La-Ce isotope measurements by multicollector-ICPMS

The La- Ce decay system (half-life 1.02 × 10 years) is a potentially highly useful tool to unravel information about the timing of geological processes and about the interaction of geological reservoirs on earth, complementing information from the more popular Sm- Nd and Lu- Hf isotope systems. Prev...

Full description

Saved in:
Bibliographic Details
Published in:Journal of analytical atomic spectrometry 2017-12, Vol.32 (12), p.2360-2370
Main Authors: Schnabel, Christiane, Münker, Carsten, Strub, Erik
Format: Article
Language:English
Subjects:
Cation exchanging
Cerium
Chromatography
Cologne
Dating techniques
Dilution
Geochemistry
Geology
Hafnium isotopes
Isotopes
Lanthanum
Mathematical analysis
Neodymium isotopes
Oxidation
Protocol
Rare earth elements
Reference materials
Reproducibility
Sensitivity analysis
Separation
Citations: Items that this one cites
Items that cite this one
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:The La- Ce decay system (half-life 1.02 × 10 years) is a potentially highly useful tool to unravel information about the timing of geological processes and about the interaction of geological reservoirs on earth, complementing information from the more popular Sm- Nd and Lu- Hf isotope systems. Previously published analytical protocols were limited to TIMS. Here we present for the first time an analytical protocol that employs MC-ICPMS, with an improved precision and sensitivity. To perform sufficiently accurate La-Ce measurements, an efficient ion-chromatographic procedure is required to separate Ce from the other rare earth elements (REE) and Ba quantitatively. This study presents an improved ion-chromatographic procedure that separates La and Ce from rock samples using a three-step column separation. After REE separation by cation exchange, Ce is separated employing an Ln Spec column and selective oxidation. In the last step, a cation clean-up chemistry is performed to remove all remaining interferences. Our MC-ICPMS measurement protocol includes all stable Ce isotopes ( Ce, Ce, Ce and Ce), by employing a 10 ohm amplifier for the most abundant isotope Ce. An external reproducibility of ±0.25 -units (2 r.s.d) has been routinely achieved for Ce measurements for as little as 150-600 ng Ce, depending on the sample-skimmer cone combinations being used. Because the traditionally used JMC-304 Ce reference material is not commercially available anymore, a new reference material was prepared from AMES laboratory Ce metal (Cologne-AMES). In order to compare the new material with the previously reported isotopic composition of AMES material prepared at Mainz (Mainz-AMES), Cologne-AMES and JMC-304 were measured relative to each other in the same analytical session, demonstrating isotope heterogeneity between the two AMES and different JMC-304 batches used in the literature. To enable sufficiently precise age correction of radiogenic Ce and to perform isochron dating, a protocol was developed where La and Ce concentrations are determined by isotope dilution (ID), using an isotope tracer enriched in La and Ce. The new protocols were applied to determine the variations of Ce isotope compositions and La-Ce concentrations of certified geochemical reference materials (CRMs): BCR-2, BCR-1, BHVO-2, JR-1, JA-2, JB-3, JG-1, JR-1, JB-1b, AGV-1 and one in-house La Palma standard.
ISSN:0267-9477
1364-5544
DOI:10.1039/c7ja00256d