G. Moncoiffe et al., Seasonal and short-time-scale dynamics of microplankton community production and respiration in an inshore upwelling system, MAR ECOL-PR, 196, 2000, pp. 111-126
An intensive study of pelagic primary production and microplankton communit
y respiration was carried out during an entire upwelling season in the Ria
de Vigo (NW Spain). From April to November measurements of oxygen productio
n and respiration using the light-dark bottle technique were made twice a w
eek at the surface, 1% light depth (1% LD, 12 +/- 4 m) and 40 m (8 m above
sea floor) alongside routine physical, chemical and biological measurements
. During the major part of the survey period intermittent intrusions of col
d, nutrient-rich upwelled water were observed in the ria with a periodicity
of about 2 wk. Rates of gross primary production (GPP) were high but varia
ble averaging 37.3 +/- 30.7 mu M O-2 d(-1) and 3.6 +/- 4.8 mu M O-2 d(-1) a
t the surface and 1% LD respectively over the period of survey (n = 50). Ra
tes of dark community respiration (DCR) were also high and variable with ma
ximum values being observed in the surface layer where the seasonal average
was 12.2 +/- 9.8 mu M O-2 d(-1). At the 1% LD and 40 m, DCR averaged 5.3 /- 4.4 and 2.8 +/- 3.0 mu M O-2 d(-1) respectively. Although seasonal avera
ge and maximal DCR (up to 46.5 mu M O-2 d(-1)) were among the highest repor
ted for coastal areas, microplankton production over the period of survey w
as dominated by autotrophic processes. Respiration losses by the microplank
ton community in the euphotic zone represented on average 43 % of estimated
mean seasonal water column GPP (2.1 to 2.7 g Cm-2 d(-1)). Net heterotrophy
in the aphotic layer consumed the equivalent of a further 25 % of estimate
d -water column GPP. The degree of coupling between primary production and
respiration was primarily controlled by upwelling. During upwelling events
respiration was generally low in the water column but it increased as a lin
ear function of chlorophyll a concentration (R-2 = 0.55, n = 13) and GPP (R
-2 = 0.47, n = 13) in the surface layer. Under such condition phytoplankton
appears as the dominant component of community respiration consuming 14% o
f GPP. During periods of upwelling relaxation respiration was high relative
to GPP. High water column respiration rates extending occasionally down to
40 m took place at the expense of organic matter trapped inside the bay. T
he seasonal breakdown of thermal stratification in autumn presented a relat
ionship between surface respiration and chlorophyll a or GPP similar to tha
t observed during upwelling events. The large excess primary production dur
ing this period was not remineralised inside the ria, suggesting that a lar
ge fraction may be exported towards the shelf.