S. Heussner et al., Spatial and temporal patterns of downward particle fluxes on the continental slope of the Bay of Biscay (northeastern Atlantic), DEEP-SEA II, 46(10), 1999, pp. 2101-2146
Citations number
76
Categorie Soggetti
Aquatic Sciences","Earth Sciences
Journal title
DEEP-SEA RESEARCH PART II-TOPICAL STUDIES IN OCEANOGRAPHY
An array of six time series sediment traps and current meters was deployed
in water depths of 2300 and 3000 m on two bottom-mounted moorings along the
axis of the Cap-Ferret Canyon, a large depression in the southeastern part
of the Bay of Biscay (northeastern Atlantic), as part of the ECOMARGE Atla
ntic experiment ECOFER. The 14-month experiment consisted of three successi
ve deployments during which particle fluxes were collected over sampling pe
riods of 16-27 d. Two large-aperture traps also were deployed to measure fl
uxes at a faster sampling rate (4-7 d), The recovered samples were analyzed
for total mass, concentration of major constituents (organic and inorganic
carbon, opal), activity of Pb-210 (Radakovitch, O., Heussner, S., 1999. Fl
uxes and budget of Pb-210 On the continental margin of the Bay of Biscay (n
ortheastern Atlantic). Deep-Sea Research II 46, 2175-2203) and coccoliths (
Beaufort, L., Heussner, S., 1999. Coccolithophorids on the continental slop
e of the Bay of Biscay - production, transport and contribution to mass flu
xes. Deep-Sea Research II 46, 2147-2174). The temporal pattern of the major
constituent fluxes essentially matched that of the total mass, suggesting
that, in general, particle transfer to the slope is largely driven by event
s acting on the same time scale. The temporal variability of the measured c
oncentrations and fluxes lacked in any obvious connection with large-scale
driving forces, either external(wind, river discharge) or internal (biologi
cal production), which all exhibited a marked seasonal signal. The rapid ch
anges of particle transfer, largely non-seasonal, is in contrast with most
other ocean margin trap experiments. On the other hand, indications were fo
und that the variability of mass fluxes could be controlled by the along-sl
ope current, and particularly by its short-term fluctuations. These dynamic
al processes could be responsible for significant changes in the dispersion
of the settling particles and hence of the resultant flux changes. The spa
tial distribution of annual mean fluxes - from 498 (380 m) to 1477 mg m(-2)
d(-1) (2250 m) at the shallower site, and from 328 (1900 m) to 459 mg m(-2
) d(-1) (2950 m) at the deeper site - exhibited a linear increase with incr
easing depth and a seaward decrease at equivalent depth or distance from th
e bottom. Such a distribution, typical of continental slope environments, r
equires inputs of material through lateral advection. The increased homogen
eity of the bulk chemical composition of settling particles with increasing
water depth and total mass flux indicates that such inputs are largely pro
vided by resuspended material with quite constant characteristics, largely
originating from the Bay of Biscay's shelf and upper slope. Due to the gene
ral northward, along-slope current, the sources are preferentially located
south of the Cap-Ferret Canyon. A particle transfer scenario for this regio
n is proposed that, in particular, calls for a basic mechanism of upstream-
downstream concentration gradients in the sources of settling particles to
explain the increase in flux with depth. (C) 1999 Elsevier Science Ltd. All
rights reserved.