Turnewitsch, Robert; Witte, Ursula; Graf, Gerhard (2000): Lead 210 concentrations in sediments of the Arabian Sea. PANGAEA, https://doi.org/10.1594/PANGAEA.735221, Supplement to: Turnewitsch, R et al. (2000): Bioturbation in the abyssal Arabian Sea: influence of fauna and food supply. Deep Sea Research Part II: Topical Studies in Oceanography, 47(14), 2877-2911, https://doi.org/10.1016/S0967-0645(00)00052-7
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In order to evaluate bioturbation in abyssal Arabian-Sea sediments of the Indus fan profiles of 210Pb (half-life: 22.3 yr) and 234Th (half-life: 24.1 d) were measured in cores collected during September and October 1995 and April 1997, respectively. The density and composition of epibenthic megafauna and lebensspuren were determined in vertical seafloor photographs during April 1997. Mean eddy-diffusive mixing coefficients according to the distribution of excess 210Pb ( 210Pb-DB) were 0.072±0.028, 0.068±0.055, 0.373±0.119, 0.037±0.009 and 0.079±0.119 cm**2 yr**-1 in the northern, western, central, eastern and southern abyssal Arabian sea, respectively. Mean eddy-diffusive mixing coefficients according to the distribution of excess 234Th (234Th-DB) were 0.53, 1.64 and 0.47 cm**2 yr**-1 in the northern, western and central abyssal Arabian Sea, respectively. Mobile epibenthic megafauna at the western, northern, central and southern study sites were dominated by ophiuroids, holothurians, ophiuroids and natant decapods (the respective densities were 100, 82, 29 and 6 individuals 1000 m**-2). The northern study site was characterized by a high abundance of spoke traces and fecal casts. The central site showed spoke traces and many tracks. The southern site displayed the highest abundance of spoke traces, whereas at the western site hardly any lebensspuren were observed. There is evidence for at least two functional endmember communities in the Arabian Sea. In the northwestern Arabian Sea (WAST) vertical particle displacement seems to be dominated by macrofauna and primarily eddy-diffusive. In the southern Arabian Sea (SAST) non-local and 'incidental' mixing due to spoke-trace producers might become more important and superimpose reduced eddy-diffusive mixing. With respect to biological data CAST is an intermediate location. Given the biological data, average 210Pb-DB is higher and decimeter-scale variability of 210Pb-DB smaller at CAST than expected. These findings indicate that in a mixture of both endmember communities the organisms may interact in way that increases values of biodiffusivity, as reflected by 210Pb-DB, and reduces decimeter-scale 210Pb-DB heterogeneity in comparison to the simple sum of the isolated effects of the endmembers. For time scales <100 years there was no evidence for a relationship between food supply (POC flux) and bioturbation intensity, as reflected by 210Pb-DB and 234Th-DB. Bioturbation intensity should be controlled primarily by the composition of the benthic fauna, its specific adaptation to the environmental setting, and the abundance of each species of the benthic community. Food supply can have only an indirect influence on bioturbation intensity. In certain parts of the ocean the a priori overall positive relationship between POC flux and biodiffusivity might include restricted intervals displaying no or even negative relations.
Median Latitude: 15.270496 * Median Longitude: 64.845696 * South-bound Latitude: 10.051660 * West-bound Longitude: 60.516330 * North-bound Latitude: 19.999660 * East-bound Longitude: 68.516660
Date/Time Start: 1995-09-24T23:05:00 * Date/Time End: 1995-10-20T21:54:00
M33/1_MC-03 (581, NAST) * Latitude: 19.999660 * Longitude: 65.584160 * Date/Time: 1995-09-24T23:05:00 * Elevation: -3183.0 m * Campaign: M33/1 * Basis: Meteor (1986) * Method/Device: MultiCorer (MUC)
M33/1_MC-09 (605, WAST) * Latitude: 16.250500 * Longitude: 60.516330 * Date/Time: 1995-10-01T16:45:00 * Elevation: -4028.0 m * Location: Northern Arabian Sediment Trap * Campaign: M33/1 * Basis: Meteor (1986) * Method/Device: MultiCorer (MUC)
Datasets listed in this publication series
- Turnewitsch, R; Witte, U; Graf, G (2000): (Fig. 2) Lead 210 in sediment core M33/1_MC-03. https://doi.org/10.1594/PANGAEA.58801
- Turnewitsch, R; Witte, U; Graf, G (2000): (Fig. 2) Lead 210 in sediment core M33/1_MC-09. https://doi.org/10.1594/PANGAEA.58802
- Turnewitsch, R; Witte, U; Graf, G (2000): (Fig. 2) Lead 210 in sediment core M33/1_MC-21. https://doi.org/10.1594/PANGAEA.58803
- Turnewitsch, R; Witte, U; Graf, G (2000): (Fig. 2) Lead 210 in sediment core M33/1_MC-33. https://doi.org/10.1594/PANGAEA.58805
- Turnewitsch, R; Witte, U; Graf, G (2000): (Fig. 2) Lead 210 insediment core M33/1_MC-23. https://doi.org/10.1594/PANGAEA.58804