Biogeosciences Plankton in the open Mediterranean Sea: a review
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1550 I. Siokou-Frangou et al.: Mediterranean plankton Fig. 7. The top panel shows the deepening of the DCM (Z Chl Max) and the chl a dispersion (Chl Dispersion) as an average of the discrete depth difference from water column average of chl a concentration, in percentage. Dispersion values in the WMS are closer to 100% than in the EMS, demonstrating a higher vertical patchiness in the latter. The bottom panel represents the west to east decrease for calculated chl a in pico-, nano- and microplankton. Note the Longitude scale: the two data points to the left are outside the MS, while the Levantine basin was not sampled. Modified with permission from Dolan et al. (2002). 80
Max) and the chl a dispersion (Chl Dispersion) as an average of the discrete depth difference from water column average of chl a concentration, in percentage. Dispersion values in the WMS are closer to 100% than in the EMS, demonstrating a higher vertical patchiness in the latter. The bottom panel represents the west to east decrease for calculated chl a in pico-, nano- and microplankton. Note the Longitude scale: the two data points to the left are outside the MS, while the Levantine basin was not sampled. Modified with permission from Dolan et al. (2002). the exception of the short period of late winter mixing. The DCM progressively sinks across a west to east gradient from 30 m in the westernmost area (Dolan et al., 2002, Fig. 7), to 70 m in the South Adriatic Sea (Boldrin et al., 2002), down to 120 m in the Levantine basin (Christaki et al., 2001; Dolan et al., 2002). The eastward increase in DCM depth is prob- ably related to lower productivity and hence higher seawater transparency in the Levantine Sea, but the level of DCM may vary considerably between cyclonic and anticyclonic areas (Ediger and Yilmaz, 1996). In the westerm MS, the depth of the DCM is strongly affected by the Atlantic water inflow and the consequent physical dynamics along the vertical axis (Raimbault et al., 1993). The distribution of biomass is clearly reflected in pri- mary production rates (Table 1). Satellite-based estimates range from 130 to 198 g C m − 2
− 1 over the years 1997– 2001 (Bricaud et al., 2002; Bosc et al., 2004), with values for the EMS generally in the lower portion of the range. Es- timates from in situ incubations in previous decades were as low as 80–90 g C m − 2
− 1 (Sournia, 1973). More recent measurements get closer to satellite-based estimates, e.g., in the Gulf of Lion (140–150 g C m − 2
− 1 , Conan et al., 1998), but remain consistently lower in other areas such as the Cre- tan Sea (59 g C m − 2
− 1 , Psarra et al., 2000). A clear east- ward reduction in primary production was reported in the Fig. 8. Integrated primary production (mg C m − 2 day − 1 ) during the MINOS cruise (May-June 1996). Repro- duced with permission from Moutin and Raimbault (2002). 81
− 2 day − 1 ) during the MINOS cruise (May–June 1996). Reproduced with permission from Moutin and Raimbault (2002). results from a late-spring (May–June) trans-Mediterranean cruise (Moutin and Raimbault, 2002), when maxima were close to 1 g C m − 2
− 1 in the south-western basin and min- ima ranged between 150 and 250 mg C m − 2 d − 1 at several stations of the Levantine Sea (Fig. 8). Interestingly, estimates obtained in spring in other studies reflect the same spatial pattern and are within the same ranges as those shown by Moutin and Raimbault (2002) (Table 1). Comparably high values (up to 1.7 g C m − 2
− 1 ) were reported in the Catalan front area in March (Moran and Estrada, 2005), and in the Alboran Sea in May–June (Lohrenz et al., 1988). At the DY- FAMED station in the Ligurian Sea, primary production rates were 240–716 mg C m − 2
et al., 2001) but reached values as high as 1.8 g C m − 2 d − 1 in April (Marty and Chiaverini, 2002). Measurements at other sites of the EMS, namely in the South Adriatic Sea (Boldrin et al., 2002) and in the North East Aegean Sea (Ignatiades et al., 2002; Zervoudaki et al., 2007), also match the low val- ues recorded by Moutin and Raimbault (2002). Spatial and seasonal variability of primary production val- ues can be high (Table 1), especially in very dynamic ar- eas like the Alboran Sea (Mac´ıas et al., 2009) and the Catalan Sea (Granata et al., 2004). Inter-annual variability of primary production may also be high, mainly depend- ing on the depth of the winter mixing (Estrada, 1996). In spite of light limitation, the contribution of subsurface and deep chlorophyll maxima can be significant, in some cases reaching 30% of the total production of the water column (Estrada et al., 1985). While satellite-based estimates represent gross primary production, values from in situ incubations are generally closer to net production. In neither case, however, is an estimate of the new versus recycled production provided, and it is hence impossible to appreciate the actual amount of biomass added to the system through phytoplankton ac- tivity. Indeed, values for new production, which can be equated to the export production assuming a quasi-steady state, are much lower, i.e. in the order of 4.5 mol C m − 2
− 1 (1mol C≡12g C) and 1.5 mol C m − 2 y − 1 for the WMS and EMS, respectively (e.g. Bethoux, 1989, but see also Minas et al., 1988 for a discussion). These estimates correspond Biogeosciences, 7, 1543–1586, 2010 www.biogeosciences.net/7/1543/2010/ Yüklə 0,96 Mb. Dostları ilə paylaş:
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