Li and U Isotopes as a Potential Tool for Monitoring Active Layer Deepening in Permafrost Dominated Catchments

Hindshaw, Ruth S.; Aciego, S.; Tipper, Edward T.

doi:10.3389/feart.2018.00102

Cited by 15 publications

(11 citation statements)

References 116 publications

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“…Long-term reproducibility for seawater (OSIL IAPSO batch P157) is 30.8±1.1 (2SD, n=45) in agreement with the compiled values of 31.1 (Carignan et al, 2004) and 30.8 (Rosner et al, 2007). We obtained a value of 4.9±1.9 (2SD, n = 10) for USGS shale rock standard SGR-1b (Hindshaw et al, 2018), in agreement with previously published values (Phan et al, 2016;Pogge von Strandmann et al, 2017b;Bohlin et al, 2018). The long-term external reproducibility of seawater is applied to the samples measured in this study (1.1 ), as this value is greater than the 2SD of individual sample measurements.…”

Section: Mg-rich Layer Silicate Synthesissupporting

confidence: 82%

Experimental constraints on Li isotope fractionation during clay formation

Hindshaw

Tosca

Goût

et al. 2019

Geochimica et Cosmochimica Acta

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125

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Knowledge of the lithium (Li) isotope fractionation factor during clay mineral formation is a key parameter for Earth system models. This study refines our understanding of isotope fractionation during clay formation with essential implications for the interpretation of field data and the global geochemical cycle of Li. We synthesised Mg-rich layer silicates (stevensite and saponite) at temperatures relevant for Earth surface processes. The resultant solids were characterised by X-ray diffraction (XRD) and Fourier-transform infrared spectroscopy (FT-IR) to confirm the mineralogy and crystallinity of the product. Bulk solid samples were treated with ammonium chloride to remove exchangeable Li in order to distinguish the Li isotopic fractionation between these sites and structural (octahedral) sites. Bulk solids, residual solids and exchangeable solutions were all enriched in 6 Li compared to the initial solution. On average, the exchangeable solutions had δ 7 Li values 7 lower than the initial solution. The average difference between the residue and initial solution δ 7 Li values (∆ 7 Li residue−solution) for the synthesised layer silicates was-16.6±1.7 at 20 • C, in agreement with modelling studies, extrapolations from high temperature experimental data and field observations. Three bonding environments were identified from 7 Li-NMR spectra which were present in both bulk and residual solid 7 Li-NMR spectra, implying that some exchangeable Li remains after treatment with ammonium chloride. The 7 Li-NMR peaks were assigned to octahedral, outer-sphere (interlayer and adsorbed) and pseudo-hexagonal (ditrigonal cavity) Li. By combining the 7 Li-NMR data with mass balance constraints we could calculate a fractionation factor, based on a Monte Carlo minimum misfit method, for each bonding environment. The calculated values are-21.5±1.1 ,-0.2±1.9 and 15.0±12.3 for the octahedral, outer-sphere and pseudo-hexagonal sites respectively (errors 1σ). The bulk fractionation factor (∆ 7 Li bulk−solution) is dependent on the chemistry of the initial solution. The higher the Na concentration in the initial solution the lower the bulk δ 7 Li value. We suggest this is due to Na outcompeting Li for interlayer sites and as interlayer Li has a high δ 7 Li value relative to octahedral Li, increased Na serves to lower the bulk δ 7 Li value. Three experiments conducted at higher pH exhibited lower δ 7 Li values in the residual solid. This could either be a kinetic effect, resulting from the higher reaction rate at high pH, or an equilibrium effect resulting from reduced Li incorporation in the residual solid and/or a change in Li speciation in solution. This study highlights the power of 7 Li-NMR in experimental studies of clay synthesis to target site specific Li isotope fractionation factors which can then be used to provide much needed constraints on field processes.

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Section: Mg-rich Layer Silicate Synthesissupporting

confidence: 82%

Experimental constraints on Li isotope fractionation during clay formation

Hindshaw

Tosca

Goût

et al. 2019

Geochimica et Cosmochimica Acta

Self Cite

125

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“…8.9 ± 0.4‰ (Magna et al, 2006)); SGR-1b: d 7 Li = 4.00 ± 0.24‰ (e.g. 4.7 ± 0.7‰ (Phan et al, 2016); 3.6 ± 0.4‰ (Pogge von Strandmann et al, 2017b); 4.9 ± 1.9‰ (Hindshaw et al, 2018)). Hence, our standard results show that our Li isotope analyses are accurate, and have a long-term external precision (for the twelve months the new laboratory has been operational) of better than ±0.4‰ (2sd).…”

Section: Isotope Analysesmentioning

confidence: 95%

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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“…There is no apparent influence by vegetation, as both glacial and vegetated terrains cover the entire range of observed δ 26 Mg. Uranium activity ratios are controlled by the ratio of physical erosion to mineral dissolution (Henderson, 2002;Chabaux et al, 2003;Robinson et al, 2004;Pogge von Strandmann et al, 2006, 2011aAndersen et al, 2009;Hindshaw et al, 2018). Relatively high physical erosion rates increase mineral surface area, promoting both recoil of 234 U and the leaching of 234 U from recoil-damaged lattice sites, and driving riverine ( 234 U/ 238 U) to high values (Figure 3E).…”

Section: Riverine Magnesiummentioning

confidence: 99%

The Response of Magnesium, Silicon, and Calcium Isotopes to Rapidly Uplifting and Weathering Terrains: South Island, New Zealand

et al. 2019

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Silicate weathering is a dominant control on the natural carbon cycle. The supply of rock (e.g., via mountain uplift) has been proposed as a key weathering control, and suggested as the primary cause of Cenozoic cooling. However, this is ambiguous because of a lack of definitive weathering tracers. We use the isotopes of the major cations directly involved in the silicate weathering cycle: magnesium, silicon and calcium. Here we examine these isotope systems in rivers draining catchments with variable uplift rates (used as a proxy for exposure rates) from South Island, New Zealand. Overall, there is no trend between these isotope systems and uplift rates, which is in contrast to those of trace elements like lithium or uranium. Li and Si isotopes co-vary, but only in rapidly uplifting mountainous terrains with little vegetation. In floodplains, in contrast, vegetation further fractionates Si isotopes, decoupling the two tracers. In contrast, Mg and Ca isotopes (which are significantly affected by the weathering of both carbonates and silicates) exhibit no co-variation with each other, or any other weathering proxy. This suggests that lithology, secondary mineral formation and vegetation growth are causing variable fractionation, and decoupling the tracers from each other. Hence, in this context, the isotope ratios of the major cations are significantly less useful as weathering tracers than those of trace elements, which tend to have fewer fractionating processes.

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Li and U Isotopes as a Potential Tool for Monitoring Active Layer Deepening in Permafrost Dominated Catchments

Cited by 15 publications

References 116 publications

Experimental constraints on Li isotope fractionation during clay formation

Experimental constraints on Li isotope fractionation during clay formation

Experimental determination of Li isotope behaviour during basalt weathering

The Response of Magnesium, Silicon, and Calcium Isotopes to Rapidly Uplifting and Weathering Terrains: South Island, New Zealand

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