Oxygen isotopic fractionation of O₂ during adsorption and desorption processes using molecular sieve at low temperatures

Insu Ahn; Minoru Kusakabe; Jong Ik Lee

doi:10.1002/rcm.6898

Oxygen isotopic fractionation of O₂ during adsorption and desorption processes using molecular sieve at low temperatures

Rapid Commun Mass Spectrom. 2014 Jun 15;28(11):1321-8. doi: 10.1002/rcm.6898.

Authors

Insu Ahn¹, Minoru Kusakabe, Jong Ik Lee

Affiliation

¹ Korea Polar Research Institute, Incheon, 406-840, Korea; Department of Earth and Planetary Material Science, Tohoku University, Aramaki, Aoba, Sendai, Miyagi, 980-8578, Japan.

PMID: 24760573
DOI: 10.1002/rcm.6898

Abstract

Rationale: Cryogenic trapping using molecular sieves is commonly used to collect O2 extracted from silicates for (17)O/(16)O and (18)O/(16)O analyses. However, gases which interfere with (17)O/(16)O analysis, notably NF3, are also trapped and their removal is essential for accurate direct measurement of the (17)O/(16)O ratio. It is also necessary to identify and quantify any isotopic fractionation associated with the use of cryogenic trapping using molecular sieves.

Methods: The oxygen isotopic compositions of O2 before and after desorption from, and adsorption onto, 13X and 5A molecular sieves (MS13X and MS5A) at 0°C, -78°C, -114°C, and -130°C were measured in order to determine the oxygen isotopic fractionation at these temperatures. We also investigated whether isotopic fractionation occurred when O2 gas was transferred sequentially into a second cold finger, also containing molecular sieve.

Results: It was confirmed that significant oxygen isotopic fractionation occurs between the gaseous O2 and that adsorbed onto molecular sieve, if desorption and adsorption are incomplete. As the fraction of released or untrapped O2 becomes smaller with decreasing trapping temperature (from 0 to -130°C), the isotopic fractionation becomes larger. Approximately half of the total adsorbed O2 is released from the molecular sieve during desorption at -114°C, which is the temperature recommended for separation from NF3 (retained on the molecular sieve), and this will interfere with (17)O/(16)O measurements.

Conclusions: The use of a single cold finger should be avoided, because partial desorption is accompanied by oxygen isotopic fractionation, thereby resulting in inaccurate isotopic data. The use of a dual cold finger arrangement is recommended because, as we have confirmed, the transfer of O2 from the first trap to the second is almost 100%. However, even under these conditions, a small isotopic fractionation (0.18 ± 0.05‰ in δ(17)O values and 0.26 ± 0.06‰ in δ(18)O values) occurred, with O2 in the second trap being isotopically enriched in the heavier isotopes.