Natural Resources Committee on May 14th, 2007

Thank you very much.

You are correct, the international partnerships deal with such things as nuclear energy storage and waste.

The committee will be briefed on that issue in the coming days. I would prefer letting the experts answer that question.

I'd like to start, perhaps, and then you can continue, Graham.

Many of the first applications of carbon dioxide capture and storage will be for use in enhanced oil recovery. What happens there is they're using the carbon dioxide to actually pressurize older wells and extract even more oil, oil they would not have been able to extract, so that is another form of wealth for the country.

Following that, we're developing technologies to extract methane out of coal seams that are not mineable. They're not accessible, and if you can pressurize that, you could actually extract natural gas, which is a very useful fossil fuel and a relatively clean fossil fuel. There are some benefits to Canada from carbon dioxide capture and storage.

I'll add briefly that as our companies get better experience, they basically offer the services and the knowledge to other countries that are also growing rapidly and also developing power. This match works best if the coal quality or the coal type in that country matches well with Canada's. Several countries have that characteristic, so there are some opportunities to reap in the long term as well.

Thank you, Mr. Chair.

Thank you for your presentations.

I've got a couple of quick questions. I want to pick up on the theme that we can't clean anything up that we have. That concerns me more than a bit.

Are you aware of the Phoenix technology? It's based on the technology that captures the emissions from the space shuttle as it takes off. It's written by NASA. We had a presentation from them, and it would seem to me that they're a long way toward reducing more than 90% of the emissions. They can also do carbon dioxide capture; they do it in a very small bolt-on to a plant. They're looking to try to test this in some smaller coal plants of 100 to 200 megawatts.

Are you guys familiar with that kind of technology?

No, we are not familiar with that technology, but we will note that and look into it.

I'll get you the information. It just concerns me that we're throwing our arms up in the air and we can't do anything to replace it with this kind of technology out there.

Second, what are the practical limits when you look at where carbon dioxide can be stored? What is the practical limit for transporting it to any particular area?

We transport natural gas from all the way out in western Canada to eastern Canada. We're actually thinking of eventually using such an infrastructure to transport carbon dioxide, but the other way. I don't know of any limitations in terms of distance. These, of course, would have to go through.... It's just a question of money, and repressurization plants and so on, to keep it moving to the storage site.

The most costly part of this whole system we're talking to you about today is the capture of the CO₂. Transporting the CO₂ is conventional pipeline technology, and it's well established. Areas in the United States, for example, have been using CO₂ pipeline technology for decades to support enhanced oil recovery in their fields. It's really not seen as an impediment.

The challenge in Canada, particularly in western Canada, is that the CO₂ sources are in a particular location and the places you'd want to use it for enhanced oil recovery or for deep sinks are in other locations. We need transportation infrastructure to connect up the sources and the uses of CO₂, but that's in the area of capital investment, not in the area of technology, in terms of the challenges before us. Really, the transportation is not an issue for us.

Thank you.

If my understanding is correct, you are referring to post-combustion capture. Certain materials help absorb carbon dioxide and then release it. However, the technology you are referring to is used in the pulp and paper industry, that is on a much smaller scale than what is being studied here. Very large vessels are needed to modernize a conventional plant, such as the one in Nanticoke.

Thank you very much for the opportunity to speak to you today.

I have quite a number of slides, so I'll do a quick page flip and try to stay within the time limit of 10 minutes.

There is a presentation outline on page 2. The topic is the current status of clean coal technologies. First of all, I'll give an overview of the CCPC and discuss some results of our early phases one and two, as we call them, provide some insight into projects that were borne out of earlier CCPC work, and then briefly cover off the next step, the phase three plans.

Page 3 indicates that it is no surprise to anyone that Canada has substantial fossil fuel reserves. Coal is by far the significant portion of these reserves, and these reserves will last for many centuries.

Page 4 talks about the Canadian Clean Power Coalition, which was formed in 2000. It's an association of predominantly Canadian, but also U.S., coal and coal-fired electricity producers. There are also participating coal miners. It's also an industry-government partnership, both federal and provincial. The objective is to demonstrate that coal-fired electricity generation can effectively manage all the environmental issues of concern. When I speak of that, there are usually five emissions of concern, and that's NOx, SO₂, particulates, mercury, and also CO₂. An additional requirement was to demonstrate flexible fuel capability, given the range of carbon-based fuels we have across the nation, and our website is there for anyone who wishes to go to it.

On page 5 there's a list of the coalition participants.

Page 6 indicates that government participation to date has been through Natural Resources Canada. I might at this point add my thanks to Natural Resources Canada for funding in the past, and hopefully funding in the future for some of our continued efforts. There's also the Alberta Energy Research Institute, which is the funding arm of the Alberta government, and Saskatchewan Industry and Resources, the funding arm of the Government of Saskatchewan, which has also participated to date.

Some of our early results are shown on page 7. It's a fairly complicated slide, but suffice it to say that we've looked to date at a range of coal types--lignite, which is the lower end of the quality of coal, sub-bituminous, the mid-ranked coal, and bituminous coal--and applying different technologies sort of across those different types of coal: conventional pulverized coal technology as well as coal gasification. The inclusion of CO₂ capture with those technologies increases the cost of electricity significantly in that work and certainly above that of conventional coal without CO₂ capture. However, the results show that both capital costs and costs of electricity are reduced by moving from conventional PC technology to technologies like coal gasification with CO₂ capture included. In all of these cases, we've also included the reduction of NOx, SO₂, particulates, and mercury, reducing those by up to 90% compared with the current pulverized coal technology.

On page 8 there's an idea, in a sense, of the CO₂ storage and utilization options, particularly in the western Canadian sedimentary basin. Of course, capturing CO₂ from these processes requires a pipeline infrastructure and the ability to store CO₂ in depleted reservoirs, all for use preferably in enhanced oil recovery. Both EOR and storage capabilities are available in Saskatchewan and Alberta, and maybe a little bit in Ontario, as we've heard, certainly in the U.S., and perhaps offshore Nova Scotia.

So that's where we got to with respect to our phase one work that we completed in 2003.

Page 9 shows that phase two continued, and, as with all studies, the technology knowledge gaps were identified, requiring further investigation. So phase two of our work began with the objective of answering these knowledge gap questions with a focus on low-ranked coals, particularly lignite and sub-bituminous, which occur in western Canada, and using coal, looking at coal gasification, oxy-fuel combustion, and post-combustion pulverized coal emissions cleanup.

In addition, we've also looked at the merits of what's called polygeneration. I know someone asked the question about FutureGen. FutureGen is an example of a polygen project, which basically is a simultaneous production of not just power or electricity but also other chemical products, like hydrogen, substitute natural gas, diesel, and so forth.

Page 10--the preliminary indications of the phase two work--shows that the phase two work is nearing completion. Preliminary results indicate, though, that through design integration we can improve the efficiency of coal gasification, IGCC, with CO₂ capture, certainly using low-ranked coals, significantly compared to our initial phase one work, and of course that efficiency improves the overall economics.

With reference to the next slide, and the recent cost escalations in terms of steel, concrete, labour, we're actually reworking our numbers on those costs. So those numbers shown on the next slide--page 11--are not available today, but I can make them available when we've completed the work.

It's a relative comparison, and clearly sub-bituminous coal in Alberta, and particularly with CO₂ capture, begins to improve the economics of IGCC and coal gasification, particularly where there's a saleable product, such as CO₂ for enhanced oil recovery.

With lignite coal, IGCC may not be the best current solution. As Saskatchewan Power have decided, they're pursuing oxy-fuel as a solution to their lower-ranked lignite coal.

On page 12, we did actually look at the supercritical plant burning a variety of coals and capturing CO₂ through an oxy-fuel process or amine scrubbing, which is a post-combustion cleanup process.

On page 13, that's the legend with respect to the previous slide.

On page 14, you can see there are significant improvements that can be made in terms, certainly, of CO₂ capture with all of the technologies--oxy-fuel, amine scrubbing, and IGCC, coal gasification.

On page 15, our work to date has really concluded that all emissions of concern--NOx, SO₂, particulates, mercury, and CO₂--can be reduced significantly for coal-fired electricity generation, simply using technology or developing the technology for use.

So what are the next steps towards commercializing clean coal technology? On page 16 I will highlight two spinoff projects that are now under development: first, the SaskPower project; and secondly, the EPCOR project.

The SaskPower project will use supercritical pulverized coal technology and an oxy-fuel, oxygen-rich process. Capacity is about 300 megawatts. It includes CO₂ capture. The fuel is lignite fuel, so a low-ranked coal. The pre-engineering work is nearing completion, and a decision to proceed towards construction is expected this year. The planned in-service date, I understand, is 2012.

The CCPC/EPCOR IGCC project--and by the way, I'm an employee of EPCOR--is a $33 million, three-year, front-end engineering design project. We are now looking at probably around a 500-megawatt coal gasification plant. This is page 18, by the way. It includes CO₂ capture and storage.

The funding is one-third industry, one-third Alberta government, and--we're hoping--we're working with the NRCan people with respect to one-third funding from the federal government.

The fuel is from Genesee in Alberta, sub-bituminous coal. The project commenced in October 2006 because we had enough funding in place to commence the project. The first phase is the technology selection process, as we call it, which is expected to be completed this year. We're looking at four or five different coal gasification technologies at the moment. The idea is to select one, and then we'll base the front-end engineering design on that particular chosen technology. The FEED, the front-end engineering design, is planned for completion in 2009, by which time we would then be in a position to make a decision on construction of that plant.

As indicated on page 19, phase three plans of CCPC are to assess technology improvements on an ongoing basis; evaluate new and emerging technologies; participate with other organizations, either nationally or internationally, on clean coal technology initiatives; and develop an information database to really capture all the learning we have accrued to date.

Those are my comments, Mr. Chairman. I hope I've stayed within the 10 minutes.

Certainly, I'll try to do that, remembering that this is a work in progress.