Potassium isotope fractionation during chemical weathering of basalts

Potassium isotope fractionation during chemical weathering of basalts

•We report high-precision K isotopes of two weathering profiles developed on basalts.•Deposition of aeolian dust and formation of secondary minerals control K isotopic composition of bauxite profiles.•Weathering of igneous rocks leads to loss of isotopically heavy K from the continents.•Heavy K isot...

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Bibliographic Details
Published in:Earth and planetary science letters Vol. 539; p. 116192
Main Authors: Chen, Heng, Liu, Xiao-Ming, Wang, Kun
Format: Journal Article
Language:English
Published: Elsevier B.V 01-06-2020
Subjects:
basalt
chemical weathering
clay minerals
global potassium cycle
potassium isotopes
potassium isotopes
chemical weathering
clay minerals
basalt
global potassium cycle
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Summary:•We report high-precision K isotopes of two weathering profiles developed on basalts.•Deposition of aeolian dust and formation of secondary minerals control K isotopic composition of bauxite profiles.•Weathering of igneous rocks leads to loss of isotopically heavy K from the continents.•Heavy K isotopic composition in modern seawater results from both continental weathering and silicate fixation. Non-traditional stable isotopes (e.g., Li, Mg, and Si) are increasingly used as tracers for studying Earth's surface processes. The isotopes of potassium (K), a highly soluble and mobile element during weathering, could be a promising new tracer for continental weathering; however, the K isotopic variations in weathering profile has not been directly studied due to previous analytical difficulties. Recent high-precision measurements revealed that K isotopes in global river waters are fractionated from the Bulk Silicate Earth (BSE) value, indicating they are influenced by chemical weathering of the crust. Isotopic fractionation during chemical weathering is one of several processes that could ultimately lead to ∼0.6‰ difference of δ41K between the BSE and modern seawater. In order to determine the direction and controlling factors of K isotopic fractionation during basalt weathering, especially under intense weathering conditions, we measured K isotopic compositions in two sets of bauxite developed on the Columbia River Basalts, together with fresh parental basalt and aeolian deposit samples using a recently developed high-precision method. Results show that K isotopic variations among fresh basalts and aeolian dust are limited, close to the BSE value. Extreme K depletion (>99%) and K isotopic fractionation (δ41K up to 0.5 ‰) are observed in bauxite drill cores due to intense chemical weathering. The top of the weathering profiles shows less depletion in K abundances and the δ41K values are closer to those of the fresh basalts and aeolian dusts, likely due to addition of aeolian dust at the tops of both profiles. The weathered products are generally depleted in heavy K isotopes, which is consistent with heavier K isotopic compositions observed in river water and seawater. The δ41K in bauxites displays a positive correlation with K2O contents as well as δ7Li, indicating the behaviors of K and Li isotopes are comparable during chemical weathering. This study shows that K concentrations and its isotopic compositions are sensitive tracers of chemical weathering and could be good weathering proxies over Earth's history.
ISSN:0012-821X
1385-013X
DOI:10.1016/j.epsl.2020.116192