What is the Difference Between Fission and Fusion?
🆚 Go to Comparative Table 🆚Fission and fusion are two different nuclear reactions that produce energy, but their processes are very distinct. Here are the key differences between them:
- Process: Fission is the splitting of a heavy, unstable nucleus into two lighter nuclei, while fusion is the process where two light nuclei combine together, releasing vast amounts of energy.
- Energy Release: Fusion releases several times the energy generated by fission, making it a far more powerful process.
- Controlled vs. Uncontrolled: Fission can be controlled and is used in nuclear power reactors, while fusion is not easily controlled and is not utilized to produce power.
- Chain Reaction: In fission, a chain reaction can be initiated, where the high-speed neutrons ejected from the initial fission reaction initiate other fission reactions.
- Conditions: Fusion occurs under extreme pressure and temperature, such as those found in the core of the Sun, while fission occurs when a neutron slams into a larger atom, forcing it to excite and split into two smaller atoms.
- Radioactive By-Products: Fission produces long-term radioactive by-products, while fusion does not produce highly radioactive fission products.
In summary, fission and fusion are both nuclear reactions that produce energy, but they differ in the process, energy release, control, chain reaction, conditions, and radioactive by-products. Fission is currently used in nuclear power reactors, while fusion is still in the experimental stages of research and development.
Comparative Table: Fission vs Fusion
Here is a table comparing the differences between fission and fusion:
| Feature | Fission | Fusion |
|---|---|---|
| Definition | Fission is the splitting of a heavy, unstable nucleus into two lighter nuclei, releasing energy in the process. | Fusion is the process where two light nuclei combine together, releasing vast amounts of energy. |
| Nuclear Reactions | Involves the division of one atom into two or more smaller or lighter atoms. | Involves the combination of two or more atoms to form a larger or heavier atom. |
| Energy Required | Less energy is needed to split an atom in a fission reaction. | High energy is needed to fuse two or more atoms together in a fusion reaction. |
| Energy Released | The amount of energy released in fission is less than the energy produced by fusion. | The amount of energy released in fusion is way greater than the energy produced by fission. |
| Reactors | Fission is used in nuclear power reactors since it can be controlled. | Fusion is not utilized to produce power since the reaction is not easily controlled and is in experimental stages. |
| Natural Occurrence | Fission does not happen naturally. | Fusion takes place naturally, such as in stars like the sun. |
| Conditions | Conditions supporting nuclear fission include the critical mass of the substance and neutrons. | Conditions supporting nuclear fusion include extreme pressure and temperature, such as those found in stars. |
Fission and fusion are both nuclear processes that release energy, but they operate in different ways. Fission involves the splitting of a heavy nucleus into smaller nuclei, while fusion involves the combining of lighter nuclei into a larger nucleus.
- Nuclear Fusion vs Fission
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- Fusion vs Vaporization
- Multiple Fission vs Fragmentation
- Binary Fission vs Multiple Fission
- Gemination vs Fusion
- Fusion vs Solidification
- Homolytic vs Heterolytic Fission
- Mitosis vs Binary Fission
- Fissile vs Fertile Isotopes
- Nuclear Energy vs Light Energy
- Nuclear Reactor vs Nuclear Bomb
- Atomic vs Nuclear Bomb
- Coal Energy vs Nuclear Energy
- Nuclear Reaction vs Chemical Reaction
- Radioactivity vs Radiation
- Proton vs Neutron
- Binary Fission vs Budding
- Budding Yeast vs Fission Yeast