Alternative ways for handling spent nuclear fuel

Sunday, 02 August 2009 23:22 administrator

There are two major options to handle spent nuclear fuel, name reprocessing and final storage. A theoretical alternative is "transmutation".


Once trough

The present approach to handling nuclear fuel in Sweden is "once-trough" and final deposition. This approach is highly realistic:

There are several aspects which may be considered negative, however:

The Plutonium issue

One of the interesting aspects of nuclear reactors is that they actually can produce fuel. This does not violate the first or second principle of thermodynamics. We are not creating energy, just making existing energy accessible.

The way things work, only a small fraction - like 0.7% - of the uranium reserves can be used in nuclear reactors. The reason for this is that a small part of uranium, the 235U isotope, can be employed to achieve self sustained chain reaction. Most of natral uranium is the isotope 238U, which absorbs far to many neutrons without fission to be useful in a normal reactor. One interesting property of 238U is that it can absorb a neutron and convert to 239Pu which is a very good nuclear fuel. Could we build a nuclear reactor that produces at least one 239Pu atom for each 235U consumed would we not have an eternal source for energy, but a process that could produce something like 100 times the energy for each kg of uranium used than the normal fission process.


One option for handling spent fuel is reprocessing. Reprocessing has a major benefit for fuel utilization at least in theory, as both uranium and plutonium can be reused. Natural uranium does only conatin about 0.7% of the isotope 235U which is usable for energy production in light water reactors. The rest is mainly 238U which cannot sustain nuclear chain reaction in normal reactor designs. When the reactor is in operation some of the 238U atoms will be converted to 239U by capturing a neutron. The 239U atom will emit a beta particle (high energy electron) and convert to 239Pu. This form of plutonimum is a good reactor fuel. So when we burn out 235U we are building up 239Pu the rate of 239Pu produced to the 235U is called breeding factor. If we achieve a breeding ratio larger than 1 we produce more fuel than we consume. This is not perpetum mobile, the price we pay is that we use up 238U. The other price is that 239Pu has some less desirable properties.

By reprocessing fuel we can extract the plutonium and use it to replace 235U, but there is a consideration that it could also be used to make bombs. Plutonium coming from light water reactors is not very attractive as weapons material, however, because it contains large amounts of heavy plutonium istopes that makes it hard to build a functional and effective weapon.



On average a fission of a 235U atom produces about 2.3 new neutrons, on the average. To sustain chain reaction exactly 1 neutron needs to be captured by a fissible atom and cause fission. Could we absorb one additional neutron in 238U we could produce as much 239plutomium as we consume 135U. 239Pu is fissible and can be used instead of 235U. This is not a perpetum mobile because we actually use up all 238U, but in a sense even better than a perpetum mobile because it actually works. The first nuclear power plant connected to the grid has been an experimental breeder.

France used to have a very ambitious breeder program, with the Super Phoenix as pinnacle, but Super Phoenix failed. It seems that Japan is going to have a serious go at a breeding cycle. Their plans call for 100% breeders well before the end of this century.



A new idea is transmutation. The idea is to convert the long lived actinides to short lived istopoes by intensive neutron bombadement using a spallation source. In a spallation source a target consisting heavy material like lead or quicksilber is irradiated with high energy protons having so high energy that they can pass the potential barrierr. The protons cause the target atoms to split producing a large number of neutrons. The neutrons will be captured in the actinides and convert them to nuclei having relatively short lifetime. To my understanding a such reactor would also produce much more power than it would consume.

Fusion, the ultimate solution

The final frontier is fusion, the way the sun and other bright stars are producing energy. The problem with fusion on earth is that we need very high temperature above 100 million Kelvins (about the same in Celsius ;-)


The cold war demonstrated the feasibilty of fusion in the form of the hydrogen bomb. Many years after the first hydrogen bomb, self sustained fusion was demonstrated in the JET (Joint Europen Torus) in England. The next step on the way of nuclear nirvana is ITER, which will demonstrate the feasibilty of fusion energy for energy production. Fusion has two advantages over fission:








Last Updated on Wednesday, 19 August 2009 20:38