Examples of fusion in the following topics:
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- A fusion reactor is designed to use the thermal energy from nuclear fusion to produce electricity.
- Fusion power is the power generated by nuclear fusion processes.
- To harness fusion power, a fusion reactor must be built to turn the energy released by fusion into electricity.
- It was first derived for fusion reactors by John D.
- State the Lawson criterion for a fusion reactor to be viable
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- The hydrogen bomb is a nuclear weapon that uses a mixture of fission and fusion to produce a massive explosion.
- A thermonuclear weapon is a nuclear weapon designed to use the heat generated by a fission bomb to compress a nuclear fusion stage.
- This type of weapon is referred to as a hydrogen bomb, or H-bomb, because it employs hydrogen fusion.
- Oddly, in most applications, the majority of its destructive energy comes from uranium fission, not hydrogen fusion alone.
- Radiation from a primary fission bomb compresses a secondary section containing both fission and fusion fuel.
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- Fusion is the process that powers active stars, releasing large quantities of energy.
- Therefore, energy is no longer released when such nuclei are made by fusion; instead, energy is absorbed.
- The fusion of lighter elements in stars releases energy, as well as the mass that always accompanies it.
- A substantial energy barrier of electrostatic forces must be overcome before fusion can occur.
- Therefore, the main technical difficulty for fusion is getting the nuclei close enough to fuse.
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- The R group at the A:B ring fusion is most commonly methyl or hydrogen, that at the C:D fusion is usually methyl.
- Decalin, short for decahydronaphthalene, exists as cis and trans isomers at the ring fusion carbon atoms.
- In the conformational drawings the ring fusion and the angular hydrogens are black.
- In each of these all chair conformations the rings are fused by one axial and one equatorial bond, and the overall structure is bent at the ring fusion.
- The fusion of ring C to ring B in a trans configuration prevents ring B from undergoing a conformational flip to another chair form.
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- Instead, use the heat of fusion ($\Delta H_{fusion}$ ) to calculate how much heat was involved in that process: $q=m\cdot \Delta H_{fusion}$, where m is the mass of the sample of water.
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- Boron trioxide is produced by treating borax with sulfuric acid in a fusion furnace.
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- The enthalpy of sublimation (also called heat of sublimation) can be calculated as the sum of the enthalpy of fusion and the enthalpy of vaporization.
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- Nuclear binding energy is also used to determine whether fission or fusion will be a favorable process.
- For elements lighter than iron-56, fusion will release energy because the nuclear binding energy increases with increasing mass.
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- Iron's very common presence in rocky planets like Earth is due to its abundant production as a result of fusion in high-mass stars.
- This is where the production of nickel-56 (which decays to the most common isotope of iron) is the last nuclear fusion reaction that is exothermic.
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- Boron is produced entirely by cosmic ray spallation (as a result of nuclear reactions), and not by stellar nucleosynthesis (not within stars as a result of fusion or supernovae).