Isotopes of niobium

Naturally occurring niobium is composed of one stable isotope. The most stable radioisotope is ⁹²Nb with a half-life of 34.7 million years, followed by are ⁹⁴Nb at a half-life of 20,400 years and ⁹¹Nb at 680 years. Other radioisotopes that have been synthesized range from ⁸²Nb to ¹¹⁰Nb; these have half-lives that are less than two hours, except ⁹⁵Nb, ⁹⁶Nb and ⁹⁰Nb.
The most stable of the meta states is ^93mNb with excitation energy 31 keV and a 16.1 year half-life; this is produced in the decay of ⁹³Zr. The primary decay mode before stable ⁹³Nb is electron capture to zirconium isotopes and the primary mode after is beta emission, with delayed neutron emission starting at ¹⁰⁴Nb, leading to molybdenum isotopes.
Only ⁹⁵Nb, along with ⁹⁷Nb and heavier isotopes are fission products in significant quantity, as the other isotopes are shadowed by stable or very long-lived isotopes of the preceding element zirconium from the usual mode of production through beta decay of neutron-rich fission fragments. ⁹⁵Nb is the decay product of ⁹⁵Zr, so disappearance of ⁹⁵Nb in used nuclear fuel is slower than would be expected from its own 35-day half-life alone.

List of isotopes

Niobium-92

Niobium-92 is an extinct radionuclide with a half-life of 34.7 million years, decaying predominantly via β⁺ decay. Its abundance relative to the stable ⁹³Nb in the early Solar System, estimated at 1.7×10⁻⁵, has been measured to investigate the origin of p-nuclei. A higher initial abundance of ⁹²Nb has been estimated for material in the outer protosolar disk, suggesting that this nuclide was predominantly formed via the gamma process in a nearby core-collapse supernova.
Niobium-92, along with niobium-94, has been detected in refined samples of terrestrial niobium and may originate from bombardment by cosmic ray muons in Earth's crust.