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Wednesday, 17 September 2014

New Life-Cycle Assessment for UK Shale Gas


A new life cycle assessment for UK shale gas has been released by researchers from the University of Manchester. This study considers a range of potential environmental impacts. Most significantly, it compares shale gas extraction against a host of other energy technologies, including conventional gas, coal, nuclear power and renewables. 

This sort of comparison is very important, because when it comes to energy sources, we have to choose how our energy mix should be balanced. All sources of energy have impacts, and we can't say no to all of them. 

Equally significant is the fact that the study doesn't just consider the global warming impact of the various technologies (the global warming potential, or GWP), but a whole host of environmental factors , including the use of abiotic resources (rare earth elements etc), acidification, eutrophication, freshwater, marine, terrestrial and human toxicity, and ozone depletion. 

Before I get into the details of the study, the first figure I'll borrow is the one that compares the global warming potential (GWP), according to the various previous studies: 


I do so to re-iterate the point, made many times by many different people, that the Howarth study famous for claiming that shale gas is worse than coal, is a real outlier. There is clear consensus that shale gas is better than coal with respect to global warming.

The following bar charts show the environmental impacts of each technology in each category, and I discuss the results in greater detail below.

Global Warming:
The consensus that shale gas is significantly better than coal is again reached in the new study, which finds that shale gas has a similar GWP to conventional gas, and in fact a lower footprint in comparison to LNG, which has to be liquified, transported across oceans and re-gasified. By assuming the worst case for all possible variables, the researchers are just able to make shale gas as bad as coal, and 2.5 times worse than North Sea gas, but they concede that this extreme end-member "is probably not realistic" (it requires an average EUR of 0.1bcf per well, and no attempts to mitigate gas venting during completion). 

In the best possible case (high average EUR and no gas vented during completion), shale gas global warming potential (GWP) is only 2.8% higher than North Sea gas, but 15-19% lower than imported LNG. Compared to coal, the central shale gas case has a GWP 51-58% lower, a significant advantage. Of course, compared to non-fossil fuel sources of energy (nuclear, solar, wind), all of the above are still fossil fuels and so have far higher GWP. 

Abiotic Depletion:
An important issue facing some energy technologies is the rate at which they use up natural resources such as metals, and in particular rare earth elements which are vital in many modern technologies. The abiotic depletion potential of elements (ADP-E) for shale gas is 18% lower than wind energy, and 94% lower than solar energy. This demonstrates that while renewable energy is often considered clean, it does still have an environmental footprint. Because of the increased footprint of shale gas with respect to conventional gas, shale gas ADP-E is 81% higher than North Sea gas, but on a similar level to coal. 

Acidification Potential:
The acidification potential describes the quantity of SO2 released by an energy technology. This study finds that the AP for shale gas is between 4 - 7 times worse than North Sea gas. However, the error bars on this factor are huge, ranging from double that of any other technology to less than coal, and interestingly, 60% lower than solar power. 

The main sources of SO2 are in diesel engines used to power the drill and fracking pumps, and in gas sweetening, where H2S present naturally in the gas is removed before it is sold. The study assumes an H2S level equal to that of conventional gas, which at face value is a reasonable assumption. However, I've not heard that so-called "sour" gas has been an issue in many shale plays, where the gas is generally found to be very "sweet" (low in H2S). If this is the case in the UK (I'm not aware of any analysis of the gas produced by Cuadrilla after their stimulations in 2011) then the AP would be towards the lower bound, making it a lower emitter of SO2 than solar power. 

Toxicity Potentials:
The report considers toxicity in marine, freshwater, terrestrial and humans separately. However, the results paint a very similar story for these different factors.

For freshwater toxicity potential, the report finds that shale gas is comparable to natural gas, and is an order of magnitude better than nuclear, offshore wind and solar. 

The human toxicity potential for shale gas comes in with a lower impact than nuclear (which is 5 times worse), solar (6 times worse) and coal (10 times worse)! 

The marine toxicity potential of shale gas comes in between 1.6-7.8 times lower than nuclear, offshore wind and solar, and a whopping 45 times lower than coal.  

The only toxicity potential in which shale gas comes in worse than other sources is terrestrial toxicity, where the impact is 13-26 times worse than conventional gas, and between 2-4.4 times worse than coal, nuclear, wind and solar. 

It is worth noting that the major source of this toxicity potential for shale gas is how drilling waste is disposed of. In the central scenarios, 60% of the waste is disposed of by landfarming, a process whereby waste is ploughed into the soil, allowing soil microbes to degrade any harmful contaminants. Alternatively, drilling waste can be treated and sent to landfill, which substantially reduces the toxicity potential. If instead 100% of the drilling waste is sent to landfill, the terrestrial toxicity potential can be reduced to an amount that is an order of magnitude lower than solar, wind and coal.   

For me these toxicity potentials are a surprising result. We hear much about the potential pollution, and impacts on human health and the environment, engendered by an increase in shale gas production in the UK. However, when a full life-cycle analysis of impacts is performed, shale gas comes in lower for a range of toxicity potentials than a range of alternative energy sources - sometimes by an order of magnitude or more! Although the results are less surprising when you learn about the extraction of rare earth elements in places like China.  

Ozone Depletion:
Shale gas is found to have a similar impact on ozone depletion as conventional gas. However, both shale gas conventional gas have a high impact compared to other sources, 25 times higher than wind and nuclear. This is because of fire-retartant gases such as halon used in pipelines. That said, shale gas still has a similar ozone depletion potential as solar (the high values for solar are due to the manufacture of tetrafluoroethylene used in the panels).

Photochemical ozone creation:
This seems to be the only factor in which shale gas appears to perform badly, with a POCP factor worse than solar, wind and nuclear by between 3, 26 and 45 in the central case, and 3.3 and 5.6 times even in the best case. The main source of POCP is in gas sweetening, and as I comment above, if UK shale gas has a low H2S content then these effects will be mitigated somewhat. 

Recommendations:
The advantage of a LCA paper like this is that you can look to see what aspects of the life cycle of shale gas production have the greatest impact, and therefore what should be the key steps taken to minimise impact.

With respect to GWP, the advantage of shale gas with respect to both coal and LNG requires low rates of methane venting during completion. It is therefore important that measures are put in place to ensure that methane is either captured and flared during the flowback processes. 

This venting is also important with respect to the photochemical ozone creation factor (POCP) - unburned butane, ethane and other VOCs can contribute to smog. By minimising venting, the POCP factor can be reduced. 

Similarly, with respect to toxicity factors, the disposal of drilling waste is the key factor. Landfarming of waste appears to increase toxicity factors substantially. The larger the portion of waste treated and taken to landfill, the lower the toxicity factors. 

Therefore if we are to produce shale gas in the UK, green completions (where the amount of gas vented is minimised) should be used, and appropriate treatment pathways for drilling waste are identified. 

Finally, I note that all of the above assumptions are determined to a certain extent by the Estimated Ultimate Recovery (EUR). The more gas you get per well, the lower the average impact is (as you have more gas for your buck). This study used a central case EUR of 1bcf. Over the last 5 years, as technology has moved forward we are seeing ever-increasing EURs. Of course, the better your EUR, the better off you are financially. By using better technology, shale gas extraction is better both economically and in terms of environmental impact.




9 comments:

  1. Two points:

    1. What 'Global Warming'? Even if there is a minuscule rise, it certainly isn't proportional to atmospheric CO2 rises.

    2. "All sources of energy have impacts, and we can't say no to all of them." But we can withdraw all subsidies. The ONLY reason there's wind & solar PV in the UK is the massive subsidies paid by taxpayers and all energy users.

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  2. JP, are you suggesting Global Warming doesnt exist? Hmmm...

    Subsidies are needed to make things happen, and I can see that the low carbon of wind and PV is a suitable thing to subsidise. The extent to which it is subsidised is another thing.I don't protest about subsidy for students/disabled/pensioners when I go to the cinema for example.

    an interesting comparison nonetheless. Thanks JV for bringing it to attention.

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    1. KW -

      1. We currently have 'The Pause' of 1.5 - 2 decades depending upon data source.

      2. Atmospheric ∆T ≠ atmospheric ∆CO2 concentration.

      3. So the fundamental question arises, why should UK taxpayers and energy users pay extra for their power? If wind & solar are so 'beneficial', fine, let their producers sell their output into the market at a cost of their choosing, and let 'greenies' salve their consciences by paying the true price for their choice. And, the greenies can also pay the premium for using conventionally generated power for when the wind doesn't blow, and/or, the sun doesn't shine.

      Gridwatch http://www.gridwatch.templar.co.uk currently has an interesting chart - Column2, Row3. It shows September's wind-generated power to date. Apart from a couple of hiccoughs, it virtually hugs the X-axis.

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  3. It doesn't add up...21 September 2014 at 04:34

    The functional unit is defined as 1 kWh of electricity generated at the power plant (i.e. transmission is excluded from the system boundary).

    The data are extremely biassed by drawing the line at energy generated without considering the impact of lack of dispatchability and the need for back-up. Wind and solar require full back-up and more investment in transmission assets which will add significantly to the environmental burden. The offshore wind capacity factors are also extremely optimistic at 30% to 50%.

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    Replies
    1. It doesn't add up...21 September 2014 at 04:54

      There is no sense of the relative or absolute importance of the various factors. Of course we know that even the importance of carbon dioxide is far from settled.

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    2. I think that making a comparison between the relative importance of these factors is a difficult challenge - it probably depends as much on culture, politics and sociology as it does science - what aspects of our natural environment do we attach the most cultural value to?

      Equally, what this study doesn't discuss is the geographical location of the impacts. We tend to assume renewable power is "clean" because the part that we see - the finished solar panel on someone's roof, for example - is not where the impact is. The impact is where the panels are constructed, and in particular where the raw materials for the panel are sourced, which is generally in other places (China being a prime example), so we don't care as much (at all?) as the impacts are not close to home. If we lived near a Chinese rare earth element mining operation we'd probably have a very different view.

      You are correct about the intermittency issue with respect to the calculations. That said, even without taking this into account I was genuinely surprised at how poorly some of the renewable options performed in some of the categories (as above, that's probably because I don't live near to where they are manufactured or the raw materials sourced).

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    3. He is correct about the backup needed to deal with the intermittency option. The decreased efficiency of bakup plant, coupled with ramping the power, result in increased emissions from the backup plant exceeding the emissions displaced by renewables such as wind and solar.

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    4. It doesn't add up...23 September 2014 at 07:18

      This study gives a good insight into the effects of including backup:


      http://bravenewclimate.com/2014/08/22/catch-22-of-energy-storage/

      EROEI should really be considered as a constraint in energy planning.

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    5. Thanks IDAU, interesting link...

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