References
- Weisz, P. B., (2004), Basic choices and constraints on long-term energy supplies, Physics Today, July, pp. 47–52; Bartlett, A. A., Thoughts on long-term energy supplies: Scientists and the silent lie, Physics Today, July, pp. 35–55.
- Edwards, J. D., (2001), Twenty-first Century Energy, American Association of Petroleum Geologists Memoir 34, pp. 21–34.
- Weisz, P. B., (2004), Basic choices and constraints on long-term energy supplies, Physics Today, July, p. 47.
- Figures derived from data in the United States Department of Energy’s International Energy Annual for 2002.
- Bradley, R. S., M. K. Hughes, and H. F. Diaz, (2003), Climate in medieval time, Science, 302, pp. 404–405; Hansen, B., S. Østerhus, D. Quadfasel, W. Turrell, 2004, Already the Day After Tomorrow?, Science, 305, pp. 953–954; Broecker, W. S., 2001, Was the medieval warm period global?, Science, 291, pp. 1497–1499.
- Gerhard, L. C., (2004), Climate change: Conflict of observational science, theory, and politics, Bulletin of the American Association of Petroleum Geologists, 88, 9, pp. 1211–1220.
- Kerr, R. A., (2004), Three degrees of consensus, Science, 305, pp. 932–934.
- Ayers, W. B., Jr., 2002, Coalbed gas systems, resources, and production and a review of contrasting cases from the San Juan and Powder River basins, Bulletin of the American Association of Petroleum Geologists, 86, 11, pp. 1853–1890.
- Curtis, J. B., (2002), Fractured shale-gas systems, Bulletin of the American Association of Petroleum Geologists, 86, 11, pp. 1921–1938.
- Law, B. E., (2002), Basin-centered gas systems, Bulletin of the American Association of Petroleum Geologists, 86, 11, pp. 1891–1920.
- Collett, T. S., (2002), Energy resource potential of natural gas hydrates, Bulletin of the American Association of Petroleum Geologists, 86, 11, pp. 1971–1992.
- See Sheffield, J., 2004, Future world energy demand and supply: China and India and the potential role of fusion energy, Proceedings 16th ANS Topical Meeting on the Technology of Fusion Energy, September 14-16, 2004, Madison, WI, in press.
- Hubbert, M. K., (1956), in Drilling and Production Practice, American Petroleum Institute, Washington D.C. and 1967, American Association of Petroleum Geologists Bulletin, 51, pp. 2207; Campbell, C. J., and J. H. Laherrere, 1998, The end of cheap oil, Scientific American, March, pp. 78–83.
- Edwards, J. D., (2001), Twenty-First Century Energy: Decline of Fossil Fuels, Increase of Renewable Non-Polluting Energy Sources, American Association Petroleum Geologists, Memoir 34, pp. 21–34; See Ball, J., 2004, As prices soar, doomsayers provoke debate on oil’s future, The Wall Street Journal, September 21, pp. 1 and 14.
- Freme, F., (2004), Coal, Mining Engineering, May, pp. 38–39.
- Jenkins, H. W., Jr., 2004, The upside of higher oil prices, The Wall Street Journal, May 19, p. A19; Leeb, S. and D. Leeb, 2004, The Oil Factor, Warner Business Books, New York, pp. 35–41.
- See Sheffield, J., 2004, Future world energy demand and supply: China and India and the potential role of fusion energy, Proceedings 16th ANS Topical Meeting on the Technology of Fusion Energy, September 14-16, 2004, Madison, WI, in press.
- Shogren, J. F., (2004), Kyoto Protocol, past present, and future, Bulletin of the American Association of Petroleum Geologists, 88, 9, pp. 1221–1226.
- Kazimi, M. S., (2003), Thorium fuel for nuclear energy, American Scientist, 91, pp. 408–415.
- Butler, D., (2004), Nuclear power’s new dawn, Nature, 429, p. 238.
- See Leeb, S. and D. Leeb, 2004, The Oil Factor, Warner Business Books, New York, p. 68. Meserve, R. A., 2004, Global warming and nuclear power, Science, 303, p. 433; Butler, D., 2004, Nuclear power’s new dawn, Nature, 429, pp. 238–240.
- Potter, C. J., W. C. Day, D. S. Sweetkind, and R. P. Dickerson, Structural geology of the proposed site area for a high-level radioactive waste repository, Yucca Mountain, Nevada, GSA Bulletin, 116, p. 858879.
- See Dawson, J., 2004, Court rules against 10,000-year radiation safety standard at Yucca Mountain, Physics Today, pp. 29–30.
- Jensen, K. A., R. C. Ewing, (2001), The Okelobondo natural fission reactor, southeast Gabon: Geology, mineralogy, and retardation of nuclear-reaction products, GSA Bulletin, 113, pp. 32–62.
- U. S. Department of Energy, 2004, A technology roadmap for Generation IV nuclear energy systems, http://gif.inel.gove/roadmap/pdfs/gen_if_roadmap.pdf.
- Joint announcement from the Bush-Putin Summit discussions, July 2002.
- Paacala, S., and R. Socolow, (2004), Stabilization wedges: Solving the climate problem for the next 50 years with current technologies, Science, 305, p. 971; Leeb, S. and D. Leeb, 2004, The Oil Factor, Warner Business Books, New York, pp. 82–87; Turner, J., 1999, Science, July 30; Weinberg, C. J., and R. H. Williams, 1990, Energy from the sun, Scientific American, September, pp. 147–155.
- Denholm, P. L., (2004), Environmental and policy analysis of Renewable Energy Enabling Technologies, Ph.D. Dissertation, University of Wisconsin-Madison, 259 p.
- Leeb, S. and D. Leeb, (2004), The Oil Factor, Warner Business Books, New York, pp. 76–77.
- See Denholm, P. L., 2004, Environmental and policy analysis of Renewable Energy Enabling Technologies, Ph.D. Dissertation, University of Wisconsin-Madison, pp. 9–11 and 43–51; White, S. M., 1998, Net Energy Payback and CO2 Emissions from Helium-3 Fusion and Wind Electrical Power Plants, Ph.D. Dissertation, University of Wisconsin-Madison, 166 p.
- Meier, P. J., (2002), Life-cycle Assessment of Electricity Generation Systems and Applications for Climate Change, Policy Analysis, Ph.D. Dissertation, University of Wisconsin-Madison, 147 p.
- NASA, 1975, Energy-related Research and Development, prepared for the Committee on Aeronautical and Space Sciences, United States Senate, by the Office of Energy Programs, 131p.
- Myers, N., (2000), Sustainable consumption, Science, 287, p. 2419; Turner, J. A., 2004, Sustainable hydrogen production, Science, 305, pp. 972–974.
- Fickett, A. P., C. W. Gellings, and A. B. Lovins, (1990), Efficient use of electricity, Scientific American, September, pp. 65–74.
- Ross, M. H., and D. Steinmeyer, (1990), Energy for industry, Scientific American, September, pp. 89--98.
- Bevington, R., and A. H. Rosenfeld, (1990), Energy for buildings and homes, Scientific American, September, pp. 77–86.
- Dmirdoven, N., and J. Deutch, 2004, Hybrid cars now, fuel cell cars later, Science, 305, pp. 974–976; Bleviss, D. L., and P. Walzer, 1990, Energy for motor vehicles, Scientific American, September, pp. 103–109.
- Petroski, H., (2003), Fuel cells, American Scientist, 91, pp. 398–402; Service, R. F., Newcomer heats up the race for practical fuel cells, Science, 303, p. 29.
- Fickett, A. P., C. W. Gellings, and A. B. Lovins, (1990), Efficient use of electricity, Scientific American, September, pp. 65–74.
- Garrett, S. L., and S. Backhaus, (2000), The power of sound, American Scientist, 88, pp. 516–525.
- Kirsh, D. A., (2000), The Electric Vehicle and the Burden of History, Rutgers University Press, 256 p.
- Fickett, A. P., C. W. Gellings, and A. B. Lovins, (1990), Efficient use of electricity, Scientific American, September, pp. 65–74.
- Leeb, S. and D. Leeb, (2004), The Oil Factor, Warner Business Books, New York, p.71.
- Paacala, S., and R. Socolow, (2004), Stabilization wedges: Solving the climate problem for the next 50 years with current technologies, Science, 305, pp. 968–972; Leeb, S. and D. Leeb, 2004, The Oil Factor, Warner Business Books, New York, pp. 84–87; Holdren, J. P., 1990, Energy in transition, Scientific American, September, pp. 157–163.
- Smith, A., (1776), An Inquiry into the Nature and Causes of the Wealth of Nations, see reprint in Great Books of the Western World, Encyclopedia Britannica, Chicago, 36, pp. 217.
- Grant, P., (2003), Hydrogen lifts off - with a heavy load, Nature, 424, pp. 129–130; Service, R. F., 2004, The hydrogen backlash, Science, 305, pp. 958–961.
- Service, R. F., (2004), The hydrogen backlash, Science, 305, pp. 958–961; Turner, J. A., 2004, Sustainable hydrogen production, Science, 305, pp. 972–974.
- Cho, A., (2004). Fire and ICE:Revving up for H2, Science, 305, pp. 964–965.
- Hazeltine, R. D. and S. C. Prager, (2002), New physics in fusion plasma confinement, Physics Today, July, pp. 30–36; Barabaschi, P., and Y. Shimomura, 2004, ITER Status, Proceedings 16th ANS Topical Meeting on the Technology of Fusion Energy, September 1416, 2004, Madison, WI, in press;
- Normile, D., (2003), ITER negotiations heat up as all sites pass muster, Science, 299, p. 1299; Leeb, S. and D. Leeb, 2004, The Oil Factor, Warner Business Books, New York, pp. 81–82.
- Meade, D., (2004), FIRE, a test bed for AIRES-RS/AT advanced physics and plasma technology, Proceedings 16th ANS Topical Meeting on the Technology of Fusion Energy, September 14-16, 2004, Madison, WI, in press.
- Keane, C. J., (2004), Status of the U.S. inertial confinement fusion program, Proceedings 16th ANS Topical Meeting on the Technology of Fusion Energy, September 14-16, 2004, Madison, WI, in press.
- Hirsch, R. L., (2002), The year 2015 fusion power conversations, Journal of Fusion Energy, 21, 2, pp. 113–116; Hirsch, R. L., G. L. Kulcinski, R. Shanny, 1997, The U.S. fusion program at a cross-roads, Issues, National Academy of Sciences, Summer.
- See Dean, S. O, 2004, Historical perspective on the United States fusion program, Proceedings 16th ANS Topical Meeting on the Technology of Fusion Energy, September 14-16, 2004, Madison, WI, in press.
- Glaser, P., 1997, Solar power from satellites, Physics Today, pp. 30–38; Criswell, D. R., and R. D. Waldron, 1990, Lunar system to supply solar electric power to Earth, 25th Intersociety Energy Conversion engineering Conference, Reno, Nevada, August 12-17; Mankins, J. C., 1998, The space solar power option, Ad Astra, Space solar power systems, January-February, pp. 22–29; Erb, R. B., 1998, Above it all, Ad Astra, Space solar power systems, January-February, pp. 30–34; Kaya, N., 1998, Japan’s solar systems, Ad Astra, Space solar power systems, January-February, pp. 40–44; Criswell, D. R., 2002, Solar power via the Moon, The Industrial Physicists, American Institute of Physics, April-May, pp. 12–15; National Research Council, 2001, Laying the Foundation for Space Solar Power, National Academy Press, Washington, 80 p.
- Dornheim, M. A., (1997), Arrays dwarf previous space power structures, Aviation Week & Space Technology, December 8, pp. 54–56.
- Leeb, S. and D. Leeb, (2004), The Oil Factor, Warner Business Books, New York, p. 77;
- Nelson, J., (2001), Solar cells by self-assembly, Science, 293, pp. 1059–1060.
- Criswell, D. R., (1996), World and lunar solar power systems costs, SPACE 96, American Society of Civil engineers; Criswell, D. R., 1998, Commercial lunar solar power and sustainable growth of the two-planet economy, Acta Forum Engelberg 1998, p. 13.
- Wittenberg, L. J., J. F. Santarius, and G. K. Kulcinski, 1986, Lunar source of He-3 for commercial fusion power, Fusion Technology, 10, pp. 167–178; Kulcinski, G. K., and H. H. Schmitt, 1987, The Moon: an abundant source of clean and safe fusion fuel for the 21st Century, 11th International Scientific Forum on Fueling the 21st Century, Moscow, USSR; Schmitt, H. H., 1997, Interlune-Intermars-Business Initiative: Returning to deep space, American Society of Civil Engineers, Journal of Aerospace Engineering, 10, 2, pp. 60–67.
- Kulcinski, G. L., (1996), Near Term Commercial Opportunities from Long Range Fusion Research, Fusion Technology, 30, p. 411.