitude
smaller than I think is possible.

ITM Power in the UK are doing a Hydrogen-to-gas-grid and methanation
project in Germany with one of the regions. They have done several
projects with Kiwa and Shell on gas options in Europe. I know of the
existence of feasibility reports on the production of synthetic
methane, but I have not had the opportunity to read them yet…

I feel quite encouraged that Renewable Gas is already happening. It’s
a bit patchy, but it’s inevitable, because the narrative of
unconventional fossil fuels has many flaws. I have been looking at
issues with reserves growth and unconventionals are not really
commensurate with conventional resources. There may be a lot of shale
gas in the ground, but getting it out could be a long process, so
production volumes might never be very good. In the USA you’ve had
lots of shale gas – but that’s only been supported by massive drilling
programmes – is this sustainable ?

BP have just finished building lots of dollars of kit at Whiting to
process sour Natural Gas. If they had installed Renewable Gas kit
instead of the usual acid gas and sulfur processing, they could have
been preparing for the future. As I understand it, it is possible to
methanate carbon dioxide without first removing it from the rest of
the gas it comes in – so methanating sour gas to uprate it is a viable
option as far as I can see. The hydrogen sulfide would still need to
be washed out, but the carbon dioxide needn’t be wasted – it can be
made part of the fuel. And when the sour gas eventually thins out,
those now methanating sour gas can instead start manufacturing gas
from low carbon emissions feedstocks and recycled carbon.

I’m thinking very big.

Regards,

jo.

In Confab : Paul Elsner

Dr Paul Elsner of Birkbeck College at the University of London gave up some of his valuable time for me today at his little bijou garret-style office in Bloomsbury in Central London, with an excellent, redeeming view of the British Telecom Tower. Leader of the Energy and Climate Change module on Birkbeck’s Climate Change Management programme, he offered me tea and topical information on Renewable Energy, and some advice on discipline in authorship.

He unpacked the recent whirlwind of optimism surrounding the exploitation of Shale Gas and Shale Oil, and how Climate Change policy is perhaps taking a step back. He said that we have to accept that this is the way the world is at the moment.

I indicated that I don’t have much confidence in the “Shale Bubble”. I consider it mostly as a public relations exercise – and that there are special conditions in the United States of America where all this propaganda comes from. I said that there are several factors that mean the progress with low carbon fuels continues to be essential, and that Renewable Gas is likely to be key.

1. First of all, the major energy companies, the oil and gas companies, are not in a healthy financial state to make huge investment. For example, BP has just had the legal ruling that there will be no limit to the amount of compensation claims they will have to face over the Deepwater Horizon disaster. Royal Dutch Shell meanwhile has just had a serious quarterly profit warning – and if that is mostly due to constrained sales (“Peak Oil Demand”) because of economic collapse, that doesn’t help them with the kind of aggressive “discovery” they need to continue with to keep up their Reserves to Production ratio (the amount of proven resources they have on their books). These are not the only problems being faced in the industry. This problem with future anticipated capitalisation means that Big Oil and Gas cannot possibly look at major transitions into Renewable Electricity, so it would be pointless to ask, or try to construct a Carbon Market to force it to happen.

2. Secondly, despite claims of large reserves of Shale Gas and Shale Oil, ripe for the exploitation of, even major bodies are not anticipating that Peak Oil and Peak Natural Gas will be delayed by many years by the “Shale Gale”. The reservoir characteristics of unconventional fossil fuel fields do not mature in the same way as conventional ones. This means that depletion scenarios for fossil fuels are still as relevant to consider as the decades prior to horizontal drilling and hydraulic fracturing (“fracking”).

3. Thirdly, the reservoir characteristics of conventional fossil fuel fields yet to exploit, especially in terms of chemical composition, are drifting towards increasingly “sour” conditions – with sigificant levels of hydrogen sulfide and carbon dioxide in them. The sulphur must be removed for a variety of reasons, but the carbon dioxide remains an issue. The answer until recently from policy people would have been Carbon Capture and Storage or CCS. Carbon dioxide should be washed from acid Natural Gas and sequestered under the ocean in salt caverns that previously held fossil hydrocarbons. It was hoped that Carbon Markets and other forms of carbon pricing would have assisted with the payment for CCS. However, recently there has been reduced confidence that this will be significant.

Renewable Gas is an answer to all three of these issues. It can easily be pursued by the big players in the current energy provision system, with far less investment than wholesale change would demand. It can address concerns of gas resource depletion at a global scale, the onset of which could occur within 20 to 25 years. And it can be deployed to bring poor conventional fossil fuels into consideration for exploitation in the current time – answering regional gas resource depletion.

Outside, daffodils were blooming in Tavistock Square. In January, yes. The “freaky” weather continues…

But Uh-Oh – Those Summer Nights

A normal, everyday Monday morning at Energy Geek Central. Yes, this is a normal conversation for me to take part in on a Monday morning. Energy geekery at breakfast. Perfect.

Nuclear Flower Power

This whole UK Government nuclear power programme plan is ridiculous ! 75 gigawatts (GW) of Generation III nuclear fission reactors ? What are they thinking ? Britain would need to rapidly ramp up its construction capabilities, and that’s not going to happen, even with the help of the Chinese. (And the Americans are not going to take too kindly to the idea of China getting strongly involved with British energy). And then, we’d need to secure almost a quarter of the world’s remaining reserves of uranium, which hasn’t actually been dug up yet. And to cap it all, we’d need to have 10 more geological disposal repositories for the resulting radioactive spent fuel, and we haven’t even managed to negotiate one yet. That is, unless we can burn a good part of that spent fuel in Generation IV nuclear fission reactors – which haven’t even been properly demonstrated yet ! Talk about unconscionable risk !

Baseload Should Be History By Now, But…

Whatever the technological capability for nuclear power plants to “load follow” and reduce their output in response to a chance in electricity demand, Generation III reactors would not be run as anything except “baseload” – constantly on, and constantly producing a constant amount of power – although they might turn them off in summer for maintenance. You see, the cost of a Generation III reactor and generation kit is in the initial build – so their investors are not going to permit them to run them at low load factors – even if they could.

There are risks to running a nuclear power plant at partial load – mostly to do with potential damage to the actual electricity generation equipment. But what are the technology risks that Hinkley Point C gets built, and all that capital is committed, and then it only runs for a couple of years until all that high burn up fuel crumbles and the reactors start leaking plutonium and they have to shut it down permanently ? Who can guarantee it’s a sound bet ?

If they actually work, running Generation III reactors at constant output as “baseload” will also completely mess with the power market. In all of the scenarios, high nuclear, high non-nuclear, or high fossil fuels with Carbon Capture and Storage (CCS), there will always need to be some renewables in the mix. In all probability this will be rapidly deployed, highly technologically advanced solar power photovoltaics (PV). The amount of solar power that will be generated will be high in summer, but since you have a significant change in energy demand between summer and winter, you’re going to have a massive excess of electricity generation in summer if you add nuclear baseload to solar. Relative to the demand for energy, you’re going to get more Renewable Energy excess in summer and under-supply in winter (even though you get more offshore wind in winter), so it’s critical how you mix those two into your scenario.

The UK Government’s maximum 75 GW nuclear scenario comprises 55 GW Generation III and 20 GW Generation IV. They could have said 40 GW Gen III to feed Gen IV – the spent fuel from Gen III is needed to kick off Gen IV. Although, if LFTR took off, if they had enough fluoride materials there could be a Thorium way into Gen IV… but this is all so technical, no MP [ Member of Parliament ] is going to get their head round this before 2050.

The UK Government are saying that 16 GW of nuclear by 2030 should be seen as a first tranche, and that it could double or triple by 2040 – that’s one heck of a deployment rate ! If they think they can get 16 GW by 2030 – then triple that by 10 years later ? It’s not going to happen. And even 30 GW would be horrific. But it’s probably more plausible – if they can get 16 GW by 2030, they can arguably get double that by 2040.

As a rule of thumb, you would need around 10 tonnes of fissionable fuel to kickstart a Gen IV reactor. They’ve got 106 tonnes of Plutonium, plus 3 or 4 tonnes they recently acquired – from France or Germany (I forget which). So they could start 11 GW of Gen IV – possibly the PRISM – the Hitachi thing – sodium-cooled. They’ve been trying them since the Year Dot – these Fast Reactors – the Breeders – Dounreay. People are expressing more confidence in them now – “Pandora’s Promise” hangs around the narrative that the Clinton administration stopped research into Fast Reactors – Oak Ridge couldn’t be commercial. Throwing sodium around a core 80 times hotter than current core heats – you can’t throw water at it easily. You need something that can carry more heat out. It’s a high technological risk. But then get some French notable nuclear person saying Gen IV technologies – “they’re on the way and they can be done”.

Radioactive Waste Disposal Woes

The point being is – if you’re commissioning 30 GW of Gen III in the belief that Gen IV will be developed – then you are setting yourself up to be a hostage to technological fortune. That is a real ethical consideration. Because if you can’t burn the waste fuel from Gen III, you’re left with up to 10 radioactive waste repositories required when you can’t even get one at the moment. The default position is that radioactive spent nuclear fuel will be left at the power stations where they’re created. Typically, nuclear power plants are built on the coast as they need a lot of cooling water. If you are going for 30 GW you will need a load of new sites – possibly somewhere round the South East of England. This is where climate change comes in – rising sea levels, increased storm surge, dissolving, sinking, washed-away beaches, more extreme storms […] The default spent fuel scenario with numerous coastal decommissioned sites with radioactive interim stores which contain nearly half the current legacy radioactive waste […]

Based on the figures from the new Greenpeace report, I calculate that the added radioactive waste and radioactive spent fuel arisings from a programme of 16 GW of nuclear new build would be 244 million Terabequerel (TBq), compared to the legacy level of 87 million TBq.

The Nuclear Decommissioning Authority (NDA) are due to publish their Radioactive Waste Inventory and their Report on Radioactive Materials not in the Waste Inventory at the end of January 2014. We need to keep a watch out for that, because they may have adapted their anticipated Minimum and Maxmium Derived Inventory.

Politics Is Living In The Past

What you hear from politicians is they’re still talking about “baseload”, as if they’ve just found the Holy Grail of Energy Policy. And failed nuclear power. Then tidal. And barrages. This is all in the past. Stuff they’ve either read – in an article in a magazine at the dentist’s surgery waiting room, and they think, alright I’ll use that in a TV programme I’ve been invited to speak on, like Question Time. I think that perhaps, to change the direction of the argument, we might need to rubbish their contribution. A technological society needs to be talking about gasification, catalysis. If you regard yourselves as educated, and have a technological society – your way of living in the future is not only in manufacturing but also ideas – you need to be talking about this not that : low carbon gas fuels, not nuclear power. Ministers and senior civil servants probably suffer from poor briefing – or no briefing. They are relying on what is literally hearsay – informal discussions, or journalists effectively representing industrial interests. Newspapers are full of rubbish and it circulates, like gyres in the oceans. Just circulates around and around – full of rubbish.

I think part of the problem is that the politicians and chief civil servants and ministers are briefed by the “Old Guard” – very often the ex-nuclear power industry guard. They still believe in big construction projects, with long lead times and massive capital investment, whereas Renewable Electricity is racing ahead, piecemeal, and private investors are desperate to get their money into wind power and solar power because the returns are almost immediate and risk-free.

Together in Electric Dreams

Question : Why are the UK Government ploughing on with plans for so much nuclear power ?

1. They believe that a lot of transport and heat can be made to go electric.
2. They think they can use spent nuclear fuel in new reactors.
3. They think it will be cheaper than everything else.
4. They say it’s vital for UK Energy Security – for emissions reductions, for cost, and for baseload. The big three – always the stated aim of energy policy, and they think nuclear ticks all those three boxes. But it doesn’t.

What they’ll say is, yes, you have to import uranium, but you’ve got a 4 year stock. Any war you’re going to get yourselves involved in you can probably resolve in 4 days, or 4 weeks. If you go for a very high nuclear scenario, you would be taking quite a big share of the global resource of uranium. There’s 2,600 TWh of nuclear being produced globally. And global final energy demand is around 100,000 TWh – so nuclear power currently produces around 2.6% of global energy supply. At current rates of nuclear generation, according to the World Nuclear Association, you’ve got around 80 years of proven reserves and probably a bit more. Let’s say you double nuclear output by 2050 or 2040 – but in the same time you might just have enough uranium – and then find a bit more. But global energy demand rises significantly as well – so nuclear will still only provide around 3% of global energy demand. That’s not a climate solution – it’s just an energy distraction. All this guff about fusion. Well.

Cornering The Market In Undug Uranium

A 75 GW programme would produce at baseload 590 TWh a year – divide by 2,600 – is about 23% of proven global uranium reserves. You’re having to import, regardless of what other countries are doing, you’re trying to corner the market – roughly a quarter. Not even a quarter of the market – a quarter of all known reserves – it’s not all been produced yet. It’s still in the ground. So could you be sure that you could actually run these power stations if you build them ? Without global domination of the New British Empire […]. The security issues alone – defending coastal targets from a tweeb with a desire to blow them up. 50 years down the line they’re full of radioactive spent fuel that won’t have a repository to go to – we don’t want one here – and how much is it going to cost ?

My view is that offshore wind will be a major contributor in a high or 100% Renewable Electricity scenario by 2050 or 2060. Maybe 180 GW, that will also be around 600 TWh a year – comparable to that maximum nuclear programme. DECC’s final energy demand 2050 – several scenarios – final energy demand from 6 scenarios came out as between roughly 1,500 TWh a year and the maximum 2,500 TWh. Broadly speaking, if you’re trying to do that just with Renewable Electricity, you begin to struggle quite honestly, unless you’re doing over 600 TWh of offshore wind, and even then you need a fair amount of heat pump stuff which I’m not sure will come through. The good news is that solar might – because of the cost and technology breakthroughs. That brings with it a problem – because you’re delivering a lot of that energy in summer. The other point – David MacKay would say – in his book his estimate was 150 TWh from solar by 2050, on the grounds that that’s where you south-facing roofs are – you need to use higher efficiency triple junction cells with more than 40% efficiency and this would be too expensive for a rollout which would double or triple that 150 TWh – that would be too costly – because those cells are too costly. But with this new stuff, you might get that. Not only the cost goes down, but the coverage goes down. Not doing solar across swathes of countryside. There have always been two issues with solar power – cost and where it’s being deployed.

Uh-Oh, Summer Days. Uh-Oh, Summer Nights

With the solar-wind headline, summer days and summer nights are an issue.

With the nuclear headline, 2040 – they would have up to 50 GW, and that would need to run at somewhere between 75% and 95% capacity – to protect the investment and electric generation turbines.

It will be interesting to provide some figures – this is how much over-capacity you’re likely to get with this amount of offshore wind. But if you have this amount of nuclear power, you’ll get this amount […]

Energy demand is strongly variable with season. We have to consider not just power, but heat – you need to get that energy out in winter – up to 4 times as much during peak in winter evenings. How are you going to do that ? You need gas – or you need extensive Combined Heat and Power (CHP) (which needs gas). Or you need an unimaginable deployment of domestic heat pumps. Air source heat pumps won’t work at the time you need them most. Ground source heat pumps would require the digging up of Britain – and you can’t do that in most urban settings.

District Heat Fields

The other way to get heat out to everyone in a low carbon world – apart from low carbon gas – is having a field-based ground source heat pump scheme – just dig up a field next to a city – and just put in pipes and boreholes in a field. You’re not disturbing anybody. You could even grow crops on it next season. Low cost and large scale – but would need a District Heating (DH) network. There are one or two heat pump schemes around the world. Not sure if they are used for cooling in summer or heat extraction in the winter. The other thing is hot water underground. Put in an extra pipe in the normal channels to domestic dwellings. Any excess heat from power generation or electrolysis or whatever is put down this loop and heats the sub-ground. Because heat travels about 1 metre a month in soil, that heat should be retained for winter. A ground source heat sink. Geothermal energy could come through – they’re doing a scheme in Manchester. If there’s a nearby heat district network – it makes it easier. Just want to tee it into the nearest DH system. The urban heat demand is 150 TWh a year. You might be able to put DH out to suburban areas as well. There are 9 million gas-connected suburban homes – another about 150 TWh there as well – or a bit more maybe. Might get to dispose of 300 TWh in heat through DH. The Green Deal insulation gains might not be what is claimed – and condensing gas boiler efficiencies are not that great – which feeds into the argument that in terms of energy efficiency, you not only want to do insulation, but also DH – or low carbon gas. Which is the most cost-effective ? Could argue reasonable energy efficiency measures are cheapest – but DH might be a better bet. That involves a lot of digging.

Gas Is The Logical Answer

But everything’s already laid for gas. (…but from the greatest efficiency first perspective, if you’re not doing DH, you’re not using a lot of Renewable Heat you could otherwise use […] )

The best package would be the use of low carbon gases and sufficient DH to use Renewable Heat where it is available – such as desalination, electrolysis or other energy plant. It depends where the electrolysis is being done.

The Age of Your Carbon

It also depends on which carbon atoms you’re using. If you are recycling carbon from the combustion of fossil fuels into Renewable Gas, that’s OK. But you can’t easily recapture carbon emissions from the built environment (although you could effectively do that with heat storage). You can’t do carbon capture from transport either. So your low carbon gas has to come from biogenic molecules. Your Renewable Gas has to be synthesised using biogenic carbon molecules rather than fossil ones.

[…] I’m using the phrase “Young Carbon”. Young Carbon doesn’t have to be from plants – biological things that grow.

Well, there’s Direct Air Capture (DAC). It’s simple. David Sevier, London-based, is working on this. He’s using heat to capture carbon dioxide. You could do it from exhaust in a chimney or a gasification process – or force a load of air through a space. He would use heat and cooling to create an updraft. It would enable the “beyond capture” problem to be circumvented. Cost is non-competitive. Can be done technically. Using reject heat from power stations for the energy to do it. People don’t realise you can use a lot of heat to capture carbon, not electricity.

Young Carbon from Seawater

If you’re playing around with large amounts of seawater anyway – that is, for desalination for irrigation, why not also do Renewable Hydrogen, and pluck the Carbon Dioxide out of there too to react with the Renewable Hydrogen to make Renewable Methane ? I’m talking about very large amounts of seawater. Not “Seawater Greenhouses” – condensation designs mainly for growing exotic food. If you want large amounts of desalinated water – and you’re using Concentrated Solar Power – for irrigating deserts – you would want to grow things like cacti for biological carbon.

Say you had 40 GW of wind power on Dogger Bank, spinning at 40% load factor a year. You’ve also got electrolysers there. Any time you’re not powering the grid, you’re making gas – so capturing carbon dioxide from seawater, splitting water for hydrogen, making methane gas. Wouldn’t you want to use flash desalination first to get cleaner water for electrolysis ? Straight seawater electrolysis is also being done.

It depends on the relative quantities of gas concentrated in the seawater. If you’ve got oxygen, hydrogen and carbon dioxide, that would be nice. You might get loads of oxygen and hydrogen, and only poor quantities of carbon dioxide ?

But if you could get hydrogen production going from spare wind power. And even if you had to pipe the carbon dioxide from conventional thermal power plants, you’re starting to look at a sea-based solution for gas production. Using seawater, though, chlorine is the problem […]

Look at the relative density of molecules – that sort of calculation that will show if this is going to fly. Carbon dioxide is a very fixed, stable molecule – it’s at about the bottom of the energy potential well – you have to get that reaction energy from somewhere.

How Much Spare Power Will There Be ?

If you’ve got an offshore wind and solar system. At night, obviously, the solar’s not working (unless new cells are built that can run on infrared night-time Earthshine). But you could still have 100 GWh of wind power at night not used for the power grid. The anticipated new nuclear 40 GW nuclear by 2030 will produce about 140 GWh – this would just complicate problems – adding baseload nuclear to a renewables-inclusive scenario. 40 GW is arguably a reasonable deployment of wind power by 2030 – low if anything.

You get less wind in a nuclear-inclusive scenario, but the upshot is you’ve definitely got a lot of power to deal with on a summer night with nuclear power. You do have with Renewable Electricity as well, but it varies more. Whichever route we take we’re likely to end up with excess electricity generation on summer nights.

In a 70 GW wind power deployment (50 GW offshore, 20 GW onshore – 160 TWh a year), you might have something like 50 to 100 GWh per night of excess (might get up to 150 GWh to store on a windy night). But if you have a 16 GW nuclear deployment by 2030 (125 TWh a year), you are definitely going to have 140 GWh of excess per night (that’s 16 GW for 10 hours less a bit). Night time by the way is roughly between 9pm and 7am between peak demands.

We could be making a lot of Renewable Gas !

Can you build enough Renewable Gas or whatever to soak up this excess nuclear or wind power ?

The energy mix is likely to be in reality somewhere in between these two extremes of high nuclear or high wind.

But if you develop a lot of solar – so that it knocks out nuclear power – it will be the summer day excess that’s most significant. And that’s what Germany is experiencing now.

Choices, choices, choices

There is a big choice in fossil fuels which isn’t really talked about very often – whether the oil and gas industry should go for unconventional fossil fuels, or attempt to make use of the remaining conventional resources that have a lower quality. The unconventionals narrative – shale gas, coalbed methane, methane hydrates, deepwater gas, Arctic oil and gas, heavy oil, is running out of steam as it becomes clear that some of these choices are expensive, and environmentally damaging (besides their climate change impact). So the option will be making use of gas with high acid gas composition. And the technological solutions for this will be the same as needed to start major production of Renewable Gas.

Capacity Payments

But you still need to answer the balancing question. If you have a high nuclear power scenario, you need maybe 50 TWh a year of gas-fired power generation. If high Renewable Electricity, you will need something like 100 TWh of gas, so you need Carbon Capture and Storage – or low carbon gas.

Even then, the gas power plants could be running only 30% of the year, and so you will need capacity payments to make sure new flexible plants get built and stay available for use.

If you have a high nuclear scenario, coupled with gas, you can meet the carbon budget – but it will squeeze out Renewable Electricity. If high in renewables, you need Carbon Capture and Storage (CCS) or Carbon Capture and Recycling into Renewable Gas, but this would rule out nuclear power. It depends which sector joins up with which.

Carbon Capture, Carbon Budget

Can the Drax power plant – with maybe one pipeline 24 inches in diameter, carrying away 20 megatonnes of carbon dioxide per year – can it meet the UK’s Carbon Budget target ?

Gain in Transmission

It constantly amazes and intrigues me how human individuals operate in networks to formulate, clarify and standardise ideas, tools, machines, procedures and systems. Several decades ago, Renewable Electricity from sources such as wind power was considered idealistic vapourware, esoteric, unworkable and uncertain, and now it’s a mainstream generator of reliable electricity in the UK’s National Grid. Who would have thought that invisible, odourless, tasteless gas phase chemicals would heat our homes ? It’s now just so normal, it’s impossible to imagine that Natural Gas was once considered to be so insignificant that it was vented – not even flared – from oil wells.

Judging by the sheer number of people working on aspects of Renewable Gas, I expect this too to be mainstream in the energy sector within a decade. What do others think ? I have begun the process of asking, for example, see below.

=x=x=x=x=x=x=x=x=

from: Jo Abbess
to: Richard A. Sears
date: Mon, May 2, 2011 at 11:59 PM
subject: Question from your TED talk

Dear [Professor] Sears,

I was intrigued by your TED talk that I recently viewed :-

http://www.ted.com/talks/richard_sears_planning_for_the_end_of_oil.html

Yes, I am interested in the idea of “printing” solar cells, which is what I think you might be alluding to with your reference to abalone shells.

But I am more interested in what you base your estimate of “Peak Gas” on. I recently did some very basic modelling of hydrocarbon resources and electricity, which look somewhat different from the IEA and EIA work and reports from BP and Royal Dutch Shell. My conclusion was that Peak Oil is roughly now, Peak Natural Gas will be around 2030, and Peak Electricity around 2060 :-

http://www.joabbess.com/2011/02/11/future-energy-tipping-points/

I am going to try to improve these charts before I submit my MSc Masters Thesis, so I am trying to find out what other people base their projections on. Could you help me by pointing me at the basis of your assessment of Peak Natural Gas ?

Thank you,

jo.

=x=x=x=x=x=x=

from: Richard A. Sears
to: Jo Abbess
date: Thu, Oct 24, 2013 at 5:30 PM

Jo,

I am just now finding a number of old emails that got archived (and ignored) when I moved from MIT to Stanford a few years ago. A quick answer is that I did about what Hubbert did in 1956. No detailed statistical modeling, just look at the trends, think about what’s happening in the industry, and make what seem like reasonable statements about it.

A number of interesting things have happened just in the last two years since you wrote to me. Significantly, US oil production is on the rise. When you count all hydrocarbon liquids, the US is or will soon be, the world largest producer. This just goes to one of my points from TED. Don’t expect oil and gas to go away any time soon. There are plenty of molecules out there. I first said this internally at Shell in the mid 1980’s when I was Manager of Exploration Economics and since then I’ve felt that I got it about right.

I did just look at your website and would caution you about extrapolating very recent trends into the future. The rate of growth in shale gas production has slowed, but there’s an important economic factor driving that. Gas prices in the US are very low compared to oil. With the development of fraccing technology to enable oil and liquids production from shale formations, the industry has shifted their effort to the liquids-rich plays. A few statistics. Gas is currently around $3.50/mcf. On an energy equivalent basis, this equates to an oil price of about $20/barrel. Brent currently sells for $110/barrel and the light oils produced from the shale plays in the US are getting between $90 and $100/barrel, depending on where they can be delivered. As a consequence, in the 3rd quarter of 2013, compared to one year ago, oil well completions are up 18% while natural gas well completions declined 30%.

Yes, you are right. Printing solar cells is an example of what I was talking about with Abalone shells. Similarly, what if you had paint that as it dried would self assemble into linked solar cells and your entire house is now generating electricity. I was totally amazed at the number of people that didn’t actually think about what I was saying and called me an !d!*t for imagining that I was going to transform coal itself into some magical new molecule. […]

In any case, I think it’s good that you’re thinking about these problems, and importantly it appears from your website that you’re thinking about the system and its complexity.

Best regards,
Rich Sears

Richard A. Sears
Visiting Scientist
MIT Energy Initiative
Massachusetts Institute of Technology

=x=x=x=x=x=x=x=x=x=

from: Jo Abbess
to: Richard A Sears
sent: Monday, May 02, 2011 3:59 PM

Dear [Professor] Sears,

Many thanks for your reply.

I had kinda given up of ever hearing back from you, so it’s lovely to
read your thoughts.

May I blog them ?

Regards,

jo.

=x=x=x=x=x=x=x=

from: Richard A Sears
date: Fri, Oct 25, 2013 at 5:03 PM
to: Jo Abbess

Jo,

I have personally avoided blogging because I don’t want to put up with people writing mean comments about me. But the data is worth sharing. You should also know the sources of that data otherwise you open yourself to more criticism.

The data on production comes from the International Energy Agency and a research firm PIRA. All of it was in recent press releases. The Energy Information Administration makes similar projections about future production. The data on well completions was recently released by API.

No need to reference me. The data is out there for all to see. But if you do, fair warning. You will get stupid comments about how I used to be a VP at Shell so of course these are the things I’m going to say. […]

By the way, there’s something else that’s very interesting in the world of peak oil and various peaks. I have long believed, as hinted in my TED talk that the most important aspect of peak oil is the demand driven phenomena, not the supply side. It’s worth noting in this context that US oil consumption peaked in 2005 and has declined about 10% since then. This data can be found easily in the BP Statistical Report on World Energy. This is real and is a result of economic shifts, greater efficiency, and the penetration of renewables. Future energy projections (references above) show that this trend continues. A big component of US energy consumption is gasoline, and US gasoline consumption peaked in 2007. I think that data can be found at http://www.eia.gov, although I haven’t looked for it lately. It’s a little factoid that I think I remember.

Rich

Richard A. Sears
Consulting Professor
Department of Energy Resources Engineering
Stanford University

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from: Jo Abbess
to: Richard A Sears
date: Sun, Jan 12, 2014 at 11:47 AM

Dear Professor Sears,

HNY 2014 !

This year I am hoping to attempt the climb on my own personal K2 by writing an academic book on Renewable Gas – sustainable, low-to-zero carbon emissions gas phase fuels.

I am not a chemist, nor a chemical engineer, and so I would value any suggestions on who I should approach in the gas (and oil) industry to interview about projects that lean in this direction.

Examples would be :-

* Power-to-Gas : Using “spare” wind power to make Renewable Hydrogen – for example by electrolysis of water. Part of the German Power-to-Gas policy. Some hydrogen can be added to gas grids safely without changing regulations, pipework or end appliances.

* Methanation : Using Renewable Hydrogen and young or recycled carbon gas to make methane (using the energy from “spare” wind power, for example). Also part of the German Power-to-Gas policy.

NB “Young” carbon would be either carbon monoxide or carbon dioxide, and be sourced from biomass, Direct Air Capture, or from the ocean. “Old” carbon would come from the “deeper” geological carbon cycle, such as from fossil fuel, or industrial processes such as the manufacture of chemicals from minerals and/or rocks.

Precursors to Renewable Gas also interest me, as transitions are important – transitions from a totally fossil fuel-based gas system to a sustainable gas system. I have recently looked at some basic analysis on the chemistry of Natural Gas, and its refinery. It seems that methanation could be useful in making sour gas available as sweetened, as long as Renewable Hydrogen is developed for this purpose. It seems that there is a lot of sour gas in remaining reserves, and the kind of CCS (Carbon Capture and Storage) that would be required under emissions controls could make sour gas too expensive to use if it was just washed of acids.

I don’t think the future of energy will be completely electrified – it will take a very long time to roll out 100% Renewable Electricity and there will always be problems transitioning out of liquid fuels to electricity in vehicular transportation.

If you could suggest any names, organisations, university departments, companies, governance bodies that I should contact, or research papers that I should read, I would be highly grateful.

Many thanks,

jo.

Mind the Gap : BBC Costing the Earth

I listened to an interesting mix of myth, mystery and magic on BBC Radio 4.

Myths included the notion that long-term, nuclear power would be cheap; that “alternative” energy technologies are expensive (well, nuclear power is, but true renewables are most certainly not); and the idea that burning biomass to create heat to create steam to turn turbines to generate electricity is an acceptably efficient use of biomass (it is not).

Biofuelwatch are hosting a public meeting on this very subject :-
http://www.biofuelwatch.org.uk/2013/burning_issue_public_event/
“A Burning Issue – biomass and its impacts on forests and communities”
Tuesday, 29th October 2013, 7-9pm
Lumen Centre, London (close to St Pancras train station)
http://www.lumenurc.org.uk/lumencontact.htm
Lumen Centre, 88 Tavistock Place, London WC1H 9RS

Interesting hints in the interviews I thought pointed to the idea that maybe, just maybe, some electricity generation capacity should be wholly owned by the Government – since the country is paying for it one way or another. A socialist model for gas-fired generation capacity that’s used as backup to wind and solar power ? Now there’s an interesting idea…




http://www.bbc.co.uk/programmes/b03cn0rb

“Mind the Gap”
Channel: BBC Radio 4
Series: Costing the Earth
Presenter: Tom Heap
First broadcast: Tuesday 15th October 2013

Programme Notes :

“Our energy needs are growing as our energy supply dwindles.
Renewables have not come online quickly enough and we are increasingly
reliant on expensive imported gas or cheap but dirty coal. Last year
the UK burnt 50% more coal than in previous years but this helped
reverse years of steadily declining carbon dioxide emissions. By 2015
6 coal fired power stations will close and the cost of burning coal
will increase hugely due to the introduction of the carbon price
floor. Shale gas and biomass have been suggested as quick and easy
solutions but are they really sustainable, or cheap?”

“Carbon Capture and Storage could make coal or gas cleaner and a new
study suggests that with CCS bio energy could even decrease global
warming. Yet CCS has stalled in the UK and the rest of Europe and the
debate about the green credentials of biomass is intensifying. So what
is really the best answer to Britain’s energy needs? Tom Heap
investigates.”

00:44 – 00:48
[ Channel anchor ]
Britain’s energy needs are top of the agenda in “Costing the Earth”…

01:17
[ Channel anchor ]
…this week on “Costing the Earth”, Tom Heap is asking if our
ambitions to go green are being lost to the more immediate fear of
blackouts and brownouts.

01:27
[ Music : Arcade Fire – “Neighbourhood 3 (Power Out)” ]

[ Tom Heap ]

Energy is suddenly big news – central to politics and the economy. The
countdown has started towards the imminent shutdown of many coal-fired
power stations, but the timetable to build their replacements has
barely begun.

It’ll cost a lot, we’ll have to pay, and the politicians are reluctant
to lay out the bill. But both the official regulator and industry are
warning that a crunch is coming.

So in this week’s “Costing the Earth”, we ask if the goal of clean,
green and affordable energy is being lost to a much darker reality.

02:14
[ Historical recordings ]

“The lights have started going out in the West Country : Bristol,
Exeter and Plymouth have all had their first power cuts this
afternoon.”

“One of the biggest effects of the cuts was on traffic, because with
the traffic lights out of commission, major jams have built up,
particularly in the town centres. One of the oddest sights I saw is a
couple of ladies coming out of a hairdressers with towels around their
heads because the dryers weren’t working.”

“Television closes down at 10.30 [ pm ], and although the cinemas are
carrying on more or less normally, some London theatres have had to
close.”

“The various [ gas ] boards on both sides of the Pennines admit to
being taken by surprise with today’s cold spell which brought about
the cuts.”

“And now the major scandal sweeping the front pages of the papers this
morning, the advertisement by the South Eastern Gas Board recommending
that to save fuel, couples should share their bath.”

[ Caller ]
“I shall write to my local gas board and say don’t do it in
Birmingham. It might be alright for the trendy South, but we don’t
want it in Birmingham.”

03:13
[ Tom Heap ]

That was 1974.

Some things have changed today – maybe a more liberal attitude to
sharing the tub. But some things remain the same – an absence of
coal-fired electricity – threatening a blackout.

Back then it was strikes by miners. Now it’s old age of the power
plants, combined with an EU Directive obliging them to cut their
sulphur dioxide and nitrous oxide emissions by 2016, or close.

Some coal burners are avoiding the switch off by substituting wood;
and mothballed gas stations are also on standby.

But Dieter Helm, Professor of Energy Policy at the University of
Oxford, now believes power cuts are likely.

03:57
[ Dieter Helm ]

Well, if we take the numbers produced by the key responsible bodies,
they predict that there’s a chance that by the winter of 2-15 [sic,
meaning 2015] 2-16 [sic, meaning 2016], the gap between the demand for
electricity and the supply could be as low as 2%.

And it turns out that those forecasts are based on extremely
optimistic assumptions about how far demand will fall in that period
(that the “Green Deal” will work, and so on) and that we won’t have
much economic growth.

So basically we are on course for a very serious energy crunch by the
winter of 2-15 [sic, meaning 2015] 2-16 [sic, meaning 2016], almost
regardless of what happens now, because nobody can build any power
stations between now and then.

It’s sort of one of those slow motion car crashes – you see the whole
symptoms of it, and people have been messing around reforming markets
and so on, without addressing what’s immediately in front of them.

[ Tom Heap ]

And that’s where you think we are now ?

[ Dieter Helm ]

I think there’s every risk of doing so.

Fortunately, the [ General ] Election is a year and a half away, and
there’s many opportunities for all the political parties to get real
about two things : get real about the energy crunch in 2-15 [sic,
meaning 2015] 2-16 [sic, meaning 2016] and how they’re going to handle
it; and get real about creating the incentives to decarbonise our
electricity system, and deal with the serious environmental and
security and competitive issues which our electricity system faces.

And this is a massive investment requirement [ in ] electricity : all
those old stations retiring [ originally built ] back from the 1970s –
they’re all going to be gone.

Most of the nuclear power stations are coming to the end of their lives.

We need a really big investment programme. And if you really want an
investment programme, you have to sit down and work out how you’re
going to incentivise people to do that building.

[ Tom Heap ]

If we want a new energy infrastructure based on renewables and
carbon-free alternatives, then now is the time to put those incentives
on the table.

The problem is that no-one seems to want to make the necessary
investment, least of all the “Big Six” energy companies, who are
already under pressure about high bills.

[ “Big Six” are : British Gas / Centrica, EdF Energy (Electricite
de France), E.On UK, RWE npower, Scottish Power and SSE ]

Sam Peacock of the energy company SSE [ Scottish and Southern Energy ]
gives the commercial proof of Dieter’s prediction.

If energy generators can’t make money out of generating energy,
they’ll be reluctant to do it.

[ Sam Peacock ]

Ofgem, the energy regulator, has looked at this in a lot of detail,
and said that around 2015, 2016, things start to get tighter. The
reason for this is European Directives, [ is [ a ] ] closing down some
of the old coal plants. And also the current poor economics around [
or surround [ -ing ] ] both existing plant and potential new plant.

So, at the moment it’s very, very difficult to make money out of a gas
plant, or invest in a new one. So this leads to there being, you know,
something of a crunch point around 2015, 2016, and Ofgem’s analysis
looks pretty sensible to us.

[ Tom Heap ]

And Sam Peacock lays the blame for this crisis firmly at the Government’s door.

[ Sam Peacock ]

The trilemma, as they call it – of decarbonisation, security of supply
and affordability – is being stretched, because the Government’s
moving us more towards cleaner technologies, which…which are more
expensive.

However, if you were to take the costs of, you know, the extra costs
of developing these technologies off government [ sic, meaning
customer ] bills and into general taxation, you could knock about over
£100 off customer bills today, it’ll be bigger in the future, and you
can still get that much-needed investment going.

So, we think you can square the circle, but it’s going to take a
little bit of policy movement [ and ] it’s going to take shifting some
of those costs off customers and actually back where the policymakers
should be controlling them.

[ KLAXON ! Does he mean controlled energy prices ? That sounds a bit
centrally managed economy to me… ]

[ Tom Heap ]

No surprise that a power company would want to shift the pain of
rising energy costs from their bills to the tax bill.

But neither the Government nor the Opposition are actually proposing this.

Who pays the premium for expensve new energy sources is becoming like
a game of pass the toxic parcel.

[ Reference : http://en.wikipedia.org/wiki/Hot_potato_%28game%29 ]

I asked the [ UK Government Department of ] Energy and Climate Change
Secretary, Ed Davey, how much new money is required between now and
2020.

08:06

[ Ed Davey ]

About £110 billion – er, that’s critical to replace a lot of the coal
power stations that are closing, the nuclear power stations that are [
at the ] end of their lives, and replace a lot of the network which
has come to the end of its life, too.

So it’s a huge, massive investment task.

[ Tom Heap ]

So in the end we’re going to have to foot the bill for the £110 billion ?

[ Ed Davey ]

Yeah. Of course. That’s what happens now. People, in their bills that
they pay now, are paying for the network costs of investments made
several years, even several decades ago.

[ Yes – we’re still paying through our national nose to dispose of
radioactive waste and decommission old nuclear reactors. The liability
of it all weighs heavily on the country’s neck… ]

And there’s no escaping that – we’ve got to keep the lights on – we’ve
got to keep the country powered.

You have to look at both sides of the equation. If we’re helping
people make their homes more inefficient [ sic, meaning energy
efficient ], their product appliances more efficient, we’re doing
everything we possibly can to try to help the bills be kept down,

while we’re having to make these big investments to keep the lights
on, and to make sure that we don’t cook the planet, as you say.

[ Tom Heap ]

You mention the lights going out. There are predictions that we’re
headed towards just 2% of spare capacity in the system in a few years’
time.

Are you worried about the dangers of, I don’t know, maybe not lights
going out for some people, but perhaps big energy users being told
when and when [ sic, meaning where ] they can’t use power in the
winter ?

[ Ed Davey ]

Well, there’s no doubt that as the coal power stations come offline,
and the nuclear power plants, er, close, we’re going to have make sure
that new power plants are coming on to replace them.

And if we don’t, there will be a problem with energy security.

Now we’ve been working very hard over a long time now to make sure we
attract that investment. We’ve been working with Ofgem, the regulator;
with National Grid, and we’re…

[ Tom Heap ]

…Being [ or it’s being ] tough. I don’t see companies racing to come
and fill in the gap here and those coal power plants are going off
soon.

[ Ed Davey ]

…we’re actually having record levels of energy investment in the country.

The problem was for 13 years under the last Government
[ same old, same old Coalition argument ] we saw low levels of investment
in energy, and we’re having to race to catch up, but fortunately we’re
winning that race. And we’re seeing, you know, billions of pounds
invested but we’ve still got to do more. We’re not there. I’m not
pretending we’re there yet. [ Are we there, yet ? ] But we do have the
policies in place.

So, Ofgem is currently consulting on a set of proposals which will
enable it to have reserve power to switch on at the peak if it’s
needed.

We’re, we’ve, bringing forward proposals in the Energy Bill for what’s
called a Capacity Market, so we can auction to get that extra capacity
we need.

So we’ve got the policies in place.

[ Tom Heap ]

Some of Ed Davey’s policies, not least the LibDem [ Liberal Democrat
Party ] U-turn on nuclear, have been guided by DECC [ Department of
Energy and Climate Change ] Chief Scientist David MacKay, author of
the influential book “Renewable Energy without the Hot Air” [ sic,
actually “Sustainable Energy without the Hot Air” ].

Does he think the lights will dim in the second half of this decade ?

[ David MacKay ]

I don’t think there’s going to be any problem maintaining the capacity
that we need. We just need to make clear where Electricity Market
Reform [ EMR, part of the Energy Bill ] is going, and the way in which
we will be maintaining capacity.

[ Tom Heap ]

But I don’t quite understand that, because it seems to me, you know,
some of those big coal-fired power stations are going to be going off.
What’s going to be coming in their place ?

[ David MacKay ]

Well, the biggest number of power stations that’s been built in the
last few years are gas power stations, and we just need a few more gas
power stations like that, to replace the coal
, and hopefully some
nuclear power stations will be coming on the bars, as well as the wind
farms that are being built at the moment.

[ Tom Heap ]

And you’re happy with that increase in gas-fired power stations, are
you ? I mean, you do care deeply, personally, about reducing our
greenhouse gases, and yet you’re saying we’re going to have to build
more gas-fired power stations.

[ David MacKay ]

I do. Even in many of the pathways that reach the 2050 target, there’s
still a role for gas in the long-term, because some power sources like
wind and solar power are intermittent, so if you want to be keeping
the lights on in 2050 when there’s no wind and there’s no sun, you’re
going to need some gas power stations there
. Maybe not operating so
much of the time as they do today, but there’ll still be a role in
keeping the lights on.

[ KLAXON ! If gas plants are used only for peak periods or for backup to
renewables, then the carbon emissions will be much less than if they are
running all the time. ]

[ Tom Heap ]

Many energy experts though doubt that enough new wind power or nuclear
capacity could be built fast enough to affect the sums in a big way by
2020.

But that isn’t the only critical date looming over our energy system.
Even more challenging, though more distant, is the legally binding
objective of cutting greenhouse gas emissions in 2050.

David MacKay wants that certainty to provide the foundation for energy
decisions, and he showed me the effect of different choices with the
“Ultimate Future Energy App”. I was in his office, but anyone can try it online.

[ David MacKay ]

It’s a 2050 calculator. It computes energy demand and supply in
response to your choices, and it computes multiple consequences of
your choices. It computes carbon consequences. It also computes for
you estimates of air quality, consequences of different choices;
security of supply, consequences; and the costs of your choices.

So with this 2050 calculator, it’s an open source tool, and anyone can
go on the web and use the levers to imagine different futures in 2050
of how much action we’ve taken in different demand sectors and in
different supply sectors.

The calculator has many visualisations of the pathway that you’re choosing
and helps people understand all the trade-offs… There’s no silver
bullet for any of this. If I dial up a pathway someone made earlier,
we can visualise the implications in terms of the area occupied for
the onshore wind farms, and the area in the sea for the offshore wind
farms, and the length of the wave farms that you’ve built, and the
land area required for energy crops.

And many organisations have used this tool and some of them have given
us their preferred pathway. So you can see here the Friends of the
Earth have got their chosen pathway, the Campaign to Protect Rural
England, and various engineers like National Grid and Atkins have got
their pathways.

So you can see alternative ways of achieving our targets, of keeping
the lights on and taking climate change action. All of those pathways
all meet the 2050 target, but they do so with different mixes.

[ Tom Heap ]

And your view of this is you sort of can’t escape from the scientific
logic and rigour of it. You might wish things were different or you
could do it differently, but you’re sort of saying “Look, it’s either
one thing or the other”. That’s the point of this.

[ David MacKay ]

That’s true. You can’t be anti-everything. You can’t be anti-wind and
anti-nuclear and anti-home insulation. You won’t end up with a plan
that adds up.

[ KLAXON ! But you can be rationally against one or two things, like
expensive new nuclear power, and carbon and particulate emissions-heavy
biomass for the generation of electricity. ]

[ Tom Heap ]

But isn’t that exactly kind of the problem that we’ve had, without
pointing political fingers, that people rather have been
anti-everything, and that’s why we’re sort of not producing enough new
energy sources ?

[ David MacKay ]

Yeah. The majority of the British public I think are in favour of many
of these sources, but there are strong minorities who are vocally
opposed to every one of the major levers in this calculator. So one
aspiration I have for this tool is it may help those people come to a
position where they have a view that’s actually consistent with the
goal of keeping the lights on.

[ Tom Heap ]

Professor MacKay’s calculator also computes pounds and pence,
suggesting that both high and low carbon electricity work out pricey
in the end.

[ David MacKay ]

The total costs of all the pathways are pretty much the same.
“Business as Usual” is cheaper in the early years, and then pays more,
because on the “Business as Usual”, you carry on using fossil fuels,
and the prices of those fossil fuels are probably going to go up.

All of the pathways that take climate change action have a similar
total cost, but they pay more in the early years, ’cause you have to
pay for things like building insulation and power stations, like
nuclear power stations, or wind power, which cost up-front, but then
they’re very cheap to run in the future.

[ KLAXON ! Will the cost of decommissioning nuclear reactors and the
costs of the waste disposal be cheap ? I think not… ]

So the totals over the 40 or 50 year period here, are much the same for these.

[ Tom Heap ]

The cheapest immediate option of all is to keep shovelling the coal.
And last year coal overtook gas to be our biggest electricity
generation source, pushing up overall carbon emissions along the way
by 4.5%

[ KLAXON ! This is not very good for energy security – look where the
coal comes from… ]

As we heard earlier, most coal-fired power stations are scheduled for
termination, but some have won a reprieve, and trees are their
unlikely saviour.

Burning plenty of wood chip [ actually, Tom, it’s not wood “chip”, it’s
wood “pellets” – which often have other things mixed in with the wood,
like coal… ] allows coal furnaces to cut the sulphur dioxide and nitrous
oxide belching from their chimneys to below the level that requires their
closure under European law.

But some enthusiasts see wood being good for even more.

16:19

[ Outside ]

It’s one of those Autumn days that promises to be warm, but currently
is rather moist. I’m in a field surrounded by those dew-laden cobwebs
you get at this time of year.

But in the middle of this field is a plantation of willow. And I’m at
Rothamsted Research with Angela Karp who’s one of the directors here.

Angela, tell me about this willow I’m standing in front of here. I
mean, it’s about ten foot high or so, but what are you seeing ?

[ Angela Karp ]

Well, I’m seeing one of our better varieties that’s on display here.
We have a demonstration trial of about ten different varieties. This
is a good one, because it produces a lot of biomass, quite easily,
without a lot of additional fertilisers or anything. And as you can
see it’s got lovely straight stems. It’s got many stems, and at the
end of three years, we would harvest all those stems to get the
biomass from it. It’s nice and straight – it’s a lovely-looking, it’s
got no disease, no insects on it, very nice, clean willow.

[ Tom Heap ]

So, what you’ve been working on here as I understand it is trying to
create is the perfect willow – the most fuel for the least input – and
the easiest to harvest.

[ Angela Karp ]

That’s absolutely correct, because the whole reason for growing these
crops is to get the carbon from the atmosphere into the wood, and to
use that wood as a replacement for fossil fuels. Without putting a lot
of inputs in, because as soon as you add fertilisers you’re using
energy and carbon to make them, and that kind of defeats the whole
purpose of doing this.

[ KLAXON ! You don’t need to use fossil fuel energy or petrochemicals or
anything with carbon emissions to make fertiliser ! … Hang on, these
are GM trees, right ? So they will need inputs… ]

[ Tom Heap ]

And how much better do you think your new super-variety is, than say,
what was around, you know, 10 or 15 years ago. ‘Cause willow as an
idea for burning has been around for a bit. How much of an improvement
is this one here ?

[ Angela Karp ]

Quite a bit. So, these are actually are some of the, if you like,
middle-term varieties. So we started off yielding about 8 oven-dry
tonnes per hectare, and now we’ve almost doubled that.

[ Tom Heap ]

How big a place do you think biomass can have in the UK’s energy
picture in the future ?

[ Angela Karp ]

I think that it could contribute between 10% and 15% of our energy. If
we were to cultivate willows on 1 million hectares, we would probably
provide about 3% to 4% of energy in terms of electricity, and I think
that’s kind of a baseline figure. We could cultivate them on up to 3
million hectares, so you can multiply things up, and we could use them
in a much more energy-efficient way.

[ KLAXON ! Is that 4% of total energy or 4% of total electricity ?
Confused. ]

[ Tom Heap ]

Do we really have 3 million hectares going a-begging for planting willow in ?

[ Angela Karp ]

Actually, surprisingly we do. So, people have this kind of myth
there’s not enough land, but just look around you and you will find
there’s lots of land that’s not used for cultivating food crops.

We don’t see them taking over the whole country. We see them being
grown synergistically with food crops.

[ KLAXON ! This is a bit different than the statement made in 2009. ]

[ Tom Heap ]

But I’d just like to dig down a little bit more into the carbon cycle
of the combustion of these things, because that’s been the recent
criticism of burning a lot of biomass, is that you put an early spike
in the amount of carbon in the atmosphere, if you start burning a lot
of biomass, because this [ sounds of rustling ], this plant is going
to be turned into, well, partly, CO2 in the atmosphere.

[ Angela Karp ]

Yes, I think that’s probably a simple and not totally correct way of
looking at it. ‘Cause a lot depends on the actual conversion process
you are using.

So some conversion processes are much more efficient at taking
everything and converting it into what you want.

Heat for example is in excess of 80%, 90% conversion efficiency.

Electricity is a little bit more of the problem. And there, what
they’re looking at is capturing some of the carbon that you lose, and
converting that back in, in carbon storage processes, and that’s why
there’s a lot of talk now about carbon storage from these power
stations.

That I think is the future. It’s a question of connecting up all parts
of the process, and making sure that’s nothing wasted.

20:02

[ Tom Heap ]

So, is wood a desirable greener fuel ?

Not according to Almuth Ernsting of Biofuelwatch, who objects to the
current plans for large-scale wood burning, its use to prop up coal,
and even its low carbon claims.

[ Almuth Ernsting ]

The currently-announced industry plans, and by that I mean existing
power stations, but far more so, power stations which are in the
planning process [ and ] many of which have already been consented –
those [ biomass ] power stations, would, if they all go ahead,
require to burn around 82 million tonnes of biomass, primarily wood,
every year. Now by comparison, the UK in total only produces around
10 million tonnes, so one eighth of that amount, in wood, for all
industries and purposes, every year.

We are looking on the one hand at a significant number of proposed,
and in some cases, under-construction or operating new-build biomass
power stations, but the largest single investment so far going into
the conversion of coal power station units to biomass, the largest and
most advanced one of which at the moment is Drax, who are, have
started to move towards converting half their capacity to burning wood
pellets.

[ Tom Heap ]

Drax is that huge former, or still currently, coal-fired power station
in Yorkshire, isn’t it ?

[ Almuth Ernsting ]

Right, and they still want to keep burning coal as well. I mean, their
long-term vision, as they’ve announced, would be for 50:50 coal and
biomass.

[ Tom Heap ]

What do you think about that potential growth ?

[ Almuth Ernsting ]

Well, we’re seriously concerned. We believe it’s seriously bad news
for climate change, it’s seriously bad news for forests, and it’s
really bad news for communities, especially in the Global South, who
are at risk of losing their land for further expansion of monoculture
tree plantations, to in future supply new power stations in the UK.

A really large amount, increasingly so, of the wood being burned,
comes from slow-growing, whole trees that are cut down for that
purpose, especially at the moment in temperate forests in North
America. Now those trees will take many, many decades to grow back
and potentially re-absorb that carbon dioxide, that’s if they’re
allowed and able to ever grow back.

[ Tom Heap ]

There’s another technology desperate for investment, which is critical
to avoiding power failure, whilst still hitting our mid-century carbon
reduction goals – CCS – Carbon Capture and Storage, the ability to
take the greenhouse gases from the chimney and bury them underground.

It’s especially useful for biomass and coal, with their relatively
high carbon emissions, but would also help gas be greener.

The Chancellor has approved 30 new gas-fired power stations, so long
as they are CCS-ready [ sic, should be “capture ready”, or
“carbon capture ready” ].

Jon Gibbons is the boss of the UK CCS Research Centre, based in an
industrial estate in Sheffield.

[ Noise of processing plant ]

Jon’s just brought me up a sort of 3D maze of galvanized steel and
shiny metal pipes to the top of a tower that must be 20 or so metres
high.

Jon, what is this ?

[ Jon Gibbons ]

OK, so this is our capture unit, to take the CO2 out of the combustion
products from gas or coal. In the building behind us, in the test rigs
we’ve got, the gas turbine or the combustor rig, we’re burning coal or
gas, or oil, but mainly coal or gas.

We’re taking the combustion products through the green pipe over
there, bringing it into the bottom of the unit, and then you can see
these big tall columns we’ve got, about 18 inches diameter, half a
metre diameter, coming all the way up from the ground up to the level
we’re at.

It goes into one of those, it gets washed clean with water, and it
goes into this unit over here, and there it meets an amine solvent, a
chemical that will react reversibly with CO2, coming in the opposite
direction, over packing. So, it’s like sort of pebbles, if you can
imagine it, there’s a lot of surface area. The gas flows up, the
liquid flows down, and it picks up the CO2, just mainly the CO2.

[ Tom Heap ]

And that amine, that chemical as you call it, is stripping the CO2 out
of that exhaust gas. This will link to a storage facility.

What would then happen to the CO2 ?

[ Jon Gibbons ]

What would then happen is that the CO2 would be compressed up to
somewhere in excess of about 100 atmospheres. And it would turn from
being a gas into something that looks like a liquid, like water, about
the same density as water. And then it would be taken offshore in the
UK, probably tens or hundreds of kilometres offshore, and it would go
deep, deep down, over a kilometre down into the ground, and basically
get squeezed into stuff that looks like solid rock. If you go and look
at a sandstone building – looks solid, but actually, maybe a third of
it is little holes. And underground, where you’ve got cubic kilometres
of space, those little holes add up to an awful lot of free space. And
the CO2 gets squeezed into those, over time, and it spreads out, and
it just basically sits there forever, dissolves in the water, reacts
with the rocks, and will stay there for millions of years.

[ Tom Heap ]

Back in his office, I asked Jon why CCS seemed to be stuck in the lab.

[ Jon Gibbons ]

We’re doing enough I think on the research side, but what we really
need to do, is to do work on a full-scale deployment. Because you
can’t work on research in a vacuum. You need to get feedback –
learning by doing – from actual real projects.

And a lot of the problems we’ve got on delivering CCS, are to do with
how you handle the regulation for injecting CO2, and again, you can
only do that in real life.

So what we need to do is to see the commercialisation projects that
are being run by the Department of Energy and Climate Change actually
going through to real projects that can be delivered.

[ Tom Heap ]

Hmm. When I talk to engineers, they’re always very passionate and
actually quite optimistic about Carbon Capture and Storage. And when
I talk to people in industry, or indeed read the headlines, not least
a recent cancellation in Norway, it always seems like a very bleak picture.

[ Jon Gibbons ]

I think people are recognising that it’s getting quite hard to get
money for low carbon technologies.

So – recent presentation we had at one of our centre meetings, was
actually a professor from the United States, Howard Herzog. And he
said “You think you’re seeing a crisis in Carbon Capture and Storage.
But what you’re actually seeing is a crisis in climate change
mitigation.”

[ KLAXON ! Priming us for a scaling back of commitment to the
Climate Change Act ? I do hope not. ]

Now, Carbon Capture and Storage, you do for no other purpose than
cutting CO2 emissions to the atmosphere, and it does that extremely
effectively. It’s an essential technology for cutting emissions. But
until you’ve got a global process that says – actually we’re going to
get on top of this problem; we’re going to cut emissions – get them to
safe level before we actually see people dying in large numbers from
climate change effects – ’cause, certainly, if people start dying,
then we will see a response – but ideally, you’d like to do it before
then. But until you get that going, then actually persuading people to
spend money for no other benefit than sorting out the climate is
difficult.

There’s just no point, you know, no country can go it alone, so you
have to get accommodation. And there, we’re going through various
processes to debate that. Maybe people will come to an accommodation.
Maybe the USA and China will agree to tackle climate change. Maybe
they won’t.

What I am fairly confident is that you won’t see huge, you know,
really big cuts in CO2 emissions without that global agreement. But
I’m also confident that you won’t see big cuts in CO2 emissions
without CCS deployment.

And my guess is there’s about a 50:50 chance that we do CCS before we
need to, and about a 50:50 chance we do it after we have to. But I’m
pretty damn certain we’re going to do it.

[ Tom Heap ]

But we can’t wait for a global agreement that’s already been decades
in the making, with still no end in sight.

We need decisions now to provide more power with less pollution.

[ Music lyrics : “What’s the plan ? What’s the plan ?” ]

[ Tom Heap ]

Dieter Helm, Professor of Energy Policy at the University of Oxford
believes we can only deliver our plentiful green energy future if we
abandon our attitude of buy-now pay-later.

[ KLAXON ! Does he mean a kind of hire purchase energy economy ?
I mean, we’re still paying for nuclear electricity from decades ago,
in our bills, and through our taxes to the Department of Energy and
Climate Change. ]

[ Dieter Helm ]

There’s a short-term requirement and a long-term requirement. The
short-term requirement is that we’re now in a real pickle. We face
this energy crunch. We’ve got to try to make the best of what we’ve
got. And I think it’s really like, you know, trying to get the
Spitfires back up again during the Battle of Britain. You know, you
patch and mend. You need somebody in command. You need someone
in control. And you do the best with what you’ve got.

In that context, we then have to really stand back and say, “And this
is what we have to do to get a serious, long-term, continuous, stable
investment environment, going forward.” In which, you know, we pay the
costs, but of course, not any monopoly profits, not any excess
profits, but we have a world in which the price of electricity is
related to the cost.”

[ KLAXON ! Is Dieter Helm proposing state ownership of energy plant ? ]

29:04

[ Programme anchor ]

“Costing the Earth” was presented by Tom Heap, and made in Bristol by
Helen Lennard.

[ Next broadcast : 16th October 2013, 21:00, BBC Radio 4 ]