A Fast Separation Method for Isotope Analysis Based on Compressed Nitrogen Gas and Ion-Exchange Chromatography Technique—A Case Study of Sr-Nd Isotope Measurement

Honglin Yuan; Xu Liu; Zhian Bao; Kaiyun Chen; Chunlei Zong

doi:10.1007/s12583-017-0944-0

Journal of Earth Science ›› 2018, Vol. 29 ›› Issue (1) : 223 -229. DOI: 10.1007/s12583-017-0944-0

Isotope Geochronology

A Fast Separation Method for Isotope Analysis Based on Compressed Nitrogen Gas and Ion-Exchange Chromatography Technique—A Case Study of Sr-Nd Isotope Measurement

Honglin Yuan ¹^,³^,^a
, Xu Liu ²
, Zhian Bao ¹^,³
, Kaiyun Chen ¹^,³
, Chunlei Zong ¹^,³

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Abstract

High-purity N₂ was used to increase the mobile phase flow rate during ion purification of ion-exchange resin. This was performed to improve the efficiency of isotope separation and purification, and to meet the efficiency requirements of rapid multiple-collector-inductively coupled plasma mass spectrometry (MC-ICPMS) analysis. For Cu isotope separation, our results indicated that at a gas flow rate >60 mL/min, the separation chromatographic peaks broadened and the recovery rate decreased to <99.2%. On the other hand, no significant change in the Cu peaks was observed at a gas flow rate of 20 mL/min and the recovery rate was determined to be >99.9%. The Cu isotope ratio, measured by the standard-sample bracketing method, agreed with reference data within a ±2 SD error range. The separation time was reduced from the traditional 10 h (without N₂) to 4 h (with N₂), indicating that the efficiency was more than doubled. Moreover, Sr and Nd isotope separation in AGV-2 (US Geological Survey andesite standard sample) accelerated with a 20 mL/min gas flow, demonstrating that with the passage of N₂, the purified liquid comprised Rb/Sr and Sm/Nd ratios of <0.000 049 and <0.000 001 5, respectively. This indicated an effective separation of Rb from Sr and Sm from Nd. MC-ICPMS could therefore be applied to accurately determine Sr and Nd isotope ratios. The results afforded were consistent with the reference data within a ±2 SD error range and the total separation time was shortened from 2 d to <10 h.

Keywords

fast isotope purification / MC-ICPMS / N₂ gas flow / Cu isotope / Sr-Nd isotopes

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Honglin Yuan, Xu Liu, Zhian Bao, Kaiyun Chen, Chunlei Zong. A Fast Separation Method for Isotope Analysis Based on Compressed Nitrogen Gas and Ion-Exchange Chromatography Technique—A Case Study of Sr-Nd Isotope Measurement. Journal of Earth Science, 2018, 29(1): 223-229 DOI:10.1007/s12583-017-0944-0

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