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Why is extremely high pressure required to cause atomic nuclei to crash into on another in stars?
Extremely high pressure is required to initiate fusion in the stars. This pressure overcomes the normal repulsion between protons, allowing protons of hydrogen to get close enough for the strong atomic force to take over and change the force to an attractive force, forming helium.Not stated, but answered for completeness sake... Extremely high temperature is also required in order to strip the hydrogen nuclei of their electrons, forming an ionized plasma, in order to get past the additional repulsion that the electron cloud would represent.
Why is extremely high pressure required to cause atomic nuclei to crash into one another stars?
Extremely high pressure is required in stars to cause atomic nuclei to crash into one another because the nuclei have positive charges, which repel each other due to the electromagnetic force. The high pressure overcomes this repulsion, allowing the nuclei to come close enough for the strong nuclear force to take effect, resulting in nuclear fusion and the release of energy.
Why is high pressure required to cause atomic nuclei to crash into one another in stars?
Extremely high pressure is required to initiate fusion in the stars. This pressure overcomes the normal repulsion between protons, allowing protons of hydrogen to get close enough for the strong atomic force to take over and change the force to an attractive force, forming helium.Not stated, but answered for completeness sake... Extremely high temperature is also required in order to strip the hydrogen nuclei of their electrons, forming an ionized plasma, in order to get past the additional repulsion that the electron cloud would represent.
Why is extremely high pressure required to cause atomic nuclei to crash into one another?
Extremely high pressure is required for fusion to occur because the electromagnetic force would otherwise cause the protons in the two nuclei to repel each other, and you need to overcome that repulsive force, and allow the stronger1 binding energy to take over.Not asked, but answered for completeness; you also need extremely high temperature because you need to strip the electron clouds away, i.e. to fully ionize the nuclei, to eliminate interference from the electrons as well.-------------------------------------------------------------------------------------------------1 The binding energy is stronger, but only at closer distances. Outside the radius of the nucleus, the electromagnetic force is more powerful, hence the need for pressure. Once inside the radius of the nucleus, at least for elements smaller than lead, the binding energy is more powerful.
Is an atomic model extremely accurate?
The atomic model cannot be extremely accurate.
Is atomic nuclei required in a chemical reaction?
No, atomic nuclei is not required for a chemical reaction.
What happens at the atomic level when metal is subjected to pressure?
The metal cautions easily slide past one another.
What type of nuclear burst occurs under?
A thermonuclear burst occurs under conditions of extremely high temperature and pressure, causing the fusion of atomic nuclei and resulting in a powerful release of energy.
What is another word for atomic?
If you mean "atomic" as in the Atomic Bomb, then the word "nuclear" could be substituted = Nuclear Bomb.
What type of decay is shown in 238 94 Pu 4 2 He xyZ?
A very unlikely type of decay.Plutonium is found as isotopes with atomic weights in the range 238 to 244. Your equation seems to involve plutonium with another 39-78 neutrons! Making it an extremely unlikely (if not impossible) isotope.A very unlikely type of decay.Plutonium is found as isotopes with atomic weights in the range 238 to 244. Your equation seems to involve plutonium with another 39-78 neutrons! Making it an extremely unlikely (if not impossible) isotope.A very unlikely type of decay.Plutonium is found as isotopes with atomic weights in the range 238 to 244. Your equation seems to involve plutonium with another 39-78 neutrons! Making it an extremely unlikely (if not impossible) isotope.A very unlikely type of decay.Plutonium is found as isotopes with atomic weights in the range 238 to 244. Your equation seems to involve plutonium with another 39-78 neutrons! Making it an extremely unlikely (if not impossible) isotope.
What is the atomic particle that has an extremely small mass compared to the others?
Of the 3 atomic particles protons, neutrons and electrons, electrons have the smallest mass.
Why is a weighted average required for calculating atomic mass?
Isotopes - that same element with a different atomic weight.
