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W2912101869 endingPage "459" @default.
W2912101869 startingPage "439" @default.
W2912101869 abstract "The evolution of atmospheric CO2 and the pH of the ocean can be reconstructed by the boron isotopic composition (δ11B) of marine carbonates, which is influenced by the δ11B of the seawater. Boron (B) in the ocean is primarily affected by continental weathering through rivers. Thus, it is essential to understand the behavior of B and B isotopes in rivers and the factors affecting riverine B, which require a better understanding of sources and processes of B in river systems. This review evaluates the inventories of B reservoirs contributing to rivers and investigates the processes regulating the B isotope geochemistry of rivers. B is widespread at the Earth’s surface and shows a wide range of concentrations between reservoirs. Different reservoirs also exhibit significant variations in B isotopic compositions. Mixing and Rayleigh effects are mainly responsible for the variations in the δ11B values of meteoric precipitation, which result in marine (δ11B = +37 ± 7‰), anthropogenic (δ11B = +9 ± 10‰), and mixing types (δ11B = +17 ± 13‰) of meteoric precipitation. The contribution of B to rivers from carbonate dissolution is negligible. Marine and non-marine evaporites have distinct δ11B values (marine δ11B: + 27 ± 9.4‰ and non-marine δ11B: −2 ± 8.6‰) that primarily reflect their different depositional environments. S-type granites that are tourmaline-free have an estimated δ11B value of −14.2 ± 4.9‰ and a Na/B value of 140 ± 34. Non-S-type granites have a δ11B value of −8.9 ± 6.7‰ and a Na/B value of 1190 ± 170. Intraplate basalts exhibit a δ11B value of −5.2 ± 4.4‰ and a Na/B value of 3300 ± 770. Subduction-related basalts have a δ11B value of + 0.3 ± 7.3‰ and a Na/B value of 1060 ± 830. Shale has high B contents of siliciclastic sedimentary rocks (104 ± 92 ppm). The inferred δ11B values of marine and continental shales are −8‰ and −16‰, respectively. The effects of metamorphism can vary widely depending on the geologic setting and type of protolith. The δ11B values of wastewater are investigated based on their industrial, agricultural, and urban sources. This inventory of B reservoirs can be useful for studies on rivers on a continental scale. In regolith and groundwater, B isotopic fractionation mainly occurs due to water-rock interactions and the biological cycle of B, whereas adsorption on sediments leads to minor B isotopic fractionation in rivers. In groundwater, the reactive transport model reveals that the δ11B value of river water is sensitive to hydrological conditions. In regolith, the steady-state mass balance model is used to predict the B isotope behavior of soil solution in different weathering regimes. In the supply-limited regime (where chemical weathering is limited by tectonic forcing), the precipitation of secondary minerals controls the variations in the δ11B values of soil solution, leading to an increase in the difference in the δ11B values between soil solution and parent rock (δ11Bdiss−δ11Brock) with lower denudation rates, whereas secondary mineral dissolution produces the opposite change in δ11B. In the kinetically limited regime (where chemical weathering is limited by climate), the biological cycle controls the variations in the δ11B values of soil solution, and the δ11B values of soil solution generally become closer to those of parent rock with higher denudation rates. The relationship between the denudation rates and δ11Bdiss−δ11Brock is thus not monotonous, indicating that additional constraints are required to distinguish between the two regimes. Understanding of B isotope geochemistry of rivers can be improved by better constraints on B end-member estimates, investigation of the B isotopic fractionation caused by weathering and biological cycling in regolith, and assessment of atmospheric and biological sub-cycle." @default.
W2912101869 created "2019-02-21" @default.
W2912101869 creator A5000554967 @default.
W2912101869 creator A5031720142 @default.
W2912101869 creator A5038706229 @default.
W2912101869 date "2019-03-01" @default.
W2912101869 modified "2023-10-17" @default.
W2912101869 title "Source and evolution of dissolved boron in rivers: Insights from boron isotope signatures of end-members and model of boron isotopes during weathering processes" @default.
W2912101869 cites W1155888585 @default.
W2912101869 cites W1480307302 @default.
W2912101869 cites W1502226098 @default.
W2912101869 cites W1518433208 @default.
W2912101869 cites W1525665188 @default.
W2912101869 cites W1614955224 @default.
W2912101869 cites W1625363718 @default.
W2912101869 cites W1631169069 @default.
W2912101869 cites W1672780680 @default.
W2912101869 cites W1782049738 @default.
W2912101869 cites W1817088834 @default.
W2912101869 cites W1845445271 @default.
W2912101869 cites W1886436359 @default.
W2912101869 cites W1914582446 @default.
W2912101869 cites W1955996665 @default.
W2912101869 cites W1963964994 @default.
W2912101869 cites W1965727537 @default.
W2912101869 cites W1965919385 @default.
W2912101869 cites W1966369325 @default.
W2912101869 cites W1967048892 @default.
W2912101869 cites W1967966016 @default.
W2912101869 cites W1968394970 @default.
W2912101869 cites W1969101840 @default.
W2912101869 cites W1969786067 @default.
W2912101869 cites W1970149785 @default.
W2912101869 cites W1972091303 @default.
W2912101869 cites W1972835862 @default.
W2912101869 cites W1973480527 @default.
W2912101869 cites W1974292437 @default.
W2912101869 cites W1974440712 @default.
W2912101869 cites W1974691910 @default.
W2912101869 cites W1975780204 @default.
W2912101869 cites W1976193132 @default.
W2912101869 cites W1978894916 @default.
W2912101869 cites W1980103011 @default.
W2912101869 cites W1982042911 @default.
W2912101869 cites W1982992605 @default.
W2912101869 cites W1983698989 @default.
W2912101869 cites W1984225359 @default.
W2912101869 cites W1984436789 @default.
W2912101869 cites W1985707420 @default.
W2912101869 cites W1986997704 @default.
W2912101869 cites W1987646385 @default.
W2912101869 cites W1988301208 @default.
W2912101869 cites W1989727520 @default.
W2912101869 cites W1989997789 @default.
W2912101869 cites W1991337545 @default.
W2912101869 cites W1992477437 @default.
W2912101869 cites W1992998537 @default.
W2912101869 cites W1993130046 @default.
W2912101869 cites W1993420118 @default.
W2912101869 cites W1995322397 @default.
W2912101869 cites W1995390144 @default.
W2912101869 cites W1999584133 @default.
W2912101869 cites W2000848122 @default.
W2912101869 cites W2001481384 @default.
W2912101869 cites W2002140589 @default.
W2912101869 cites W2002606625 @default.
W2912101869 cites W2004043302 @default.
W2912101869 cites W2004052805 @default.
W2912101869 cites W2005993109 @default.
W2912101869 cites W2006620025 @default.
W2912101869 cites W2007281304 @default.
W2912101869 cites W2008587428 @default.
W2912101869 cites W2010465868 @default.
W2912101869 cites W2010468221 @default.
W2912101869 cites W2011068784 @default.
W2912101869 cites W2014343207 @default.
W2912101869 cites W2014919567 @default.
W2912101869 cites W2015155734 @default.
W2912101869 cites W2016060520 @default.
W2912101869 cites W2016143081 @default.
W2912101869 cites W2018769657 @default.
W2912101869 cites W2019315183 @default.
W2912101869 cites W2019743151 @default.
W2912101869 cites W2020028063 @default.
W2912101869 cites W2020465669 @default.
W2912101869 cites W2020595147 @default.
W2912101869 cites W2020810253 @default.
W2912101869 cites W2021697797 @default.
W2912101869 cites W2021860334 @default.
W2912101869 cites W2024106365 @default.
W2912101869 cites W2025454461 @default.
W2912101869 cites W2026734845 @default.
W2912101869 cites W2026932541 @default.
W2912101869 cites W2029365544 @default.
W2912101869 cites W2029664473 @default.
W2912101869 cites W2031339543 @default.
W2912101869 cites W2032522075 @default.
W2912101869 cites W2032857836 @default.