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meteorite abundance of insulators

Input interpretation

insulators | meteorite abundance
insulators | meteorite abundance

Summary

median | 1.6×10^-4 mass% highest | 4 mass% (sulfur) lowest | 2.5×10^-5 mass% (iodine)
median | 1.6×10^-4 mass% highest | 4 mass% (sulfur) lowest | 2.5×10^-5 mass% (iodine)

Units

Ranked values

| | visual | ratios | 5 | iodine | | 6×10^-6 | 1 4 | bromine | | 3×10^-5 | 4.8 3 | boron | | 4×10^-5 | 6 2 | chlorine | | 0.009 | 1500 1 | sulfur | | 1 | 160000
| | visual | ratios | 5 | iodine | | 6×10^-6 | 1 4 | bromine | | 3×10^-5 | 4.8 3 | boron | | 4×10^-5 | 6 2 | chlorine | | 0.009 | 1500 1 | sulfur | | 1 | 160000

Meteorite abundance rankings

1 | iodine | 2.5×10^-5 mass% 2 | bromine | 1.2×10^-4 mass% 3 | boron | 1.6×10^-4 mass% 4 | chlorine | 0.037 mass% 5 | sulfur | 4 mass%
1 | iodine | 2.5×10^-5 mass% 2 | bromine | 1.2×10^-4 mass% 3 | boron | 1.6×10^-4 mass% 4 | chlorine | 0.037 mass% 5 | sulfur | 4 mass%

Unit conversion for median meteorite abundance 1.6×10^-4 mass%

1.6 ppmm (parts per million by mass)
1.6 ppmm (parts per million by mass)

Corresponding quantity

Corresponding mass ratio: | 1.6 µg/g (micrograms per gram) | 0.16 mg/100 g (milligrams per hundred grams) | 1.6 g/t (grams per metric ton)
Corresponding mass ratio: | 1.6 µg/g (micrograms per gram) | 0.16 mg/100 g (milligrams per hundred grams) | 1.6 g/t (grams per metric ton)

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