Grain size effects on excess Thorium-230 of sediment cores from the Southern Ocean and the South East Atlantic
Cobertura |
MEDIAN LATITUDE: -38.952176 * MEDIAN LONGITUDE: 6.416640 * SOUTH-BOUND LATITUDE: -52.612500 * WEST-BOUND LONGITUDE: 4.458000 * NORTH-BOUND LATITUDE: -19.655750 * EAST-BOUND LONGITUDE: 9.177667 * DATE/TIME START: 1988-03-01T00:00:00 * DATE/TIME END: 1989-11-11T23:49:00 |
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Data(s) |
19/11/2010
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Resumo |
Excess Thorium-230 (230Thxs) as a constant flux tracer is an essential tool for paleoceanographic studies, but its limitations for flux normalization are still a matter of debate. In regions of rapid sediment accumulation, it has been an open question if 230Thxs-normalized fluxes are biased by particle sorting effects during sediment redistribution. In order to study the sorting effect of sediment transport on 230Thxs, we analyzed the specific activity of 230Thxs in different particle size classes of carbonate-rich sediments from the South East Atlantic, and of opal-rich sediments from the Atlantic sector of the Southern Ocean. At both sites, we compare the 230Thxs distribution in neighboring high vs. low accumulation settings. Two grain-size fractionation methods are explored. We find that the 230Thxs distribution is strongly grain size dependent, and 50-90% of the total 230Thxs inventory is concentrated in fine material smaller than 10 µm, which is preferentially deposited at the high accumulation sites. This leads to an overestimation of the focusing factor Psi, and consequently to an underestimation of the vertical flux rate at such sites. The distribution of authigenic uranium indicates that fine organic-rich material has also been re-deposited from lateral sources. If the particle sorting effect is considered in the flux calculations, it reduces the estimated extent of sediment focusing. In order to assess the maximum effect of particle sorting on Psi, we present an extreme scenario, in which we assume a lateral sediment supply of only fine material (< 10 µm). In this case, the focusing factor of the opal-rich core would be reduced from Psi = 5.9 to Psi = 3.2. In a more likely scenario, allowing silt-sized material to be transported, Psi is reduced from 5.9 to 5.0 if particle sorting is taken into consideration. The bias introduced by particle sorting is most important for strongly focused sediments. Comparing 230Thxs-normalized mass fluxes biased by sorting effects with uncorrected mass fluxes, we suggest that 230Thxs-normalization is still a valid tool to correct for lateral sediment redistribution. However, differences in focusing factors between core locations have to be evaluated carefully, taking the grain size distributions into consideration. |
Formato |
application/zip, 6 datasets |
Identificador |
https://doi.pangaea.de/10.1594/PANGAEA.753876 doi:10.1594/PANGAEA.753876 |
Idioma(s) |
en |
Publicador |
PANGAEA |
Relação |
Kretschmer, Sven (2010): The Influence of particle size, composition, and transport on the distribution of 230Thxs, 231Paxs, and 10Be in marine sediment. PhD Thesis, Elektronische Dissertationen an der Staats- und Universitätsbibliothek Bremen, Germany, 134 pp, urn:nbn:de:gbv:46-00101745-16 |
Direitos |
CC-BY: Creative Commons Attribution 3.0 Unported Access constraints: unrestricted |
Fonte |
Supplement to: Kretschmer, Sven; Geibert, Walter; Rutgers van der Loeff, Michiel M; Mollenhauer, Gesine (2010): Grain size effects on Th-230 (xs) inventories in opal-rich and carbonate-rich marine sediments. Earth and Planetary Science Letters, 294(1-2), 131-142, doi:10.1016/j.epsl.2010.03.021 |
Palavras-Chave | #+/- 2 sigma; 230Th; 230Th std dev; 230Th xs; 230Th xs std dev; 232Th; 232Th std dev; 234U; 234U/238U; 234U/238U std dev; 234U std dev; 235U; 235U std dev; 238U; 238U aut; 238U aut/238U tot; 238U aut std dev; 238U std dev; 2 sigma; Age; AGE; Al; Al std dev; Aluminium; Aluminium, standard deviation; ANT-VIII/3; biogenic opal; bSiO2; Ca; CaCO3; Caesium; Caesium, standard deviation; Calcium; Calcium, standard deviation; Calcium carbonate; Calculated, see reference(s); Carbon, organic, total; Ca std dev; Center for Marine Environmental Sciences; Comment; Cs; Cs std dev; DBD; Density, dry bulk; Depth; Depth, bottom/max; DEPTH, sediment/rock; Depth, top/min; Depth bot; Depth top; Event; Fe; Fe std dev; Fraction; fractionation method; GeoB1027-2; GeoB1028-4; Giant box corer; GKG; Grain size, mean; Grain size, sieving/settling tube; Gravity corer (Kiel type); gs mean; ICP-SF-MS, Thermo Scientific, Element 2; Iron; Iron, standard deviation; K; K std dev; Lithology; Lithology/composition/facies; Loss; M6/6; Magnesium; Magnesium, standard deviation; Manganese; Manganese, standard deviation; MARUM; Meteor (1986); Method; Method comment; Mg; Mg std dev; Mn; Mn std dev; Opal, auto analysis (Müller & Schneider, 1993); Opal, biogenic silica; Particle composition (minor components are in parantheses); particle size class [µm]; Polarstern; Potassium; Potassium, standard deviation; PS16; PS16/311; PS16/312; PS1768-8; PS1769-1; Rb; Rb std dev; Rec; Recovery; Rubidium; Rubidium, standard deviation; Sediment after fractionation; Shona Ridge; Size fraction; SL; Specific surface area; SSA; Thorium 230; Thorium 230, standard deviation; Thorium 230 excess; Thorium 230 excess, standard deviation; Thorium 232; Thorium 232, standard deviation; TOC; Uranium 234; Uranium 234, standard deviation; Uranium 234/Uranium 238 activity ratio; Uranium 234/Uranium 238 activity ratio, standard deviation; Uranium 235; Uranium 235, standard deviation; Uranium 238; Uranium 238, authigenic; Uranium 238, authigenic, standard deviation; Uranium 238, authigenic/Uranium 238, total ratio; Uranium 238, standard deviation; Velocity, settling, comment; Visual description; V settl; Walvis Ridge |
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