Lithium isotope behaviour during weathering in the Ganges Alluvial Plain

Strandmann, Philip A.E. Pogge von; Frings, Patrick J.; Murphy, Melissa J.

doi:10.1016/j.gca.2016.11.017

Cited by 81 publications

(91 citation statements)

References 96 publications

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“…The Li isotopic composition of the Lena River main channel is relatively uniform throughout the catchment (~19 ± 2‰; 1σ), and is several permil lower than the global riverine mean of ~23‰ (Huh et al, 1998a), with the exception of one atypical sample with high [Li] and δ 7 Li (LR2013-41; δ 7 Li = 29.0‰, 396 nM). The ranges of δ 7 Li and [Li] measured in this study are similar to those of data from other large global rivers systems elsewhere (e.g., the Mackenzie River, Millot et al, 2010; the Ganges-Brahmaputra, Kısakűrek et al, 2005, Bagard et al, 2015, Pogge von Strandmann et al, 2017 and the Amazon, Dellinger et al, 2015).…”

Section: Dissolved δsupporting

confidence: 81%

“…Thus, the δ 7 Li data have not been corrected for these inputs, consistent with the approaches of other riverine studies (e.g. Millot et al, 2010;Bagard et al, 2015;Liu et al, 2015;Pogge von Strandmann et al, 2017).…”

Section: Sources Of Dissolved Lithiummentioning

confidence: 65%

“…2), which broadly overlaps with average continental silicate rock values (UCC, ~ 0.6 ± 0.6‰, Teng et al, 2004;Sauzéat et al, 2015;andbasalts ~3 to 5‰, Elliott et al, 2006, Tomascak et al, 2008). The suspended sediments are isotopically heavier than the global mean suspended sediment Li isotopic composition for large global rivers of -1.5 ± 1‰ (1σ; Dellinger et al, 2014) but comparable to δ 7 Lisusp values for other rivers (e.g., the Mackenzie River, Millot et al 2010; the Ganges-Brahmaputra; Kısakűrek et al 2005, Bagard et al 2015, Pogge von Strandmann et al 2017the Dongqu, Weynell et al, 2017); and the Amazon, Dellinger et al, 2014). Variations in d 7 Li have been reported for suspended sediments related to variations in Si/Al (a proxy for grain size) in depth profiles in the Amazon, Mackenzie and Ganges-Brahmaputra Rivers that are the result mineral sorting within the water column (Bouchez et al 2011, Dellinger et al 2014, Dellinger et al 2017).…”

Section: Dissolved δmentioning

confidence: 72%

“…High riverine d 7 Li values have been interpreted as reflecting less complete weathering, greater secondary mineral formation and thus greater 'weathering intensity' (i.e., the ratio of chemical to physical denudation; Bouchez et al, 2013;Dellinger et al, 2015). There have been a number of large global rivers in tropical and temperate environments where the behaviour of Li isotopes has been studied: e.g., the Amazon River (Chan et al, 1992;Huh et al, 1998a;Dellinger et al, 2014Dellinger et al, , 2015; the Orinoco River (Huh et al, 1998a;Huh et al, 2001); rivers in the high Himalayas and the Ganges-Brahmaputra (Huh et al, 1998a;Kısakűrek et al, 2005;Bagard et al, 2015;Manaka et al, 2017;Pogge von Strandmann et al, 2017) the Changjiang (Yangtzee)…”

Section: Introductionmentioning

confidence: 99%

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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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Section: Dissolved δsupporting

confidence: 81%

Section: Sources Of Dissolved Lithiummentioning

confidence: 65%

Section: Dissolved δmentioning

confidence: 72%

Section: Introductionmentioning

confidence: 99%

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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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“…This is expected, given that both plant (or algal) growth and clay formation are significantly greater on the east coast. In other words, the enhanced dissolution of primary silicates in mountainous regions causes a correlation of Li and Si isotopes (also observed in the Himalayan foothills; Pogge von Strandmann et al, 2017). This co-relationship between the two systems can be modeled using a Rayleigh relationship (Vigier et al, 2009;Pogge von Strandmann et al, 2012, 2014b, 2017Murphy et al, 2019), and by assuming a continental crust starting composition (Savage et al, 2010;Sauzéat et al, 2015).…”

Section: Riverine Siliconmentioning

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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Enrichment of dissolved silica in the deep equatorial Pacific during the Eocene‐Oligocene

et al. 2017

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Silicon isotope ratios (expressed as δ30Si) in marine microfossils can provide insights into silica cycling over geologic time. Here we used δ30Si of sponge spicules and radiolarian tests from the Paleogene Equatorial Transect (Ocean Drilling Program Leg 199) spanning the Eocene and Oligocene (~50–23 Ma) to reconstruct dissolved silica (DSi) concentrations in deep waters and to examine upper ocean δ30Si. The δ30Si values range from −3.16 to +0.18‰ and from −0.07 to +1.42‰ for the sponge and radiolarian records, respectively. Both records show a transition toward lower δ30Si values around 37 Ma. The shift in radiolarian δ30Si is interpreted as a consequence of changes in the δ30Si of source DSi to the region. The decrease in sponge δ30Si is interpreted as a transition from low DSi concentrations to higher DSi concentrations, most likely related to the shift toward a solely Southern Ocean source of deep water in the Pacific during the Paleogene that has been suggested by results from paleoceanographic tracers such as neodymium and carbon isotopes. Sponge δ30Si provides relatively direct information about the nutrient content of deep water and is a useful complement to other tracers of deep water circulation in the oceans of the past.

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Lithium isotope behaviour during weathering in the Ganges Alluvial Plain

Cited by 81 publications

References 96 publications

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

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

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

Enrichment of dissolved silica in the deep equatorial Pacific during the Eocene‐Oligocene

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