Dynamics of nutrients and phytoplankton biomass in the Pearl River estuary and adjacent waters of Hong Kong during summer:preliminary evidence for phosphorus and silicon limitation

Abstract: The Pearl River in the south of China is the second largest river in China in terms of discharge volume. Two cruises were made to investigate the dynamics of nutrients and phytoplankton biomass in June and July 1998, across the Pearl River estuary to the adjacent territorial waters of Hong Kong. On-deck incubation experiments of 5 mixtures of freshwater from the surface with seawater from below the halocline were conducted to simulate time scales of phytoplankton blooms for each freshwaterheawater mixture and … Show more

“…A decrease in DIN : SRP ratios, to a certain extent, is generally consistent with the results of bioassays that there is a shift from P to N limitation (Doering et al 1995;Yin et al 2001;Smith 2006). Because surface seawater contains low nutrients, most previous studies have focused on changes in riverine nutrient loadings or additional sources of P in estuaries to explain the nonlinear decrease of N : P ratios across the salinity gradient (Fisher et al 1992;Yin et al 2004;Harrison et al 2008).The switch from P-limited riverine water to N limitation with increasing salinity is expected, because surface seawater generally has a DIN : SRP ratio of # 3 (Fanning 1992), although in the Mediterranean Sea, DIN : SRP ratios may exceed the Redfield ratio of 16 in winter (Krom et al 1991;Kress and Herut 2001). Previous studies have implied that a sudden shift in the limiting nutrient across estuaries is a salinity-related phenomenon (Caraco 1988;Doering et al 1995), but whether this shift is mainly because of changing riverine loadings, increasing salinity stress, additional sources of phosphorus, or just simply through mixing remains unclear.…”

Shifts in limiting nutrients in an estuary caused by mixing and biological activity

“…A decrease in DIN : SRP ratios, to a certain extent, is generally consistent with the results of bioassays that there is a shift from P to N limitation (Doering et al 1995;Yin et al 2001;Smith 2006). Because surface seawater contains low nutrients, most previous studies have focused on changes in riverine nutrient loadings or additional sources of P in estuaries to explain the nonlinear decrease of N : P ratios across the salinity gradient (Fisher et al 1992;Yin et al 2004;Harrison et al 2008).The switch from P-limited riverine water to N limitation with increasing salinity is expected, because surface seawater generally has a DIN : SRP ratio of # 3 (Fanning 1992), although in the Mediterranean Sea, DIN : SRP ratios may exceed the Redfield ratio of 16 in winter (Krom et al 1991;Kress and Herut 2001). Previous studies have implied that a sudden shift in the limiting nutrient across estuaries is a salinity-related phenomenon (Caraco 1988;Doering et al 1995), but whether this shift is mainly because of changing riverine loadings, increasing salinity stress, additional sources of phosphorus, or just simply through mixing remains unclear.…”

Shifts in limiting nutrients in an estuary caused by mixing and biological activity

“…Phosphorus was the potential limiting nutrient in PRE (Yin et al, 2000). The particle-bound P would release into the water when the ambient PO 4 3 − concentration decreased, which potentially alleviated P limitation in the Pearl River estuary.…”

Relationship between nutrients and plankton biomass in the turbidity maximum zone of the Pearl River Estuary

“…First, many rivers that are rich in NO 3 À and NO 2 À flow into the SCS. In particular, two of the largest rivers in the world (the Mekong and Pearl Rivers) enter from the north, contributing large amounts of nutrients and organic matter to the SCS, especially in the wet season (Yin et al, 2000;Chen et al, 2008). Also, the high-nutrient riverine water fuels higher productivity in the SCS relative to the WPS.…”

Distributions and sea-to-air fluxes of nitrous oxide in the South China Sea and the West Philippines Sea