Thorium speciation in seawater

Santschi, Peter H.; Murray, James; Baskaran, M.; Benitez-Nelson, Claudia R.; Guo, Laodong; Hung, Chin‐Chang; Lamborg, Carl H.; Moran, S. Bradley; Passow, Uta; Roy‐Barman, Matthieu

doi:10.1016/j.marchem.2005.10.024

Cited by 153 publications

(84 citation statements)

References 126 publications

(186 reference statements)

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“…Consequently, the MnO 2 adsorbers carry a net negative charge at seawater pH. In seawater, Th appears to be complexed by organic compounds, such as humic acids and acidic polysaccharides, and incorporated into submicron colloids, which also carry a net negative charge (see Santschi et al 2005). Hence, repulsion between these Th complexes and the MnO 2 surface may occur, thereby reducing collection efficiency.…”

Section: Adsorption On Mno 2 Impregnated Cartridgesmentioning

confidence: 99%

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A review of present techniques and methodological advances in analyzing 234Th in aquatic systems

et al. 2006

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The short-lived thorium isotope 234 Th (half-life 24.1 days) has been used as a tracer for a variety of transport processes in aquatic systems. Its use as a tracer of oceanic export via sinking particles has stimulated a rapidly increasing number of studies that require analyses of 234 Th in both marine and freshwater systems. The original 234 Th method is labour intensive.Thus, there has been a quest for simpler techniques that require smaller sample volumes.Here, we review current methodologies in the collection and analysis of 234 Th from the water column, discuss their individual strengths and weaknesses, and provide an outlook on possible further improvements and future challenges. Also included in this review are recommendations on calibration procedures and the production of standard reference materials as well as a flow chart designed to help researchers find the most appropriate 234 Th analytical technique for a specific aquatic regime and known sampling constraints.

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Section: Adsorption On Mno 2 Impregnated Cartridgesmentioning

confidence: 99%

“…Details of 234 Th speciation, modelling, conversion of 234 Th flux into the flux of carbon and other elements, and fields of expected future applications of 234 Th can be found in companion papers of Santschi et al (2005), Savoye et al (2005), Buesseler et al (2005), and Waples et al (2005), respectively, in this issue.…”

Section: Introductionmentioning

confidence: 99%

A review of present techniques and methodological advances in analyzing 234Th in aquatic systems

et al. 2006

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“…To determine 230 Th production, 234 U concentrations are estimated using measured salinity and published estimates of the salinity-U relationship in North Pacific seawater (Chen et al, 1986) and the seawater 234 U/ 238 U ratio (Andersen et al, 2010). More than 99.8% of Th in seawater, however, is 232 Th, a primordial isotope added to seawater in the dissolved pool through the partial dissolution of lithogenic materials (Santschi et al, 2006). Thorium (and therefore all Th isotopes) is highly insoluble in seawater and is rapidly removed from solution by scavenging onto particulate matter (Moore and Sackett, 1964).…”

Section: Introductionmentioning

confidence: 99%

Quantifying lithogenic inputs to the North Pacific Ocean using the long-lived thorium isotopes

Hayes

Anderson

Fleisher

et al. 2013

Earth and Planetary Science Letters

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Dissolved 232 Th is added to the ocean though the partial dissolution of lithogenic materials such as aerosol dust in the same way as other lithogenically sourced and more biologically important trace metals such as Fe. Oceanic 230 Th, on the other hand, is sourced primarily from the highly predictable decay of dissolved 234 U. The rate at which dissolved 232 Th is released by mineral dissolution can be constrained by a Th removal rate derived from 230 Th: 234 U disequilibria, assuming steady-state. Calculated fluxes of dissolved 232 Th can in turn be used to estimate fluxes of other lithogenically sourced dissolved metals as well as the original lithogenic supplies, such as aerosol dust deposition, given the concentration and fractional solubility of Th (or other metals) in the lithogenic material. This method is applied to 7 water column profiles from the Innovative North Pacific Experiment (INOPEX) cruise of 2009 and 2 sites from the subtropical North Pacific. The structure of shallow depth profiles suggests rapid scavenging at the surface and at least partial regeneration of dissolved 232 Th at 100-200 m depth. This rapid cycling could involve colloidal Th generated during mineral dissolution, which may not be subject to the same removal rates as the more truly dissolved 230 Th. An additional deep source of 232 Th was revealed in deep waters, most likely dissolution of seafloor sediments, and offers a constraint on dissolved trace element supply due to boundary exchange.

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“…By contrast, the POC fluxes we report (4.5 ± 3.9 mmol m -2 d -1 ) are on average three times lower than fluxes from other studies (12.6 ± 13.3 mmol m -2 d -1 ) due to lower POC: 234 Th ratios measured in >51 µm particles. In general, POC: 234 Th ratios can vary widely as a function of season, ecosystem composition, size-fraction, depth, and particle sampling methodology (Coppola et al, 2005;Buesseler et al, 2006;Santschi et al, 2006;Jacquet et al, 2011). In GB1 and GB2, an ecosystem effect likely accounts for the 14-fold difference in POC: 234 Th between oligotrophic waters (e.g, 0.8 µmol dpm -1 at GB2-106) and polar waters (e.g., 10.8 µmol dpm -1 at GB1-85) ( Table 3).…”

Section: Choice Of Export Depthmentioning

confidence: 99%

Novel analytical strategies for tracing the organic carbon cycle in marine and riverine particles

Rosengard¹

2017

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Particulate organic carbon (POC) in the ocean and mobilized by rivers on land transfers ~0.1% of global primary productivity to the deep ocean sediments. This small fraction regulates the long-term carbon cycle by removing carbon dioxide from the atmosphere for centuries to millennia. This thesis investigates mechanisms of POC transfer to the deep ocean by analyzing particles collected in transit through two globally significant carbon reservoirs: the Southern Ocean and the Amazon River Basin. These endeavors test the hypothesis that organic matter composition controls the recycling and transfer efficiency of POC to the deep ocean, and illustrate new applications for ramped pyrolysis/oxidation (RPO), a growing method of POC characterization by thermal stability. By coupling RPO to stable and radiocarbon isotope analyses of riverine POC, I quantify three thermally distinct soil organic carbon pools mobilized by the Amazon River, and evaluate the degradability and fate of these different pools during transport to the coastal Atlantic Ocean. More directly, RPO analyses of marine samples suggest that POC transfer in the water column is in fact selective. Observations of consistent biomolecular changes that accompany transport of phytoplankton-derived organic matter to depth across the Southern Ocean support the argument for preferential degradation of specific POC pools in the water column. Combining discussions of POC recycling and transfer across both marine and terrestrial systems offer new perspectives of thermal stability as a proxy for diagenetic stability and POC degradation state. The challenges of interpreting RPO data in these two environments set the stage for applying the technique to more controlled experiments that trace POC from source to long-term sink.

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Thorium speciation in seawater

Cited by 153 publications

References 126 publications

A review of present techniques and methodological advances in analyzing 234Th in aquatic systems

A review of present techniques and methodological advances in analyzing 234Th in aquatic systems

Quantifying lithogenic inputs to the North Pacific Ocean using the long-lived thorium isotopes

Novel analytical strategies for tracing the organic carbon cycle in marine and riverine particles

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