Thank you.
Good morning to committee members and staff. I am pleased to be here with you today to provide my perspective on recent efforts by Capital Power on our front end engineering and design study related to integrated gasification combined cycle and carbon capture and storage project. Before I do that, I'd like to give you a little bit of information about Capital Power, as it is a new name in Canada.
Capital Power was launched last July through a $500 million IPO. The company was created when EPCOR Utilities of Edmonton spun off its generation business. Today our assets are approximately $5 billion. Capital Power and its affiliates develop, acquire, and operate power generation from a wide range of energy sources, including coal, natural gas, waste heat, hydro, biomass, and wind. The company has 3,500 megawatts of capacity and interests in 31 facilities across three provinces and five states. Our company was the first to reintroduce supercritical coal combustion technology to North America, and it operates the cleanest coal-fired plant in Canada.
Finally, we have been a leader in Canada's effort to commercialize near-zero emissions coal-powered technology. As we look to the future, we see that North America's population will continue to grow, and so will our economy. We also know that aging infrastructure will need to be replaced to meet the growing demand for reliable, affordable, environmentally responsible electricity across North America and worldwide. We believe the best way to meet this demand is to provide power from a mix of fuel sources, including coal.
Consider these facts. Approximately one-fifth of Canada's energy is generated from coal. Not only is coal the most abundant and cheapest energy source in Canada, with reserves that will last hundreds of years, it's also stable and a low-cost source of energy. Internationally, coal is even more prominent. The United States and China are the world's largest coal producers, with 60% and 80% respectively of their electricity generation from coal. Coal will continue to be a very significant energy source in Canada and on a worldwide basis. With new technologies and carbon capture and storage being developed by a worldwide effort, overall greenhouse gas emissions from the power generation industry will be reduced while enabling Canada's vast coal reserves to continue as a viable and efficient option for power generation for many years to come.
One of those technologies that make CCS possible in Canada and the United States is coal gasification. Coal gasification combines heat and pressure to break coal down into its chemical components, creating a synthesis gas that is mainly hydrogen. This gas is then burned cleanly in a gas turbine to create electricity. With the help of a few chemical processes, a pure stream of carbon dioxide is also produced, and this can be captured and stored in saline aquifers. This CO2 can also be beneficially used for an enhanced oil recovery, a process by which the CO2 is injected into oil wells. This allows more oil to be recovered and provides revenue generation opportunities.
Combining an integrated gasification combined cycle plant, or IGCC, with a carbon capture facility that would capture CO2 results in reductions in CO2 emissions by 85% to 90%. This is approximately one-third of what is emitted from natural gas combined cycle. Compared to supercritical coal facilities, IGCC technology has the potential to further reduce nitrogen oxide, particulate matter, and sulphur dioxide, by over 99%, and mercury by almost 70%. CCS and gasification technologies do exist. The science is sound. What we need to do is demonstrate these two technologies together on a commercial scale.
Over the past four years, a great deal of work has been done toward achieving this important goal. Following on the work of the Canadian Clean Power Coalition, Capital Power has undertaken the detailed design of a 235-megawatt IGCC facility with carbon capture and sequestration.
With an investment of $33 million in equal parts from Capital Power, the Government of Canada, and the Government of Alberta, the front-end engineering and design, or FEED, study will be finalized over the next few weeks. This project was specifically designed for operation at the Genesee generating station in Alberta. As this is a site-specific design, the specific details cannot be utilized on a generic basis; however, the learnings and the validation of technology can.
While we can confidently say the technology is solid and the facility could operate at the availability and efficiency levels we predicted, the business case is not there for an independent power producer in Alberta to go it alone at this time. In our environment of low power prices and capital-intensive technology, industry would need significant help from government to make the first-of-a-kind facility commercially viable in Alberta. We expect the economics of building and operating such a facility to become more attractive as recent technology breakthroughs become more widely available and as newer technologies advance. For example, we're already seeing significant strides in the development of lower-cost technologies, such as membranes for air separation. This means that a plant like this could become economically feasible without subsidy within the next 10 to 15 years.
What is important is that industry and government continue to explore options together so we can make intelligent, well-informed decisions as we move forward on a path to a smaller carbon footprint. What we have today, as a result of this study, is critical information and a major step forward for a relatively small investment over a four-year period. We can soon provide decision-makers with a true understanding of the costs of this technology and comfort that it will actually work, as we now have a benchmark against which to compare other technologies to in order to help us determine which ones make the most sense to pursue.
In conclusion, the commercialization of technology solutions, including CCS and synthetic gas technology, will ensure that we can count on a long-term source of near-zero-emission baseload power for the future. Future policies need to balance the need for investment in the critical power generation infrastructure with the requirement for targeted environmental regulations to transition Canada to a lower carbon future. In addition, because of our industry's long capital life cycles, policies must recognize the costs of investments made in generation infrastructure by ratepayers and investors. Great progress is being made towards the commercialization of these new technologies, and while much remains to be done, I'm confident we can get there through a combination of good public policy, technological investment, and industry and government working together towards the goals for our common future.
I look forward to your questions.
