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Decay energy is the energy that has been freed during radioactive decay. When radioactive decay is ongoing it drops off some energy by means of discharging radiation.

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The energy of beta particles in beta decay is not fixed because it depends on the specific isotope and decay process involved. Beta decay can produce high-energy electrons and positrons through beta minus and beta plus decay, respectively. The energy of the beta particles is determined by the energy released during the decay process.

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Gamma decay produces energy in the form of gamma rays, which are high-energy electromagnetic radiation, instead of particles. Gamma decay occurs when an unstable atomic nucleus transitions to a lower energy state by releasing gamma rays.

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The endpoint energy of a beta particle is the maximum kinetic energy it can have after being emitted in a beta decay process. This energy depends on the specific isotope undergoing decay, with different isotopes having different endpoint energies.

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The energy released in radioactive decay comes from the conversion of mass from the parent atom into energy according to Einstein's famous equation, E=mc². This energy is released in the form of radiation or kinetic energy of the decay products.

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Yes, gamma decay emits energy in the form of gamma radiation, which is a high-energy electromagnetic wave. Gamma decay does not emit any particles, only electromagnetic radiation.

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Gamma decay occurs when an excited nucleus releases energy in the form of a gamma ray photon in order to reach a more stable energy state. This type of decay often follows alpha or beta decay processes, as the nucleus transitions to lower energy levels. Gamma decay allows the nucleus to shed excess energy without changing its atomic number or mass.

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The end point energy of a beta decay is the kinetic energy of all particles emitted through B-decay. This is often ignoring the energy of the recoiling daughter nucleus.

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the heat radiantof the energy

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The decay of radioactive elements in the Earth's crust, particularly uranium, thorium, and potassium, generates geothermal energy. This decay produces heat that warms the surrounding rock and water, leading to the formation of geothermal reservoirs that can be harnessed for energy production.

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Energy loss in the form of emitted radiation during radioactive decay occurs because the nucleus becomes more stable by undergoing the decay process. The emitted radiation carries away energy and particles, resulting in a more stable nucleus with lower energy levels. Thus, radioactive decay helps to increase the overall stability of the nucleus by reducing excess energy.

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Because its not a decay process. Gamma is an emission of energy in the form of photons from the nucleus when the nucleus changes from one energy level to a lower energy level. It is true that this is often preceded by a decay event, such as alpha or beta, but it is a distinct, non decay, event.

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Alpha decay is the loss of 2 protons and 2 neutrons

Beta-decay is the loss of a positron or electron

Gamma decay is the loss of a photon

The equation relates this loss to energy produced E=mc^2

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No, gamma decay does not change the atomic number of an atom. Gamma decay involves the release of high-energy electromagnetic radiation (gamma rays) from the nucleus of an atom, but it does not affect the number of protons in the nucleus, which determines the atomic number.

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No, an input of energy is not required for nuclear decay to happen in an atom. Nuclear decay is a spontaneous process that occurs when an unstable nucleus emits particles or energy to become more stable.

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  • alpha decay - fully ionized helium nuclei
  • beta decay - electrons or positrons, and electron neutrinos
  • gamma decay - very high energy photons

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In radioactive decay, unstable nuclei release energy in the form of radiation as they transform into more stable configurations. This release of energy is due to the conversion of mass into energy according to Einstein's famous equation, E=mc^2. As the nucleus becomes more stable through radioactive decay, it loses energy and transitions to a lower energy state.

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From weakest to strongest decay, the order is:

  1. Gamma decay - involves the emission of high-energy photons.
  2. Beta decay - involves the emission of beta particles (electrons or positrons).
  3. Alpha decay - involves the emission of alpha particles (helium nuclei).

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Gamma rays consist of high-energy waves and always accompany alpha and beta decay processes. They are electromagnetic radiation emitted from the nucleus of an atom during radioactive decay to achieve a more stable state.

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The process of a radioactive decay is atomic nucleus of an unstable atom loses energy by emitting ionizing particles

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Coal is a material that formed from the decay of ancient organisms and is used today as a source of energy.

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Gamma decay can be stopped by dense materials such as lead or concrete, which absorb and block the high-energy gamma rays emitted during the decay process.

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Radioactive decay, specifically the decay of elements like uranium, thorium, and potassium, occurs in the mantle. This decay releases heat energy, which drives convection currents in the mantle. This movement of material helps transfer heat from the Earth's interior to the surface.

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"geothermal" (the source is a combination of original impact energy and radioactive decay.)

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The decay that releases only energy without any particles is called gamma decay. In this process, an excited atomic nucleus releases excess energy in the form of gamma rays (high-energy photons) to transition to a lower energy state.

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decay of radioactive elements

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To conserve energy in beta decay.

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Gamma decay consists of the emission of gamma rays, which are high-energy photons. This type of radioactive decay occurs when an unstable nucleus releases excess energy in the form of gamma rays to become more stable.

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Gamma decay releases high-energy gamma rays, which are a form of electromagnetic radiation. These gamma rays carry a significant amount of energy and are emitted from the atomic nucleus during gamma decay to help the nucleus transition to a more stable state.

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Yes, that's more or less what happens in the case of radioactive decay.

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Gamma decay stops when the nucleus reaches a stable energy state. This process involves the emission of high-energy photons (gamma rays) from the nucleus to release excess energy and achieve a more stable configuration.

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Nuclear decay is a process where an unstable nucleus releases energy in the form of radiation (such as alpha, beta, or gamma particles) to become more stable. This energy release can take the form of heat, light, or kinetic energy, depending on the type of decay.

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During radioactive decay, the energy transformation that occurs is the conversion of nuclear potential energy within the unstable atomic nucleus into various forms of energy such as heat, electromagnetic radiation (gamma rays), and kinetic energy of emitted particles (alpha and beta particles).

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Nuclear energy is either:

  • fission reaction, or
  • fusion reaction, or
  • radioactive decay

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Decay and radiation occur at the atomic level within unstable nuclei of atoms. Decay is the process where an unstable nucleus emits particles or energy to become more stable, while radiation refers to the particles or energy emitted during this process. Both decay and radiation can occur in natural radioactive elements or in artificially created radioactive isotopes.

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The decay of radioactive isotopes in the Earth's crust, such as uranium and thorium, causes geothermal energy by producing heat as a byproduct. This heat warms underground water reservoirs, creating geothermal resources that can be harnessed for energy production.

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All nuclear decay releases both energy and particles. Even gamma rays from the meta stable decay of Technetium-99m, being only photons, are particles, because a photon is considered a particle - or is it energy? - or is it mass? - hmmm? - see quantum mechanics on that one.

Also, Einsten's famous mass energy equivalence equation e = mc2 states rather plainly that energy is mass and mass is energy. That means that if nuclear decay releases energy, then it also releases mass, and vice versa. There is no way around the equivalence.

Do not misunderstand this. The equation does not mean that energy can be converted into mass or vice versa, it means that energy is mass and vice versa. Neither energy nor mass can be created nor destroyed. So, when an atomic bomb goes off and loses mass generating a high amount of energy, the mass that is lost is simply carried away with the energy.

Sorry if it seems I deviated from the topic, but I did not. This is part of reinforcing the answer and enhancing the explanation.

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The name of the spontaneous process is nuclear decay or radioactive decay. This process involves the release of particles (such as alpha or beta particles) and energy from the unstable nucleus of an atom in order to achieve a more stable configuration.

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The radioactive decay produces heat energy, which keeps the convection currents moving.

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Energy and electrical charge are two quantities that are always conserved in nuclear decay equation.

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Radioactive decay happens because unstable atomic nuclei release energy in the form of radiation to become more stable.

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