Here's my basic problem with your argument: How can you know that the amount of extractable coal will not go up substantially at higher price points?

Take a doubling of the price of coal. How many coal fields become economically feasible to mine at double the price? Is there some way to get at that?

I read "Estimating Long-Term World Coal Production with Logit and Probit Transforms" earlier and think the Logit and Probit transform approach is an advancement over Hubbert Linearization. It looks similar to what Sam Foucher did with the Hybrid Shock Model. Although no doubt better than HL, which both Rapier and I have shown dissatisfaction with, I would prefer that we think about depletion and a host of other problems through maximum entropy and related probability techniques.

So this is not at all a bash at Prof. Rutledge, but just a chance to announce that I have compiled most of my blog postings and edited them to fit into a manuscript format. Whether it will make it easier for "everyone" to follow my arguments, I kind of doubt it. But having the narrative formatted in math markup, captioned figures, full index, references, links, and footnotes should make it easier for people that are serious about the topic.

Should have the first draft out early January as a PDF.

Anecdotal evidence supports the view that we are within sight of Peak Coal. In the picturesque Hunter Valley of New South Wales wealthy business people have set up thoroughbred horse farms. Lately coal miners want to dig large pits right next door. Now even the business types are questioning the scramble for coal.
http://www.ozeform.com/Racing/News/101214/Miningindustrytoworkwithbreede...

Another telltale sign in Australia is that Chinese and Indian interests are buying coal mines. For now that coal goes into the system but perhaps later it could be direct export. The Australian government seems to have its head in the sand or perhaps coal dust. We are the OECD's biggest per capita CO2 emitter (~20t a year) and the biggest coal exporter (250-300 Mt a year) yet we lecture other countries at the climate conferences. To Peak Coal I say bring it on.

The one line message I get from this article would be this -

Three peer reviewed studies have concluded that total world coal production to 2100 will be 20% or less of the figure assumed by the IPCC.

Two comments on the state of UK Coal reserves and the financial health of UK Coal plc.

Some surface mine reserves in the UK have been or are proposed to be sterilised by Government action. The Governments of Scotland and Wales have already introduced a 500 metre buffer zone between areas of settlement and surface / opencast mine sites. When this proposal was made for Wales coal producers claimed that it would sterilise a significant proportion of known coal reserves:

" Members expressed there concerns that the 500 metre boundary proposed in the
consultation would lead to nearly two thirds of the coal reserves in Wales being
sterilised and that the remaining third had either been worked or was uneconomical.
Members said that the introduction of wind farms was also causing issues for the
sterilisation of coal reserves. Members felt that the impact of this sterilisation would
close the surface mining industry in Wales. Members noted that this was likely to
form a precedent which would be followed by England and Scotland."

(8th Meeting of the UK Coal Forum available @

http://webarchive.nationalarchives.gov.uk/+/http://www.berr.gov.uk/files... )

I do not have a reference to show what the impact of such a measure has been on Scottish coal reserves.

Now Andrew Bridgen MP has a Bill before Parliament to introduce similar legislation to cover England. First indications are that, if passed, this measure would reduce available English coal reserves by a further 200 - 500m tonnes of recoverable coal (see 'Visit to opencast sites test out buffer zone', The Journal 3/11/10 @

http://www.journallive.co.uk/north-east-news/todays-news/2010/11/03/visi...

As yet I have no information on what proportion of known English / UK reserves this represents.

In addition, as possibly the original author of the cumulative deficit being carried by UK Coal plc in 'UK Coal: An Alternative Report' and the update 'Briefing Note C1 'UK Coal's Financial Situation' avaible from http://www.leicestershirevillages.com/measham/minorca-protest.html, just to bring UK Coal's debt figures up to date its last Interim Financial Staetment, October 2010 indicated that the level of debt had risen to £265m (See http://miranda.hemscott.com/static/cms/2/4/2/6/binary/6893857063/1812145...)

"....The main production in Montana is from the Powder River Basin (PRB), and it appears that Wyoming drew much the better hand in the PRB. I believe that the differences in PRB production for Wyoming and Montana represent geology at least as much as any other factors."

One significant factor in Montana coal production is the lack of access to local rail lines. During the late 1970's through the mid 1980's several new rail lines were built in the Wyoming's Powder River Basin to access this coal, most notably the Gillette to Orin line of the Burlington Northern railroad. Later the Union Pacific railroad built a connector to the PRB. In contrast, the state of Montana has had many rail lines removed during the late 1970's and early 1980's. As example a mine at Klein, MT has to truck the coal about 50 miles to a rail head near Billings since the rail line through Klein was abandoned in 1981. The coal mine shut down, then reopenned after the state rebuilt the highway for heavier trucks to haul the coal.

Unless the coal can be shipped almost entirely by rail, some of the US coal deposits may not be economical to mine, especially given the high cost of trucking due to fuel price increases. Besides, most states do not want the burden of heavy coal trucks destroying the highways, as they cannot they afford repairs with tax revenue shortfalls. And certainly the coal mine companies cannot afford to build new highways. So the coal may very well remain in the ground forever at numerous places in the US.

a ton of coal produces about 2.86 tones of CO2 according to this source
http://www.eia.doe.gov/cneaf/coal/quarterly/co2_article/co2.html
So the good news is that if Rutledge is correct, there will be
8 trillion tons of CO2 factored into the IPCC report that will not be generated.

This is about 240 years' worth, at current rates, if I have my math right. Our Choice says we produce 90 million tons per day

Thanks for the interessting article.

One minor comment on German coal reserves. I've talked to some German coal miners of the Ruhr region recently and they stated that there are definitely large coal seams up to 6m thick in large numbers left and not yet mined because of different reasons (deep >2000m, no mines left in the regions of the seams - e.g. Saar, environmental restrictions, etc.).

So maybe this coal will never be mined, but there are definitly large amounts of coal left with significant positive EROEI, even in mature regions like Germany, but they are not mined because we are not China and do not bring up anything "at any price". The reason the price of the Germany coal is that high is not only geological (of course it is to some degree - 1800m deep mining etc.). But a German miner earns about $5000/month, a Chinese maybe around $500/month if he's lucky, environmental restrictions in a dence populated region like the Ruhr area in Germany are extrem etc.

Nice to have you around again Dave.

I calculate your Coal ultimate to be something around 480 Gtoe (I work with these units). Jean Laherrère, who also uses data from the BGR, is presently coming to a 700 Gtoe ultimate. The EWG assessed something between 600 and 650 Gtoe. BP reports available reserves of some 700 Gtoe.

The essential question is: what makes you prefer the ultimates provided by curve fitting methods over the reserve estimates?

Thanks very much for this Dave. When you first posted this assessment I was somewhat sceptical that such large amounts of coal would be left in the ground.

Since then I've come round to your analysis. the price of coal has increased substantially over the past 2-3 years to the point where now Nuclear Power is unequivocally the cheapest form of electricity production on the East Coast of China. The Chinese have responded and now propose 245 reactors by 2030 (from 11 in 2009). The number keeps going up. So all those deep seams look like being priced out of the market just like British Coal.

What you write is not correct: "However, all the estimates for the long-term production, and the cumulative production plus reserves are completely different from what the IPCC (United Nations Intergovernmental Panel on Climate Change) assumes is available for production in its scenarios."
Not "all":

You have missed for example scenario B1 which has C emissions of about 700 Gt (including coal, oil and gas, so coal is smaller than your estimate).(With that scenario a temperature rise of 2 degrees centigrade is calculated by 2100 compared to 2000, btw.). (See figure 10.26 in IPCC 4th report chapter 10).

Furthermore, keep in mind that the scenarios you criticize were constructed 10 years ago, and are being updated as we speak for the next assessment (see for instance "IPCC Workshop on New Emission Scenario
Laxenburg, Austria, 29 June - 1 July 2005" http://www.ipcc.ch/publications_and_data/publications_and_data_supportin...).
The scenarios are NOT predictions, but a purpose for the scenarios are also to be used as sensitivity studies for the models.

The evolution of scenarios is discussed to produce a class of "most probable" scenarios, that better can be used and understood by end-users. But that brings on a range of difficult questions too.

Id suggest you stop bashing on that particular A1 scenario - it is NOT a prediction.

The message from this post is that the global coal reserves, at the current economic price, are a lot lower than is widely expected.

The implications for this need to be considered in the context of the global primary energy supply. Coal, oil and NG between them are about 80% of that energy at present.

We all know about peak oil. Natural gas has not peaked, but an increasing part of the remaining reserves are either in locations remote from their markets, requiring expensive LNG transportation, or are shale gas which is more expensive to extract.

The combined effect is that the global energy supply is getting more expensive. That means in practice the ERoEI is declining. More and more resources need to be invested to sustain or increase the total energy supply. The energy production part of the economy is increasing at the expense of the rest of the economy. Sooner or later the increasde expense of extracting fossil energy cuts into and decreases the rest of the global economy, and so cuts energy demand (at that price). The world will have hit peak net energy. We may already be at that point.

Soon after that, we will hit global peak energy. Total global GDP will decline.

Of course, we should be investing in non-finite energy sources as fast as possible, because these tend to have large, up front capital costs, but see the recent post by Nate Hagens to understand why we are not doing this as fast as we should.

Nuclear power is a more complicated case. The current technology is based on a finite fuel supply. It has huge upfront capital costs and unquantifiable decommissioning costs. It is a high technology energy source which will be hard to sustain in a globally declining energy environment. There are huge logistic bottlenecks to its rapid expansion. It has contested environmental impacts and is a political impossibility in many countries.

At this moment, the general consensus is that we must No go about amession of 1000 GT of CO2 to avoid à 2C of temperature increase.

http://www.nature.com/nature/journal/v458/n7242/full/nature08017.html
https://regtransfers-sth-se.diino.com/download/f.thompson/migrated_data/...
http://www.pnas.org/content/106/38/16129.full

You coal reserve estimate are way above this limit. Also, this does not take account of oil and gaz, especially non convetional. Also, it does not matter much how fast these reserve are consummed. This will only delay to moment when the equilibrium temperature is reached by a few decades.

I don't think it's accurate to speak about economically recoverable reserves in vacuum. Yes, as the price of coal increases with demand, it becomes more economically feasible to extract a greater percentage of the world's known reserves.

On the other hand, what is that price point and what will such a price for coal do to the economic viability of other sources of energy? At some point, it becomes cheaper to use other fuels, such as natural gas, nuclear, or renewables, than it does to mine coal, drive up demand, and commit to a long-term higher price of energy.

All the arguments in favor of coal use and expanding coal use are economic in nature: this stuff is cheap. But to keep it cheap, we have to abandon hope of recovering much of the world's vast coal resources because recovery of those resources is more expensive. At those kinds of prices, coal starts to become much less attractive: it's bothersome to transport, difficult to extract, of inconsistent quality, and difficult to burn efficiently and cleanly. It's really a sub-optimal fuel.

High liquid fuel costs, high natural gas demand, and some economically viable coal-to-liquids process projects may change the calculus, particularly if some of the prototype technologies for in-situ coal gasification take off, but consider what other hydrocarbon projects are in the (pardon the pun) pipeline:

-Japan has recently undertake serious research into methane gas hydrate extraction. This may seem a long-shot technology, but that's what people said to Sony about digital imaging in the late '80s and what American engineers said to Toyota about hybrid drive technology in the 90s. The Japanese business sector has a history of sticking with these long-term R&D projects, so I wouldn't be surprised if we saw the first commercial gas hydrate extraction facility open up in the next 10 or 20 years. This would dramatically expand global gas reserves.

-Shale gas goes ever on. There are concerns about it's production ability and impacts, but I suspect these will prove to be more technological issues than geological and it certainly doesn't seem to affect the futures trade.

-Oil sand developments continue, with the total cost lowered by currently cheap natural gas. This may change in the future, but any attempts at CTL technologies would require even more massive thermal inputs.

-Coal is falling out of favor as the electrical generating fuel of choice in the US and an expansion of nuclear power, renewables, and a deployment of more efficient coal burning designs in the developing world has hedged future growth projections. This is as much an infrastructural issue as anything else: in the States, we're tearing down old coal boilers, with more to follow in the next decade or so, so our actual ability to utilize this fuel source in the future is diminished. Furthermore, it's just as likely that high electricity demand and high fuel prices will make other sources of generating electricity just as economically and politically attractive as coal.

-And what about oil shales? Sure, they're expensive to use, but we're talking about a future where energy is expensive enough to make reserves of coal which are currently totally uneconomical profitable. It takes just as much effort to strip mine shales as it does coal and the industry expects profitability at $95/bbl (higher with higher natural gas prices). This cost comes down as economies of scale are deployed. Either way, any future renewed interest in coal to liquids technology, as I believe would be the saving grace of the coal industry, would have to compete with unconventional petroleum production from tar sands and oil shales.

So there's a lot of economic considerations, infrastructural considerations, and we have to think about what future technologies currently under development may yield. In short, the point at which these currently unfeasible coal reserves are extractable may also be the point at which other technologies and sources may come online and how that would influence deployment of coal consuming technologies in the future.

Since coal is relatively expensive to ship overland, the rate at which mid-continetal reserves are consumed would seem to be related to the demand for electricity within a couple thousand kilometers of the reserves. This would be the case for Montana, Western China, Siberia, etc. Where large amounts of gas and oil are also available in the same vicinity, such as Siberia, it is likely that the reserves stay in the ground longer and are used less widely.

On the other hand, countries which have available coal reserves but limited other supplies of fossil fuel are likely to exploit them beyond the point that would be consistent with a "global" model of reserves and economic value through a variety of subsidies.

Lastly, if Peak Oil seriously jeopardizes the welfare of the economically well off, the think tanks will be funded to reevaluate their conclusions, public opinion will be reconditioned, and environmental concerns will go out the window.

Nations that have access to coal will use it, while others will depend on imports of gas or nuclear fuel.

Dave,

I just wanted to congratulate you on providing the Excel spreadsheet along with your results. I expect a large amount of effort went into compiling the historical numbers and making them freely available is a huge stride toward a more 'Open Source Science'.

If scientific results are supposed to be reproducible, scientific papers should always be accompanied by the data and software from which the results are generated. David's inclusion of an Excel spreadsheet is so remarkable because it so rarely occurs.

Thanks for setting a good example,

Jon

The problem that I have with this analysis is to do with the distinction between known resources and reserves. We are in (or rapidly coming to, depending on who you believe credible) a period where crude oil is going to be perpetually over $100 a barrel, because of the costs for production at the margin needed to meet global demand. The demand for domestically based alternate fuels will thus rise.

At present coal is still one of those products (Germany being an exception to the almost global rule) that it is the cheapest producer that gains the market, and that there are still many deposits where all you need do is scrape the dirt from the top and buy a bigger shovel and then, provided you can provide transport the coal, it costs very little (about $10 a ton) to produce. Even within those constraints we have the example of Botswana who, until recently had 1 power station, 1 mine, and 1 mining machine - all that was needed in a country that bought most of its electricity from South Africa. The reserves of the country were therefore considered to be very small. Then South Africa decided it needed its power for itself, and the feed to Botswana is being cut off. Suddenly there are coal mines being developed and reserve estimates continue to climb. And the Chinese are helping, since this could be another source for future supplies and so the reserve base is climbing (up to 200 billion tonnes ).

Even in the UK the need to meet future energy needs (as opposed to goals) are causing the government to have a bit of a rethink on their coal-fired power plans.

Coal's biggest competitor at the moment is natural gas, and the plentiful cheap supply of this to power plants is restricting and confining the coal market. However there is a production cost and ability to gas from shale, that Art Berman has written about, that will, over time likely reduce the volumes that are available at a competitive price, relative to the price and availability of coal for power stations. At which time coal supply will require the conversion of more of what is now only a resource, back into a reserve.

Here are some of my thoughts:

First, why ask how much coal we have? Don't we want to reduce or eliminate coal because of climate change?

Yes, we do. For better or worse, however, it's important to be realistic about the availability of coal. If we're not running out of it, we have to make a conscious decision to eliminate it, not rely on geological limits. Also, it's good to know whether or not we'll face energy shortages due to coal scarcity. If not, we have more options - if we face an emergency, we will have the option of using coal. Of course, that may be expensive and difficult to do without excessive CO2, but options are usually good to have. In that vein, we should note that if we have coal to spare it's actually easier to sequester CO2 - sequestration consumes a fair amount of energy, and if things are tight it will be much harder to pay for something whose necessity isn't obvious to all .

So, do we face limits on our coal production, as a practical matter?

No. Coal is unlike oil - we have enormous reserves, we know where they are, and in many cases there is no significant increasing marginal cost to their extraction, except for temporary costs of expansion.

Do higher energy prices raise the costs of extracting fossil fuels?

It depends on the individual case. Coal has a high E-ROI. For instance from a recent survey by Heinberg ( from http://www.theoildrum.com/node/4061 ): "Consider the case of Massey Energy Company, the nation’s fourth-largest coal company, which annually produces 40 million tons of coal using about 40 million gallons of diesel fuel—about a gallon per ton" .

That's a very high E-ROI: a gallon of diesel is about 140K BTU's, and a ton of coal is very roughly 20M (see http://www.uwsp.edu/CNR/wcee/keep/Mod1/Whatis/energyresourcetables.htm ), so that's an E-ROI about 140:1! Now, diesel costs very roughly 10x as much per BTU (reflecting it's scarcity premium), so the cost ratio isn't quite as favorable, but it's still well above 10:1. So, the price of diesel rises by $1 (roughly 25%), and the cost of coal rises by $1, or very, very roughly 2% - not a big deal. Also, we should note that coal mining (and transportation) is often electric even now (especially underground), and that it's pretty amenable to further electrification - in other words, coal mining can power itself using a small fraction of it's production.

Will higher coal prices make a substantially larger fraction of the coal available for extraction?

Yes, but only slightly higher prices are needed. Here's what Heinberg has to say: "if Montana and Illinois can resolve their production blockages, or the nation becomes so desperate for energy supplies that environmental concerns are simply swept away, then the peak will come somewhat later, while the decline will be longer, slower, and probably far dirtier.". The Montana "production blockages" he talks about are relatively trivial, and Illinois doesn't really have them. The pollution he refers to is CO2 and sulfur - the sulfur costs about 2 cents/KWH to scrub, and the CO2 might cost out at $80/ton of CO2, which IIRC would add about $30/ton of coal, should we choose to internalize this cost.

Illinois coal simply couldn't compete with Powder River coal with a 2 cent premium for sulfur scrubbing - it's as simple as that. UK and German coal became a bit more expensive, and they couldn't compete with cheap oil.

The same general rule applies to US, UK and European coal: only under Business As Usual is coal declining. I discussed this at length with David, and I thought we came reasonably close to some kind of agreement on this. If there are serious energy shortages, the old reserve numbers will apply, for better or worse.

So, would a doubling in coal prices substantially increase recoverable coal reserves?

Yes. Now, "recoverable" is tricky: the normal distinction used by the USGS is "economically recoverable" - that includes economic assumptions, and Illinois coal (and much other coal in the world), at a slightly higher cost as discussed above, is currently uneconomic. But, that's under Business As Usual - if we have a true energy scarcity, Illinois coal will very, very quickly become economic.

What about the "Law of Receding Horizons"?

That applies only to low E-ROI sources of energy. Coal is high E-ROI, unlike Canadian bitumen (tar sands) or Colorado kerogen (oil shale). I would note that the importance of this "law" has been enormously exaggerated, as it's confused with temporary capex issues and scarcity premia, which are allocating temporarily scarce capital resources.

More coal gets extracted from the ground each year as measured in tons, but hasn't the quality declined so much that net energy content is lower now than 10 years ago?

Powder River coal is lower energy density (sub-bituminous), but it's sufficiently cheaper to mine that the difference doesn't matter. Again, this is a purely economic shift from Illinois coal, which is higher energy density (bituminous). This shift has caused endless confusion to analysts unfamiliar with the coal industry (OTOH, people inside the industry understand this).

Aren't coal prices rising?

In many cases, this is due to the temporary costs of expansion. Oil & gas are much more expensive per BTU due to a scarcity premium, and so demand has increased for coal. Most coal is on long-term contract, not on the higher spot market (unlike oil). But it's important to be clear that in many places, like the US, the long-term marginal cost of extraction isn't really increasing, as it is for oil.

Is Coal-to-Liquids (CTL) feasible?

Yes, but projects tend to be large and expensive, and would be CO2 intensive. That means that investors would like federal loan guarantees, but that such guarantees are unlikely. Nevertheless, CTL is cost-effective even with fairly high carbon taxes, with oil prices at anything like the current level , and projects are slowly moving ahead . The best path would be CTL with CO2 sequestration - this would deserve guarantees.

Is oil-shale feasible?

With oil over $100/barrel, the answer is almost certainly yes. There's something like a $50T incentive there for exploitation, and somebody is going to make something work. In that way its similar to the Bakken basin, which may have 400B barrels of true oil, though only 4B is economically recoverable right now.

Kerogen has the advantage of not needing hydrogenation (which is needed for both tar-sands and CTL), which requires expensive natural gas or a combination of added energy and water (also a significant cost).

On the other hand Green River kerogen (mis-named oil shale) is low density, and a pain to dispose of after burning (it expands). That's why even low-value coal is more attractive for burning (which is what the Estonians do with it). That's also why retort conversion to oil (the conventional method) is unattractive, and why Shell is considering in-situ conversion instead.

Further, kerogen requires a lot of energy to upgrade - the Shell process looks very much like a very slow, inconvenient method of converting electricity to oil (kind've like ethanol, except ethanol mostly uses natural gas). All in all, it seems inevitable to me, but not cheaply or at large volumes any time soon.

I wouldn't reject it, as it is extremely valuable to have diversity in energy supply, but it would be much better to concentrate on electrifying our vehicles ASAP. In other words, we can't let it distract us from the main and best solutions available to us, which are, unfortunately, inconvenient for oil & gas and car companies.

Perhaps most importantly, kerogen burns quite nicely. If we were to run out of coal, we could certainly burn kerogen, and we certainly would before we let the lights go out.

When Dave first posted here 3 years ago I was very much on the side of Heading Out, believing that the death of the UK coal industry was down to Thatcher, politics, economics and Norwegian trout that reportedly did not like the acid from our S rich coal. But I see things rather differently now, in no small measure to Dave's work.

First part of learning curve is to see where Thatcher and the miner's strike (1984 - 85) fits into the long-term decline of UK coal, that began sometime around the decision made by Churchill (then first lord of the admiralty) to convert the Royal Navy from coal to oil - the rest is history.

The rest of the debate is rather more complex. 19th and 20th Century infrastructure - cities, railways, docks, power stations etc. got built close to the most easy to access supplies of energy. Now infrastructure is in the wrong place for what remains.

Heading Out's point about Botswana is a good one. In Africa at least, the coal isn't there because it hasn't been looked for. Or, someone knows where it is, but circumstances haven't been right to make it economic. As Africa urbanises and develops over the coming century, I guess that its reserves will increase greatly, at least for a few decades.

This is by way of introduction to a larger point. Statistical regularities are where science begins, not where it ends.

Dave's statements that he became dissatisfied with Hubbert linearization because of fluctuations and that "Hubbert linearization is based on the logistic function, and a cumulative normal is a better fit for some regions" set off a warning bell in my head.

The first rule of applied statistics is, don't change your model just to get a better fit. There has to be an underlying reason to do so. What physical and social processes are going on, that mean that a cumulative normal is a better model than the logistic?

I fail to see how any prediction can be made with confidence, without being reasonably sure about the underlying physical and/or social mechanisms. Simple extrapolation of an observed but not explained regularity is the way to go badly wrong. Changing your model "to get a better fit" is a way to go worse wrong.

TOD would gain by having more exposition, and more careful discussion, of these underlying mechanisms and their interaction -- or what we believe them to be. Without a plausible underlying model, statistical extrapolations are, and should be, easily dismissed. The model must be made more explicit.

Interestingly the statistician here, WebHubbleTelescope, has a model - the dispersive discovery model. It seems to me to have great power even though it is very abstract. The question is, can others do better with more detailed, less abstract abstractions?

Dave (or anyone),

I had a quick look at your excellent paper and saw that you don't give estimates of Peak Coal (t50's) presumably because of uncertainties and irregular production curves.

Yet many of us are used to thinking that peak dates are relatively important as they indicate a rise in prices (and economic effects) as demand starts to exceed supply. Are you at all able to tell from your analysis (by making a cumulative plot of all the regions, for instance) when world demand starts to exceed supply? Or do you just reckon we'll, more or less, just see a monotonically increasing price over time?

This analysis is deeply flawed.

There are good reasons why Hubbert linearisation may provide useful estimates of ultimate recoverable oil and gas. The logistic function is a simple (the simplest) representation of a unique, continuous scarcity process constraining growth. In global O&G, we understand the process well - most production is from giant fields that are geologically rare and unlikely to be replicated in future discoveries; scale is such that multiple smaller fields cannot replicate giant field production; most production is by straightforward multi-phase fluid flow to isolated well points, which cannot be greatly enhanced beyond physical limits. There are even decent arguments why a Gaussian linearisation might sometimes be superior (aggregation of multi-site production curves may be loosely analagous to the aggregation of the central limit theorem).

But coal is not like that. Sure, in certain regions, at certain times, scarcity processes will be at work that we should expect to result in behavior approximating a logistic (or Gaussian) model. But it is wrong to assume that those processes are stationary and immutable (as we think they are for conventional O&G). As I've argued before, the coal resources of this planet are poorly known and probably gigantic. It is naive to assume that, in the absence of meaningful energy alternatives (and in the absence of economic collapse*), they will not be exploited; exploited following scarcity processes very different to today's. Of course, Work Return on Work Invested (not EROEI) needs to be significantly > 1, but that is not an issue at the depths in my example (typically < 500-1000 m).

G.

(* The only really likely reason, given what we know to expect from conventional O&G depletion.)

Every continent seems to have large deep and remote coal deposits. Some think in situ gasification will extract that carbon when conventional mining is unviable. However UCG is not going so well in places and the prospects don't look good.

In some countries there is talk of serious financial penalties for CO2 release. Suppose minemouth sub-bituminous coal cost $20 a tonne to produce. Now suppose carbon tax was $25 per tonne of CO2. Using a factor of 2.4 (not the 2.86 mentioned upthread) that tonne of coal will cost another 2.4 X $25 = $60 of carbon tax. That quadruples the effective cost from $20 to $80. Some say much higher carbon taxes will be needed to make carbon sequestration economic or to give a clear advantage to gas generation. That's combined cycle gas without carbon capture and storage CCS. This is why there is no chance of serious carbon taxes in coal dependent nations like Australia.

However even the talk of carbon taxes has created paralysis among utility companies. If they build a coal plant now without CCS they could be financially crippled if the carbon tax comes in some years later. In Australia Big Coal seems to be saying let's build now and add CCS later while cleantech is saying we want carbon taxes now. I think Big Coal will win this round only to find Asian demand makes coal expensive anyway.

http://www.abc.net.au/news/stories/2010/12/07/3086585.htm?section=justin
Mines hit hard by heavy rainfall
By Debra Nowland
Updated Tue Dec 7, 2010 9:56am AEDT

"The early start to this year's wet season could put mines at risk (ABC News: Paul Robinson)

In central Queensland, coal mines look more like dams, and in some cases flooding has disrupted operations since September.

Mining companies say they are now re-assessing whether they can meet their export orders, but the mining union is accusing them of poor planning....
In recent years, coal companies have been living in a bit of a fool's paradise, we've had more than 10 years of drought," he said. "The older, wiser heads, that knew about how to set open cut mines up with water management ... have retired," he said.

"The double whammy is that they don't have their mining operations set up to deal with the wet weather," he said.

"So they not only lose production, but they also lose time having to clean their operations up and get them back into running order before they can get back into production mode."

A major environmental risk is the run-off from flooded mine sites.

Mr Roche says the water has nowhere to go and wants authorities to be flexible with its release.

"Not to introduce any environmental harm to the state but to deal in a pragmatic way with huge amounts of water built up in dams, which could be perhaps put into flowing water courses without any environmental harm," he said.

Part of the funding for my PhD (a long time ago, I am retired now) came from the gas industry who were worried than the conversion of the domestic gas supply from town gas to natural gas was irreversible and that they needed to be able to make methane from coal after the North Sea reserves were exhausted.

Their opinion at that time was definitely that the reserves were still there, and could be brought into production if there wasn't a cheaper source of energy. The coal industry (also nationalised at that time) definitely considered itself to be in decline and my dealings with them were more along the lines of technology that could be used with imported coal, rather than british coal.

So I think the characterisation of Britain as being pretty much mined out is fair, and it is ineresting to see just how close the estimates made 150 years ago were. I would say a 3-fold overestimate, when the context required an over rather than an underestimate, was an extremely good prediction to make in 1861.

I am curious to know how good a curve fitted to the pre-1861 data would be. Dropping back 15 years and seeing no great variation isn't all that compelling because that is still well after the decline had set in. A good fit with the eventual outcome based on the pre-1861 data would be. The basic problem with curve fitting techniques is always that they are fine for interpolation, but extrapolation fails unless the decline is already obvious.

Also, while it is reasonable to treat oil as independent from coal, I doubt the reverse is true. Oil has a large demand that cannot be easily substituted by other energy sources, so analysing it in isolation is reasonable. Coal doesn't. Its production depends not only on the availability of coal, but also on the availability of other fuel supplies. I think you need to consider the reserves of coal plus all more easily utilised fuels together, rather than coal on its own. Going back where I started, coal use was run down in Britain because gas became available, and the contingency plan then was to manufacture gas from imported coal after the local gas reserves were exhausted.

Finally, once again going back to 1861, the estimates made then assumed deeper and thinner seams would eventually get mined, than actually have been. What happens if the experience of the geology that actually did get mined in a depleted region like Britain, is used to refine global estimates of reserves? How does the figure that gives stack up against the curve extrapolation?

So we have two issues: essentially how much recoverable coal there is, and how much is point of no return or at least very serious damage from climate change perspective. It seems that the latter number (as currently known) is lower or similar to the former. If we recover recoverable coal (and add gas and oil), we will simply cook the Earth? Prettty much regardless of the model?

So we have no choice but to leave carbon underground in any case. Yes, from scientific,geologic and economic standpoint it is good to know, but from practical standpoint we already have all we should use?

As they say the discussion is academic?

As indicated up thread I am not going to permit a debate here about the impacts of CO2 on climate change. Some may want to allege links between CO2 and what are viewed as anomalous climatic events. Personally I'd point to the geological record for the last 10,000 years which shows cyclic, rhythmic shifts in the pattern of the Indian Ocean Monsoon - and as a geologist I have faith in what the geological / isotope geochemical record tells me.

Discussing fossil fuel constraints on CO2 emission scenarios is on limits, speculating about the impact of CO2 on climate is not. If you want to discuss climate change please go do it on another blog.