Employing uranium in light-water re

Employing uranium in light-water reactors of conventional design in which essentially only 235U is used (up to 0.7% in
natural uranium) and where about 1000 MWd/kg 235U are attained means that 4 x lo6 tonnes uranium correspond to ca. 690 x 10l2 kwhr. If this uranium were to be fully exploited using fast breeder reactors, then this value could be very considerably increased, namely to ca. 80000 x 1Ol2 kwhr. An additional 44000 x 10j2 kwhr could be obtained if the aforementioned thorium reserves were to be employed in breeder reactors. The significance of the fast breeder reactors can be readily appreciated from these figures. They operate by synthesizing the fissionable 239Pu from the nonfissionable nuclide 238U (main constituent of natural uranium, abundance 99.3%) by means of neutron capture. 238U is not fissionable using thermal neutrons. In the same way fissionable 233U can be synthesized from 232Th.
The increasing energy demand can be met for at least the next 50 years using present reactor technology.
The dominant reactor type today, and probably for the next 20 years, is the light-water reactor (boiling or pressurized water reactor) which operates at temperatures up to about 300 "C. High temperature reactors with cooling medium (helium) temperature up to nearly 1000 "C are already on the threshold of large scale development. They have the advantage that they not only supply electricity but also process heat at higher temperatures (cJ Sections 2.1.1 and 2.2.2). Breeder reactors will probably become commercially available in greater numbers as generating plants near the end of the 1990s at the earliest, since several technological problems still confront their development.
In 1995, Japan and France were the only countries that were still using and developing breeder reactors.
It is important to note that the supply situation of countries highly dependent on energy importation can be markedly improved by storing nuclear fuels due to their high energy content. The prerequisite for the successful employment of nuclear energy is not only that safe and reliable nuclear power stations are erected, but also that the whole fuel cycle is completely closed. This begins with the supply of natural uranium, the siting of suitable enrichment units, and finishes with the waste disposal of radioactive fission products and the recycling of unused and newly bred nuclear fuels.
Waste management and environmental protection will determine the rate at which the nuclear energy program can be realized.