Self-Healing Ceramics for Nuclear Safety

Roland Piquepaille writes "Pacific Northwest National Laboratory (PNNL) researchers have used supercomputers to simulate how common ceramics could repair themselves after radiation-induced damages. This is an important discovery because 'materials that can resist radiation damage are needed to expand the use of nuclear energy.' These ceramics, which are able to handle high radiation doses, could improve the durability of nuclear power plants. They also might help to solve the problem of nuclear waste storage. But read more for additional references about how this research could improve nuclear safety."

Now if I could get some of that

[Chabil+Ha']

To replace the pottery my kids accidentally smash...

Waste storage?

[momerath2003]

The only problem with nuclear waste storage is politicians. Radioactive waste storage is a proven, safe technology. Even so, long-term geological storage is not the right solution, since we would be throwing away a lot of good, fissionable material that can be recycled for energy production in, e.g., fast reactors.

Re:Waste storage?

[Chandon+Seldon]

If you get your fuel recycling going properly, then the cycle-end waste gets back to ore-level radioactivity in a couple hundred years. We have building technology that can reliably be trusted to store stuff for a couple hundred years - poured cement anywhere that isn't in a flood zone or on a tectonic fault line.

It's only with this damn fool "recycling nuclear fuel gives the terrorists nuclear bombs" nonsense that we're stuck with dangerously radioactive material 1500 years from now.

Gas Cooled Fast reactor

[BlueParrot]

Out of the generation IV proposals it is probably the gas cooled fast reactor that will benefit the most from this.
http://en.wikipedia.org/wiki/Gas_cooled_fast_reactor

One of the major issues with global warming is that the hydrogen used to produce amonia and subsequently artificial fertilizer, is currently derived from natural gas. The process emits a lot of CO2 , and it isn't really feasible to
stop producing hydrogen as it could result in a collapse of agriculture due to drastically increased fertilizer prices.

Two generation IV reactors, the very high temperature reactor, and the gas cooled fast reactor, are aimed to resolve this by dramatically improving the efficiency of electrolysis of water. This can be achieved through so called thermochemical hydrogen production ( http://en.wikipedia.org/wiki/Sulfur-iodine_cycle), but it requires temperatures exceeding 800 C.

While it is likely that thermal reactors with helium coolant ( such as the pebble bed reactor ) could achieve this, it gets more tricky for fast reactors. Fast reactors have about 100 times less waste, better uranium utilization and the waste decays to safe levels between 100 and 1000 times quicker than for thermal reactors. The main catch is that the MUCH higher power density and neutron flux makes it difficult to find suitable materials. Sodium coolant doesn't work for hydrogen production since it boils before reaching the necessary temperatures, lead has corrosion issues especially at high temperatures and its high mass density makes it difficult to find materials that are strong enough at the temperatures required. Helium works, but because it has a much lower heat capacity than molten metals the reactor would likely reach higher temperatures under accident scenarios, and thus materials that can withstand a very strong neutron flux at high temperatures is absolutely necessary for a gas cooled fast reactor to be feasible.