When (^{222}Rn) emits a beta particle, it transforms into (^{222}Fr), which is Francium.
The nuclear reaction is: 232Th--------------- 228Ra + α
When tritium-3 emits a beta particle, it becomes helium-3. The beta particle is an electron, so when it is emitted, a neutron in the tritium nucleus is converted into a proton, resulting in helium-3, which has two protons and one neutron.
The isotope formed when tritium (3H) emits a beta particle is helium-3 (3He). This process occurs when a neutron in the tritium nucleus converts to a proton, releasing a beta particle (electron) and an electron antineutrino.
When a nucleus emits a beta particle, it loses one of its neutrons and gains one proton. Hence, it's mass and atomic number remain the same but its charge and What_happens_to_a_nucleus_when_it_emits_a_beta_particlenumber is increased by +1.
When (^{222}Rn) emits a beta particle, it transforms into (^{222}Fr), which is Francium.
When 60Co decays by beta- decay it produces 60Ni.
The nuclear reaction is: 232Th--------------- 228Ra + α
Beta Particle
When U-235 emits a beta particle, it undergoes beta decay, transforming into Neptunium-235 (Np-235). During this process, a neutron in the nucleus of U-235 is converted into a proton, releasing a beta particle in the form of an electron and an antineutrino.
When tritium-3 emits a beta particle, it becomes helium-3. The beta particle is an electron, so when it is emitted, a neutron in the tritium nucleus is converted into a proton, resulting in helium-3, which has two protons and one neutron.
The isotope formed when tritium (3H) emits a beta particle is helium-3 (3He). This process occurs when a neutron in the tritium nucleus converts to a proton, releasing a beta particle (electron) and an electron antineutrino.
When a nucleus emits a beta particle, it loses one of its neutrons and gains one proton. Hence, it's mass and atomic number remain the same but its charge and What_happens_to_a_nucleus_when_it_emits_a_beta_particlenumber is increased by +1.
Alpha decay emits an alpha particle, which consists of two protons and two neutrons. Beta decay emits either an electron (beta minus decay) or a positron (beta plus decay).
When an atom of 85Kr spontaneously decays, it emits a beta particle. This decay process involves the transformation of a neutron into a proton, with the emission of an electron and an antineutrino.
If an element emits a beta particle, it results in the transformation of a neutron into a proton within the nucleus. This process changes the element to the one that is two elements higher in the periodic table.
When C-6 (carbon-6) emits a beta particle, it becomes nitrogen-6 (N-6) as a result of beta decay. Beta decay involves the transformation of a neutron into a proton within the nucleus, causing the element to change.