Everything about Subcritical Reactor totally explained
A
subcritical reactor is a nuclear
fission reactor that produces fission without achieving
criticality. Instead of a sustaining
chain reaction, a subcritical reactor uses additional
neutrons from an outside source. A reactor coupled to a
particle accelerator to produce neutrons by
spallation is called an
Accelerator-Driven System (
ADS).
Motivation
The long-lived
transuranic elements in
nuclear waste can in principle be
fissioned, releasing
energy in the process and leaving behind the
fission products which are shorter-lived. This would shorten considerably the time for disposal of radioactive waste. However, some isotopes have
threshold fission
cross sections and have a small effective fraction of
delayed neutrons and therefore require a
fast reactor for being fissioned, and for safety reasons preferably a subcritical reactor if they constitute a significant fraction of the fuel. The three most important long-term radioactive isotopes that could advantageously be handled that way are
Neptunium-237,
Americium-241 and Americium-243. The
nuclear weapon material
Plutonium-239 is also suitable although it can be incinerated in a cheaper way as
MOX fuel or inside existing fast reactors.
Principle
Most current ADS designs propose a high-intensity
proton accelerator with an energy of about 1
GeV, directed towards a
spallation target made of
thorium that's cooled by liquid
lead-
bismuth in the
core of the reactor. In that way, for each proton interacting in the target, an average 20
neutrons are created to irradiate the surrounding fuel. Thus, the neutron balance can be regulated such as the reactor would be below
criticality if the additional neutrons by the accelerator were not provided. The main advantage is inherent safety, even if the
nuclear fuel under consideration lack
Uranium's nice self-regulating properties—like delayed neutrons and doppler coefficient—that make standard
nuclear reactors safe. Whenever the neutron source is turned off, the reaction ceases.
Technical challenges
There are technical difficulties to overcome before ADS can become economical and eventually be integrated into future nuclear waste management. The accelerator must provide a high intensity and be highly reliable. There are concerns about the window separating the protons from the spallation target, which is expected to be exposed to stress under extreme conditions. The chemical separation of the transuranic elements and the fuel manufacturing, as well as the structure materials, are important issues. Finally, the lack of
nuclear data at high neutron energies limits the efficiency of the design.
Some laboratory experiments and many theoretical studies have demonstrated the theoretical possibility of such a plant.
Carlo Rubbia, a nuclear
physicist and former director of
CERN, was one of the first to conceive a design of a subcritical reactor, the so-called "
energy amplifier". In 2005, several large-scale projects are going on in Europe and Japan to further develop subcritical reactor technology.
Economics and public acceptance
Subcritical reactors have been proposed both as a means of generating
electric power and as a means of
transmutation of
nuclear waste, so the gain is twofold. However, the costs for construction, safety and maintenance of such complex installations are expected to be very high, let alone the amount of research needed to develop a practical design (see above). There exist cheaper and reasonably safe waste management concepts, such as the long-term
geological disposal. However, the solution of a subcritical reactor might be favoured for a better
public acceptance—it is considered more acceptable to burn the waste than to bury it for hundreds of thousands of years. For future waste management, a few transmutation devices could be integrated into a large-scale nuclear program, hopefully increasing only slightly the overall costs.
Subcritical Hybrid Systems
While originally thought that an ADS would be a part of a
light water reactor design, other proposals have been made that incorporate an ADS into other
generation IV reactor concepts.
One such proposal calls for a
gas cooled fast reactor that's fueled primarily by Plutonium and Americium. The neutronic properties of Americium make it difficult to use in any critical reactor due to neutronic properties that tend to make the
moderator temperature coefficient more positive, decreasing stability. The inherent safety of an ADS, however, would allow Americium to be safely burned. These materials also have good neutron economy, allowing the pitch-to-diameter ratio to be large, which allows for improved natural circulation and economics.
Further Information
Get more info on 'Subcritical Reactor'.
|
External Link Exchanges
Do you know how hard it is to get a link from a large encyclopaedia? Well we're different and will prove it. To get a link from us just add the following HTML to your site on a relevant page:
<a href="http://subcritical_reactor.totallyexplained.com">Subcritical reactor Totally Explained</a>
Then simply click through this link from your web page. Our crawlers will verify your link, extract the title of your web page and instantly add a link back to it. If you like you can remove the words Totally Explained and embed the link in article text.
As long as your link remains in place, we'll keep our link to you right here. Please play fair - our crawlers are watching. Your site must be closely related to this one's topic. Any kind of spamming, dubious practises or removing the link will result in your link from us being dropped and, potentially, your whole site being banned. |
