Hostname: page-component-586b7cd67f-rdxmf Total loading time: 0 Render date: 2024-11-23T23:10:20.748Z Has data issue: false hasContentIssue false

20.—Energy in the Future—The Role of Nuclear Fission and Fusion

Published online by Cambridge University Press:  14 February 2012

Synopsis

For comfort the total future world population faces a limit. Three or more educated generations seem likely before the population growth will be checked. It seems prudent to envisage a world population of about 15 thousand million in a century or two. Their energy needs for food, water, warmth, clean air, locomotion and management of wastes may be assessed at 5 to 50 thermal kilowatts per capita. That amounts to 0·05 per cent, to 0·5 per cent, of the energy supply from the sun. Generating this amount by nuclear fission would cause no severe pressure on world resources of uranium and thorium for hundreds of centuries, if near-breeders such as CANDU reactors are used exploiting the uranium-thorium fuel cycle. Neither the cost of fuel supply nor of waste management to keep the environment unburdened by extra radioactivity need be as high as prices now paid for coal and oil. The addition of breeders or other means such as nuclear fusion or spallation for increasing the neutron supply would significantly lower the use of uranium and thorium but would not necessarily reduce the cost of power.

Type
Research Article
Copyright
Copyright © Royal Society of Edinburgh 1972

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

References to Literature

[1] Darwin, C. G., 1952. The Next Million Years. London: Hart-Davis.Google Scholar
[2] Strutt, Hon. R. J., 1906. ‘On the Distribution of Radium in the Earth's Crust and on the Earth's Internal Heat, Part I. Part II, Sedimentary Rocks. Part III, Rock-forming Minerals’, Proc. Roy. Soc., A 77, 472 and 78, 150. Goldschmidt, V. M., 1954. Geochemistry. Oxford.Google Scholar
[3] Griffith, J. W. and Roscoe, S. M., 1964. ‘Canadian Resources of Uranium and Thorium’ Paper P/24, 3rd Int. Conf. Peaceful Uses of Atomic Energy, Geneva.Google Scholar
[4] Dresner, L. and Weinberg, A. M., 1962. ‘Recent Developments in the Theory and Technology of Chain Reactors’, Rev. Mod. Phys., 34, 747765.Google Scholar
[5]Lewis, W. B., 1964. ‘How Much of the Rocks and the Oceans for Power?—Exploiting the Uranium-Thorium Fission Cycle’, AECL-1916. Lewis, W. B. and Church, T. G., 1964. ‘Electricity Supply in Canada and the Role of Nuclear Power’, AECL-2001, Paper P/1, Proc. 3rd Int. Conf. Peaceful Uses of Atomic Energy, Geneva. Lewis, W. B., Duret, M. F., Craig, D. S., Veeder, J. I. and Bain, A. S., 1971. ‘Large-scale Nuclear Energy from the Thorium Cycle’. Paper 157, 4th U.N. Conf. Peaceful Uses of Atomic Energy, Geneva.Google Scholar
[6]Watson, L. C.et al., 1958. ‘The Disposal of Fission Products in Glass’, Paper P/195, Proc. 2nd Int. Conf. Peaceful Uses of Atomic Energy, Geneva. Merritt, W. F., 1967. ‘Permanent Disposal by Burial of Highly Radio-active Wastes Incorporated into Glass’, Paper SM-93/29, Int. Atom. Energy Ag. Symp. Disposal of Radioactive Wastes into the Ground, pp. 403408.Google Scholar
[7] (a) Thompson, W. S. and Lewis, D. T., 1965. Population Problems. New York: McGraw-Hill. (b) Putnam, Palmer C., 1953. Energy in the Future. New York: Van Nostrana.Google Scholar
[8]Marx, Karl, Capital. A lengthy footnote mostly abusive but giving erroneous credit to Malthus for being unmarried. See Keynes, J. M. ‘Robert Malthus’ in Essays in Biography. (1933) London: Macmillan.Google Scholar
[9] Ref. 7 (6) for industrial urban pattern. Han, Suyin, 1967. China in the Year 2001, for commane pattern for large population. London: Watts.Google Scholar
[10]Lewis, W. B., 1969. ‘The Intense Neutron Generator and Future Factory Type Ion Accelerators’, AECL-3190, IEEE Trans. Nucl. Sci., NS-16, (1), 2835.CrossRefGoogle Scholar
[11]Alexandrov, A. P., 1968. ‘Nuclear Power and its Role in Technical Progress’, General Address 7th Plenary Session. Wld Power Conf., Moscow.Google Scholar
[12]The literature is so extensive, it may be of interest to refer to ‘World Survey of Major Facilities in Controlled Fusion’, Spec. Suppl. Nucl. Fusion, 1970. Vienna: IAEA.Google Scholar
[13] e.g. Gobeli, G., Bushnell, J. C., Peercy, P. S. and Jones, E. D., 1969. ‘Observation of Neutrons Produced by Laser Irradiation of Li-Deuteride’, Phys. Rev., 188, 300302. Kidder, R. E., 1968. ‘Application of Lasers to the Production of High-Temperature and High-Pressure Plasma’, Nucl. Fusion, 8, 312. Shearer, J. W. and Barnes, W. S., 1970. ‘Mechanisms for Production of Neutron-Emitting Plasma by Sub-Nanosecond Laser-Pulse Heating’, Phys. Rev. Lett., 24, 9294 (and Errata, p. 432, 1970). Basov, N.et al., 1968. Zh. Eksp. Teor. Fiz. (Translation JETP Lett., 8, 14). Floux, F.et al., 1970. ‘Nuclear Fusion Reactions in Solid Deuterium Laser-Produced Plasma’, Phys. Rev., A 1, 821824. Haught, A. F. and Polk, D. H., 1970. ‘Formation and Heating of Laser Irradiated Solid Particle Plasmas’, Physics Fluids, 13, 28252841.Google Scholar
[14]Abramyan, E. A., 1970. ‘The Generation of Intensive Relativistic Electron Beams’, unpublished. Novosibirsk: Inst. Nucl. Phys. Sarantsev, V. P.et al., 1967. ‘Collective Linear Acceleration of Ions’, Proc. 6th Int. Conf. on High Energy Accelerators, p. 289, CEAL-1000. Cambridge, Mass. McMillan, E. M., Sessler, A. M.et al., 1968. Symp. Electron Ring Accelerators, UCRL-18103, Lawrence Radiation Laboratory. Berkeley, Calif. Rostoker, N. and Hammer, D., 1970. ‘Propagation of High Current Relativistic Electron Beams’, Physics Fluids, 13, 1831. Benford, J. and Ecker, B., 1971. ‘Transport of Intense Relativistic Electron Beams in a z Pinch’, Phys. Rev. Lett., 26, 1160.Google Scholar
[15]Proc. BNES Conf. Nucl. Fusion Reactors, Culham Lab. 1969, 1970. Br. Nucl. Energy Soc.Google Scholar
[16] ‘Nuclear Energy Centres Industrial and Agro-Industrial Complexes’, USAEC, Oak Ridge Nat. Lab. Rep. ORNL-4290, 1968.Google Scholar
[17]Lewis, W. B., 1956. ‘Scientific Prospects in Atomic Energy’. Address, Symp. Def Res. Bd, AECL-404.Google Scholar
[18]Taylor, M. K., Ferranti-Packard, Canada, private communication. Marchetti, C., ISPRA, Euratom, private communication.Google Scholar
[19]Wynveen, R. A., 1963. Ch. 12 in Young, G. J. (Ed.) Fuel Cells. New York: Reinhold.Google Scholar
[20]Williams, K. R. (ed.), 1966. An Introduction to Fuel Cells. London: Elsevier. Breiter, M. W., 1969. Electrochemical Processes in Fuel Cells. New York: Springer Verlag. Dugdale, I., 1965. Ch. 2 in Spring, K. H.Direct Generation of Electricity. London: Academic Press.Google Scholar