The equation for the beta decay of 165Ta is:
73165Ta --> 72165Hf + 10e + ve
where the e is a positive beta particle or positron.
T99 is Technetion 99 has a Decay rate of 6h
Technetium-99 is produced through the decay of Molybdenum-99. Molybdenum-99 undergoes beta decay to form Technetium-99, with the emission of a beta particle (electron) and an antineutrino. This decay process is commonly utilized in nuclear medicine for imaging and diagnostic purposes.
The nuclear decay equation for Po-208 is: Po-208 → Pb-204 + He-4
Technetium is not found in nature in appreciable amounts because it has no stable isotopes. It undergoes radioactive decay relatively quickly, making it rare and short-lived in the Earth's crust. Any technetium present on Earth is likely formed as a byproduct of nuclear reactions or artificially created in laboratories.
This depends on a specified isotope of technetium !
T99 is Technetion 99 has a Decay rate of 6h
All nuclear decay is spontaneous.
Technetium-99 is produced through the decay of Molybdenum-99. Molybdenum-99 undergoes beta decay to form Technetium-99, with the emission of a beta particle (electron) and an antineutrino. This decay process is commonly utilized in nuclear medicine for imaging and diagnostic purposes.
The nuclear decay equation for Po-208 is: Po-208 → Pb-204 + He-4
Natural chromium is stable and does not decay/
Energy and electrical charge are two quantities that are always conserved in nuclear decay equation.
The "m" in 99mTc indicates that the technetium is in a metastable state. This means that the technetium is in an excited nuclear state that will decay to a more stable state by emitting gamma radiation. Metastable technetium is commonly used in nuclear medicine imaging.
Technetium is not found in nature in appreciable amounts because it has no stable isotopes. It undergoes radioactive decay relatively quickly, making it rare and short-lived in the Earth's crust. Any technetium present on Earth is likely formed as a byproduct of nuclear reactions or artificially created in laboratories.
The decay equation is:Co-60----------------------Ni-60 + e-
The equation for the beta decay of 17F: 917F --> 817O+ 10e + ve where the 10e is a positive beta particle or positron.
The equation for the beta decay of 14C: 614C --> 714N + -10e where the e is an electron.
The balanced nuclear equation for the beta decay of potassium-42 is: ^42K -> ^42Ca + e^- + νe