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Nuclear Fission and Fusion - Part IV |
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5.
Types
of fission reactions, difference between nuclear fusion and fission
reactions Uncontrolled
fission reaction The emitted neutrons can create further fission reactions. So the second stage fissioning of 23592U will give rise to nine more neutrons. These 9 neutrons can further cause fissioning giving rise to 27 neutrons. This is the chain reaction. Each fission reaction gives out an enormous amount of energy. Now you can see how a chain reaction can give rise to explosive amount of heat energy. A fission reaction whereby the reaction is allowed to proceed without any moderation (by removal of neutrons) is called an uncontrolled fission reaction. An uncontrolled fission reaction is used for nuclear bombs. Controlled
fission reaction In the nuclear fission reaction shown above, if we remove two of the three neutrons then, instead of having three more 23592U to fission, we will have only one more of such a reaction. In this way, the rate of reaction can be controlled. The neutrons can be removed by what are called moderators which are made up of materials which like to absorb neutrons. Cadmium (Cd) is one such material. A nuclear fission reaction, whereby the rate of reaction can be moderated externally by allowing just enough number of neutrons to keep the fission reaction rate constant is called a controlled fission reaction. Allowing the moderators to absorb just enough number of neutrons to keep the chain reaction continuing can also control energy emitted during the fission reaction. This is the principle behind nuclear reactors that produce power and generate electricity. Both, nuclear fusion and nuclear fission reactions lead to the production of new nuclei, there are some basic differences between the two.
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