What is the Difference Between Nuclear Fusion and Fission?
🆚 Go to Comparative Table 🆚The main difference between nuclear fusion and fission lies in the processes and the amount of energy released. Here are the key differences:
- Nuclear Fission:
- Involves the splitting of a heavy, unstable nucleus (such as uranium) into two lighter nuclei.
- Occurs when a neutron slams into a larger atom, forcing it to excite and split into two smaller atoms, called fission products.
- Releases a tremendous amount of energy.
- Used in nuclear power reactors because it can be controlled.
- Energy released is lower than that of nuclear fusion.
- Nuclear Fusion:
- Involves the combination of two light nuclei (such as hydrogen isotopes) to form a single heavier nucleus.
- Takes place when two hydrogen atoms (deuterium and tritium) fuse in a high-pressure atmosphere with extremely high temperatures.
- Releases an enormous amount of energy, several times greater than that of nuclear fission.
- Currently in experimental stages and not utilized for power production due to difficulty in sustaining the reaction for long periods.
- Energy released is much greater than that of nuclear fission.
In summary, nuclear fission is a process where a heavy nucleus splits into two lighter nuclei, releasing energy, while nuclear fusion is a process where two light nuclei combine to form a single heavier nucleus, releasing a much larger amount of energy. Fission is currently used in nuclear power plants, while fusion is still in the experimental stage.
Comparative Table: Nuclear Fusion vs Fission
The primary difference between nuclear fusion and nuclear fission is the process through which energy is released:
Nuclear Fission: In this process, a large atom splits into smaller atoms, releasing a massive amount of energy. It requires a small amount of energy to initiate the reaction, and it generates a significant amount of radioactive decay as a byproduct. Fission is used in nuclear power reactors since it can be controlled. Examples of fission include the splitting of uranium-235 or plutonium-239.
Nuclear Fusion: In this process, two atoms combine to form a larger nucleus, releasing even more energy than nuclear fission. It requires a high amount of energy to initiate the reaction, and it generates a smaller amount of radioactive decay as a byproduct. Fusion powers the sun and stars, and it is used in hydrogen bombs. An example of fusion is the combination of hydrogen isotopes deuterium and tritium to create a helium nucleus and a neutron.
Here is a table summarizing the differences between nuclear fusion and nuclear fission:
| Feature | Nuclear Fission | Nuclear Fusion |
|---|---|---|
| Process | Splitting a large atom into smaller atoms | Combining two atoms into a larger atom |
| Energy Release | Huge amount of energy | More energy released than nuclear fission |
| Energy Required | Small amount of energy | High amount of energy |
| Byproduct | A lot of radioactive decay | Less radioactive decay |
Fission is used in nuclear power plants to generate energy, while fusion is still in the experimental stages of research and has not been harnessed for large-scale energy production.
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- Multiple Fission vs Fragmentation
- Fusion vs Vaporization
- Binary Fission vs Multiple Fission
- Nuclear Reactor vs Nuclear Bomb
- Homolytic vs Heterolytic Fission
- Nuclear Energy vs Light Energy
- Coal Energy vs Nuclear Energy
- Atomic vs Nuclear Bomb
- Nuclear Reaction vs Chemical Reaction
- Fusion vs Solidification
- Mitosis vs Binary Fission
- Fissile vs Fertile Isotopes
- Gemination vs Fusion
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- Cell Division vs Nuclear Division
- Uranium vs Plutonium
- Thorium vs Uranium