Lithium isotope fractionation during uptake by gibbsite

Wimpenny, Josh; Colla, Christopher A.; Yu, Ping; Yin, Qing‐Zhu; Rustad, James R.; Casey, William H.

doi:10.1016/j.gca.2015.07.011

Cited by 74 publications

(61 citation statements)

References 77 publications

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“…Therefore, this confirms that clay formation strongly affects Li isotope fractionation (Bouchez et al, 2013;Wimpenny et al, 2015;Wimpenny et al, 2010), but also adds to the mass balance argument made above, that it is secondary mineral formation, rather than sorption, that is largely controlling Li isotope fractionation in this experiment (84-88% of Li by mass balance) (Hindshaw et al, 2019;Pistiner and Henderson, 2003;Vigier et al, 2008;Wimpenny et al, 2015). here (Pogge von Strandmann et al, 2006;Vigier et al, 2009).…”

Section: Mineral Saturation Statessupporting

confidence: 86%

“…sorbed Li) and the secondary mineral fraction (i.e. Li substituting into the crystal structures of neoforming minerals) (Chan and Hein, 2007;Millot and Girard, 2007;Pistiner and Henderson, 2003;Vigier et al, 2008;Wimpenny et al, 2015;Wimpenny et al, 2010). For this mass balance, we assume that the Na acetate leach represents the exchangeable fraction, while the subsequent HCl leach represents Li recovered from secondary minerals (including oxyhydroxides and clays or zeolites).…”

Section: Lithium Mass Balancementioning

confidence: 99%

“…However, while the general mechanics of Li isotope fractionation during weathering are fairly well understood, there is less information available on the precise processes that d 7 Li traces, such as whether the primary fractionation mechanism is adsorption onto secondary mineral surfaces, uptake into interlayer sites, or via structural or lattice-bound incorporation into neoformed minerals (Hindshaw et al, 2019;Pistiner and Henderson, 2003;Pogge von Strandmann et al, 2010;Wimpenny et al, 2015). Further, fractionation factors and reaction kinetics are also poorly known.…”

Section: Introductionmentioning

confidence: 99%

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Experimental determination of Li isotope behaviour during basalt weathering

et al. 2019

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Silicate weathering is the primary control of atmospheric CO2 concentrations on multiple timescales. However, tracing this process has proven difficult. Lithium isotopes are a promising tracer of silicate weathering. This study has reacted basalt sand with natural river water for ~9 months in closed experiments, in order to examine the behaviour of Li isotopes during weathering. Aqueous Li concentrations decrease by a factor of ~10 with time, and d 7 Li increases by ~19‰, implying that Li is being taken up into secondary phases that prefer 6 Li. Mass balance using various selective leaches of the exchangeable and secondary mineral fractions suggest that ~12-16% of Li is adsorbed, and the remainder is removed into neoformed secondary minerals. The exchangeable fractionation factors have a D 7 Liexch-soln =-11.6 to-11.9‰, while the secondary minerals impose D 7 Lisecmin-soln =-22.5 to-23.9‰. Overall the experiment can be modelled with a Rayleigh fractionation factor of a = 0.991, similar to that found for natural basaltic rivers. The mobility of Li relative to the carbon-cycle-critical cations of Ca and Mg changes with time, but rapidly evolves within one month to remarkably similar mobilities amongst these three elements. Th evolution shows a linear relationship with d 7 Li (largely due to a co-variation between aqueous [Li] and d 7 Li), suggesting that Li isotopes have the potential to be used as a tracer of Ca and Mg mobility during basaltic weathering, and ultimately CO2 drawdown.

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Section: Mineral Saturation Statessupporting

confidence: 86%

Section: Lithium Mass Balancementioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Experimental determination of Li isotope behaviour during basalt weathering

et al. 2019

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“…The range of isotopic fractionation factors in Fig. 5 are consistent with experimentally determined values for various secondary minerals, including those predicted to be oversaturated within the Lena River (see section 5.2), with αvermiculite = 0.971, αkaolinite = 0.979, αgibbsite = 0.984-0.993, αferrihydrite ≈ 0.998, and αsmectite = 0.984 (Zhang et al 1998;Pistiner and Henderson, 2003;Millot and Girard, 2007;Vigier et al 2008;Wimpenny et al 2015). The range of α is also comparable to that those observed in other global rivers (e.g., Amazon (Dellinger et al, 2015); Ganges (Bagard et al, 2015;Pogge von Strandmann et al, 2017)).…”

Section: Modelled Rayleigh Fractionation Factors and Water Residence supporting

confidence: 81%

Tracing silicate weathering processes in the permafrost-dominated Lena River watershed using lithium isotopes

Murphy

Porcelli

Strandmann

et al. 2019

Geochimica et Cosmochimica Acta

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“…A mass balance approach can potentially provide quantitative information on the biogeochemical processes that fractionate the tracer of interest (Georg et al, 2006a;Bouchez et al, 2013). However, the associated uncertainties are large due to poor constraints on elemental and isotopic fractionation factors, which can be highly dependent on mineralogy, climate, ecosystem dynamics, or other aspects of the studied watershed (e.g., Wimpenny et al, 2015;Frings et al, 2016). As a result, most isotope weathering studies to date have focused on empirically calibrating isotopic fractionation factors, rather than using the isotopic information to assess the underlying biogeochemical processes (e.g., Hughes et al, 2013;Baronas et al, 2017a).…”

Section: Introductionmentioning

confidence: 99%

Ge and Si isotope signatures in rivers: A quantitative multi-proxy approach

Baronas

Torres

West

et al. 2018

Earth and Planetary Science Letters

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Solutes derived from the dissolution of silicate minerals play a key role in Earth's climate via the carbon and other biogeochemical cycles. Silicon (Si) is a unique constituent of silicate minerals and a biologically important nutrient, so tracing its behavior in near-surface environments may provide important insights into weathering processes. However, Si released by weathering is variably incorporated into secondary mineral phases and biota, obscuring signals derived from primary weathering processes. Due to chemical similarities, Germanium (Ge) may help better understand the Si cycle and its relationship to chemical weathering. With this aim, we report new measurements of the concentration and isotopic composition of Ge for both the dissolved and particulate phases of a variety of global rivers. These measurements are combined with analyses of concentration and isotopic ratio of Si on the exact same sample set in order to make direct comparisons of the behavior of these two elements in natural river systems. With this dataset, we develop a new modeling framework describing the full elemental and isotopic systems of these solutes in rivers (i.e., Ge/Si, δ74Ge, and δ30Si). This multi-proxy approach allows us to ascertain the relative importance of biological versus mineral uptake in modulating the fluxes of these elements delivered to the modern ocean. Dissolved δ74Ge composition of rivers studied thus far range from 0.9 to 5.5 ‰ with a discharge-weighted global average of 2.6±0.5 ‰. The Ge isotope composition of riverine suspended and bedload sediments is indistinguishable from silicate source rocks, which is consistent with mass balance expectations. The multi-proxy modeling suggests that, among the watersheds studied here, the isotopic fractionation of Si during secondary mineral phase precipitation (∆30Sisec) ranges from-2.7 to-0.2 ‰, which removes between 19-79% of the initial dissolved Si sequestration, while between 12-54% is incorporated by biota. For Ge, modeling indicates that 79-98% of the dissolved load is incorporated into secondary mineral phases with a ∆74Gesec ranging from-4.9 to-0.3 ‰. The fractionation induced by biological uptake is calculated to range from-2.6 to-1.3 ‰ for ∆30Sibio and-0.7±0.7 ‰ for ∆74Gebio. In addition to improving our understanding of the coupled Ge and Si cycles, our study provides a framework for Please note that this is an author-produced PDF of an article accepted for publication following peer review. The definitive publisher-authenticated version is available on the publisher Web site. using multiple isotopic tracers to elucidate the chemical behavior of solutes in natural waters Highlights ► Ge and Si isotope composition of water and sediments in various rivers is presented. ► Dissolved δ 74 Ge range 0.9-5.5‰, river sediment δ 74 Ge range 0.5-0.7‰. ► Dissolved δ 74 Ge is strongly fractionated due to low chemical Ge mobility. ► Ge/Si-isotope multi-proxy provides quantitative constraints on secondary vs biological fractionation.

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Lithium isotope fractionation during uptake by gibbsite

Cited by 74 publications

References 77 publications

Experimental determination of Li isotope behaviour during basalt weathering

Experimental determination of Li isotope behaviour during basalt weathering

Tracing silicate weathering processes in the permafrost-dominated Lena River watershed using lithium isotopes

Ge and Si isotope signatures in rivers: A quantitative multi-proxy approach

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