Geochemical behavior of stable strontium isotopes during continental weathering process: A review

Abstract

Continental weathering, an important geological process that affects the formation and evolution of the earth, involves the interaction of matter and energy among the lithosphere, atmosphere, hydrosphere, and biosphere. Stable Sr isotope (δ88/86Sr) is a novel non-traditional stable isotope. It has been widely discussed in tracing continental weathering, studying marine Sr cycle, and analyzing biogeochemical behavior in recent years. Its combination with 87Sr/86Sr can indicate the source of Sr and the mass fractionation of geological processes, which has incomparable advantages over other isotopic systems, such as Li, Mg, and Ba. However, owing to the small mass difference (2%) between 86Sr and 88Sr, fractionation is not significant, which makes the measurement of the ratio δ88/86Sr difficult and limits its application to trace continental weathering.In this study, major developments and challenges in using stable Sr isotopes to trace continental weathering are reviewed, when considering high-precision testing methods, characteristics of δ88/86Sr in natural reservoirs, and geochemical behaviors. The high-precision measurement methods currently used for stable Sr isotopes mainly include multi-collector inductively coupled plasma mass spectrometry (MC-ICP-MS) and thermal ionization mass spectrometry (TIMS), both of which involve chemical purification by a cation exchange column or Sr specific resin, coupled with various methods for quality discrimination correction. The present analytical precision for the determination of δ88/86Sr in geological samples is 0.02‰ ∼ 0.08‰. The δ88/86Sr varies widely in natural reservoirs. In particular, the range of δ88/86Sr values in extraterrestrial reservoirs, the biosphere, the lithosphere, and the hydrosphere are -1.73‰ to +0.66‰, -0.87‰ to +0.85‰, -0.20‰ to +0.53‰ and -0.45‰ to +0.66‰, respectively. Stable Sr isotope fractionation occurs in the processes of differential dissolution of primary minerals (Δ88/86Sr = -0.13‰), formation and adsorption of secondary minerals (Δ88/86Sr = -0.15‰), precipitation of carbonate (Δ88/86Sr = -0.20‰), and biological processes (Δ88/86Sr = -0.15‰), which causes the δ88/86Sr in fluid (solid) phase to δ88/86Sr increases (decrease). Previous research on the fractionation mechanisms and constraint conditions of stable Sr isotopes during continental weathering is insufficient. Thus, promoting a wide application of stable Sr isotopes to trace continental weathering through the combination of field profiles, laboratory experiments and theoretical calculation is urgently warranted.