Difference between revisions of "Nuclear fusion"

 
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[[Category:Physics]]
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[[Category: Physics]]
 
== Explanation ==
 
== Explanation ==
Nuclear fusion is the process in which two or more lighter nuclei fuse together at a very high temperature to form a stable heavier nucleus. In the process, a massive amount of [[energy]] is released along with protons and neutrons. A good example of the nuclear fusion reaction is the stars. The hydrogen atoms in the core of the [[sun]], fuses due to the high kinetic energy from the temperature to form helium, thus powering it up with the energy.
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Nuclear fusion is the process in which lighter nuclei fuse together at a very high [[temperature]] to form a stable heavier [[atomic nucleus|nucleus]]. In the process, a massive amount of [[energy]] is released along with [[proton]]s and [[neutron]]s. A good example of the nuclear fusion reaction is the stars. The [[hydrogen]] atoms in the core of the [[sun]], fuses due to the high [[kinetic energy]] from the temperature to form [[helium]], thus powering it up with the energy.
 
== Frequently Asked Questions ==
 
== Frequently Asked Questions ==
 
=== Where does the energy of the nuclear fusion reaction come from? ===
 
=== Where does the energy of the nuclear fusion reaction come from? ===
 
The energy released is attributed to the energy required to overcome the long-range electrostatic repulsion of protons, so that the lighter nuclei could fuse together and form a heavier nucleus. This is also the reason why the combined mass of the nuclei is higher than the mass of the heavier nucleus formed after the reaction. The lost mass attributes to the released energy and other subatomic particles released along with it.
 
The energy released is attributed to the energy required to overcome the long-range electrostatic repulsion of protons, so that the lighter nuclei could fuse together and form a heavier nucleus. This is also the reason why the combined mass of the nuclei is higher than the mass of the heavier nucleus formed after the reaction. The lost mass attributes to the released energy and other subatomic particles released along with it.

Latest revision as of 08:25, 28 November 2016

Explanationedit

Nuclear fusion is the process in which lighter nuclei fuse together at a very high temperature to form a stable heavier nucleus. In the process, a massive amount of energy is released along with protons and neutrons. A good example of the nuclear fusion reaction is the stars. The hydrogen atoms in the core of the sun, fuses due to the high kinetic energy from the temperature to form helium, thus powering it up with the energy.

Frequently Asked Questionsedit

Where does the energy of the nuclear fusion reaction come from?edit

The energy released is attributed to the energy required to overcome the long-range electrostatic repulsion of protons, so that the lighter nuclei could fuse together and form a heavier nucleus. This is also the reason why the combined mass of the nuclei is higher than the mass of the heavier nucleus formed after the reaction. The lost mass attributes to the released energy and other subatomic particles released along with it.