Enriched stable Tin (Sn) isotopes:
|
| Nominal mass |
Accurate mass |
% Natural abundance |
Chemical form |
Enrichment available % |
|
| 112 Sn |
111.904826 (5) |
0.97 (1) | metal |
68 - 95+ |
|
| 114 Sn |
113.902784 (4) |
0.66 (1) |
metal |
60 - 90+ |
|
| 115 Sn |
114.903348 (3) |
0.34 (1) |
metal |
19 - 32+ |
|
| 116 Sn |
115.901747 (3) |
14.54 (9) |
metal |
95 - 99+ |
|
| 117 Sn |
116.902956 (3) |
7.68 (7) |
metal |
92 - 94+ |
|
| 118 Sn |
117.901609 (3) |
24.22 (9) |
metal, oxide |
90 - 98+ |
|
| 119 Sn |
118.903311 (3) |
8.59 (4) |
metal |
82 - 97+ |
|
| 120 Sn |
119.9021991 (29) |
32.58 (9) |
metal |
85 - 99+ |
|
| 122 Sn |
121.9034404 (30) |
4.63 (3) |
metal |
64 - 93+ |
|
| 124 Sn |
123.9052743 (17) |
5.79 (5) |
metal, oxide |
52 - 98+ |
| |
| Tin has the most stable isotopes (10) of all elements. Tin isotopes are used in a variety of applications. Sn-112 is used as precursor in the production of the radioisotope Sn-113 while Sn124 is used for producing Sb-124. Sn-116 and Sn-117 can both be used for the production of the medical radioisotope Sn-117m which is used in treating bone cancer. Both Sn-118 and Sn-119 have been evaluated for the production of Sn-119m. |
Trace Sciences: your most reliable supplier of enriched stable Tin isotopes.
We have other forms of Tin (Sn) isotopes available.
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