it emits very high energy photons
Gamma radiation emits high-energy photons, which are electromagnetic particles with no mass or charge. They are the most penetrating type of radiation and are often produced alongside alpha or beta particles during radioactive decay.
Gold-198 predominantly emits a mono-energetic gamma ray of energy 0.412 MeV. It also emits beta rays of much higher energy than that of gamma rays.
When a radioisotope emits radiation, it undergoes radioactive decay, transforming into a more stable element. This process releases energy in the form of radiation, which can be in the form of alpha particles, beta particles, or gamma rays.
Alpha particles but also electrons and gamma radiations (Th 232).
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.
Gamma
Gamma radiation emits high-energy photons, which are electromagnetic particles with no mass or charge. They are the most penetrating type of radiation and are often produced alongside alpha or beta particles during radioactive decay.
Gold-198 predominantly emits a mono-energetic gamma ray of energy 0.412 MeV. It also emits beta rays of much higher energy than that of gamma rays.
Any radioactive element gives off subatomic particles, and these particles carry considerable energy. That is the definition of radioactivity. Examples of radioactive elements include uranium, plutonium, polonium, radium, and many more.
When a radioisotope emits radiation, it undergoes radioactive decay, transforming into a more stable element. This process releases energy in the form of radiation, which can be in the form of alpha particles, beta particles, or gamma rays.
Alpha particles but also electrons and gamma radiations (Th 232).
Even gamma decay is considered to produce a particle for each decay event: the photon. Perhaps you are thinking of K capture (a form of beta decay), but it still emits a neutrino.
Even gamma decay is considered to produce a particle for each decay event: the photon. Perhaps you are thinking of K capture (a form of beta decay), but it still emits a neutrino.
When the nucleus emits an alpha or beta particle, it is in the exited state. To return to the ground state, it has to emit energy. It emits this energy in the form of gamma rays. There is no change in the atomic no or the mass no when it emits gamma rays, but it does decrease the energy in the nucleus when gamma rays are emitted
In the process of radioactive decay an unstable atomic nucleus emits energy to get closer to a state of stability. Whether this energy is emitted in particles, electromagnetic radiation, or both depends on which decay paths are available to the nucleus and which decay paths are forbidden to the nucleus by Quantum Mechanics.Some of the decay processes are:alpha - energy is released in the momentum of the ejected alpha particle (helium nucleus)beta - energy is released in the momentum of the ejected electron or positron (and the hard to detect neutrino)gamma - energy is released as electromagnetic radiation (gamma ray photon)spontaneous fission - energy is released in the momentum of the ejected fission product atoms and the ejected neutrons
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.
A gamma particle, which is a photon of high-energy electromagnetic radiation, is typically formed during nuclear reactions such as beta decay or fusion. When a nucleus transitions from an excited state to a lower-energy state, it emits a gamma particle to balance its energy levels.