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When a nucleus emits a gamma ray photon, it releases high-energy electromagnetic radiation. This process is known as gamma decay, and it typically occurs after alpha or beta decay has taken place. Gamma rays have no mass or charge and are highly penetrating, which makes them useful in various fields such as medicine, industry, and research.
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What effect does losing a gamma ray have on the nucleus?
Losing a gamma ray does not change the number of protons or neutrons in the nucleus, so the nucleus remains the same element. However, the nucleus may be left in an excited state after emitting a gamma ray, and it typically returns to its ground state quickly by emitting the gamma ray.
What type of radioactive decay involves only the release of high energy photons and therefore does not change the mass of the radionuclide?
There is no normal process by which a nucleus can release energy without changing the element. Even gamma radiation, which is photon emission from the nucleus during a restabilization sequence, has a predecessor, i.e. usually beta or alpha, which does change the element.
Gamma rays have the same basic nature as?
Gamma rays have the same basic nature as X-rays and are a form of electromagnetic radiation. They are high-energy photons with the shortest wavelengths and highest frequencies in the electromagnetic spectrum.
Is it possible to make a gamma with just an electron gun and something that will make it short enough to produce gamma rays?
No. Gamma radiation is photons that emanate from the nucleus in response to a reduction in that nucleus' excitation state. The interaction of electrons, on the other hand, produces x-rays. X-rays, while still photons, are generally less in energy than gamma radiation. Though there is some overlap, and while it is true that a photon is a photon, gamma radiation and x-rays are not the same thing.
Photons with the highest energy have?
Photons with the highest energy have shorter wavelengths and higher frequencies. These photons are known as gamma rays and are produced by processes such as nuclear reactions and particle interactions. They are the most energetic form of electromagnetic radiation.
What effect does losing a gamma ray have on the nucleus?
Losing a gamma ray does not change the number of protons or neutrons in the nucleus, so the nucleus remains the same element. However, the nucleus may be left in an excited state after emitting a gamma ray, and it typically returns to its ground state quickly by emitting the gamma ray.
Are the gamma rays photons in the sun because they act the same?
the core
What type of radioactive decay involves only the release of high energy photons and therefore does not change the mass of the radionuclide?
There is no normal process by which a nucleus can release energy without changing the element. Even gamma radiation, which is photon emission from the nucleus during a restabilization sequence, has a predecessor, i.e. usually beta or alpha, which does change the element.
What change in atomic mass when an atom emits gamma radiation?
It remains the same.
Gamma rays have the same basic nature as?
Gamma rays have the same basic nature as X-rays and are a form of electromagnetic radiation. They are high-energy photons with the shortest wavelengths and highest frequencies in the electromagnetic spectrum.
What is released from the nucleus during gamma decay?
Alpha decay means that an alpha particle (helium-4 nucleus) is emitted.Alpha decay means that an alpha particle (helium-4 nucleus) is emitted.Alpha decay means that an alpha particle (helium-4 nucleus) is emitted.Alpha decay means that an alpha particle (helium-4 nucleus) is emitted.
Does nucleus changes its charge while emitting from beta and gamma particles simultaneously?
No, the nucleus does not change its overall charge when emitting beta and gamma particles simultaneously. Beta particles are high-energy electrons or positrons emitted during beta decay, whereas gamma particles are high-energy photons emitted during gamma decay. Both types of particles are neutral, so the overall charge of the nucleus remains the same.
What happens when an atom emits?
It is actually the nucleus of the atom that emits energy. The energy we can harness comes from fission or splitting of the nucleus of uranium235 or plutonium239. The nucleus splits into two parts which recoil and give up their kinetic energy as heat when they are stopped in the fuel, and there is also some energy from gamma rays at the same time. Basically in the process the final results of the fission have lost mass, and this appears as energy following the relation E = M x C2. Atoms can also emit energy as radioactivity, without fissioning. This can be alpha, beta, or gamma radiation. Alpha and beta are particles, so that the resulting nucleus is changed and there results a different element. Gamma is a penetrating ray in the electromagnetic spectrum and corresponds to a change in the energy state of the nucleus, but it remains the same element.
Is it possible to make a gamma with just an electron gun and something that will make it short enough to produce gamma rays?
No. Gamma radiation is photons that emanate from the nucleus in response to a reduction in that nucleus' excitation state. The interaction of electrons, on the other hand, produces x-rays. X-rays, while still photons, are generally less in energy than gamma radiation. Though there is some overlap, and while it is true that a photon is a photon, gamma radiation and x-rays are not the same thing.
Does the emission of alpha beta and gamma radiations take place from a nucleus at the same time?
No.
How does magnetism effect gamma radiation?
No. Gamma rays are photons (light particles). Photons are particles with no mass, no charge and no magnetic moment.
Does transmutation occur in gamma decay?
No, transmutation does not occur in gamma decay. Gamma decay is a type of radioactive decay where a nucleus releases a gamma ray photon to reach a more stable state, but the identity of the nucleus remains the same. Transmutation involves the change of one element into another through various nuclear reactions.
