Tellurium-125

Main isotopes of tellurium

iso	NA	half-life	DM	DE (MeV)	DP
¹²⁰Te	0.09%	is stable with 68 neutrons
¹²¹Te	syn	16.78 d	ε	1.040	¹²¹Sb
¹²²Te	2.55%	is stable with 70 neutrons
¹²³Te	0.89%	is stable with 71 neutrons
¹²⁴Te	4.74%	is stable with 72 neutrons
¹²⁵Te	7.07%	is stable with 73 neutrons
¹²⁶Te	18.84%	is stable with 74 neutrons
¹²⁷Te	syn	9.35 h	β⁻	0.698	¹²⁷I
¹²⁸Te	31.74%	2.2×10²⁴ y	β⁻β⁻	0.867	¹²⁸Xe
¹²⁹Te	syn	69.6 min	β⁻	1.498	¹²⁹I
¹³⁰Te	34.08%	7.9×10²⁰ y	β⁻β⁻	2.528	¹³⁰Xe

Standard atomic weight (A_r)

127.60(3)

There are 38 known isotopes and 17 nuclear isomers of tellurium (₅₂Te), with atomic masses that range from 105 to 142. These are listed in the table below.

Naturally-occurring tellurium on Earth consists of eight isotopes. Two of these have been found to be radioactive: ¹²⁸Te and ¹³⁰Te undergo double beta decay with half-lives of, respectively, 2.2×10²⁴ (2.2 septillion) years (the longest half-life of all nuclides proven to be radioactive) and 7.9×10²⁰ (790 quintillion) years. The longest-lived artificial radioisotope of Tellerium is ¹²¹Te with a half-life of nearly 19 days. Several nuclear isomers have longer half-lives, the longest being ^121mTe with a half-life of 154 days.

The very-long-lived radioisotopes ¹²⁸Te and ¹³⁰Te are the two most common isotopes of tellurium. Of elements with at least one stable isotope, only indium and rhenium likewise have a radioisotope in greater abundance than a stable one.

It has been claimed that electron capture of ¹²³Te was observed, but the recent measurements of the same team have disproved this. The half-life of ¹²³Te is longer than 9.2 × 10¹⁶ years, and probably much longer.

¹²⁴Te can be used as a starting material in the production of radionuclides by a cyclotron or other particle accelerators. Some common radionuclides that can be produced from tellurium-124 are iodine-123 and iodine-124.

The short-lived isotope ¹³⁵Te (half-life 19 seconds) is produced as a fission product in nuclear reactors. It decays, via two beta decays, to ¹³⁵Xe, the most powerful known neutron absorber, and the cause of the iodine pit phenomenon.

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