Nutrient cycling and fluxes in Beatrix Bay, Pelorus Sound, New Zealand

Gibbs, Max M.; Ross, Alex H.; Downes, Malcolm T.

doi:10.1080/00288330.2002.9517123

Cited by 14 publications

(5 citation statements)

References 41 publications

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“…The lack of synchronicity would suggest that the labile carbon compounds were degraded by heterotrophic organisms in the surface layer limited by the thermocline and that only a small proportion of larger particles (particularly faecal pellets) and macroaggregates were deposited in sediments. These results coincide with those observed by di¡erent authors in the neritic zone of the north-west Mediterranean (Cahet et al, 1972), in Norway ¢ords (Sargent et al, 1983) and in Beatrix Bay, New Zealand (Gibbs et al, 2002). In similar environments, breakage of the pycnocline by wind and hydrodynamic conditions favour the export of autochthonous material towards the bottom (Olesen & Lundsgaard, 1995;Pesant et al, 2002).…”

Section: Discussionsupporting

confidence: 90%

Physico-chemical characterization of the benthic environment of the Golfo San Jorge, Argentina

et al. 2005

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The benthic system of the Golfo San Jorge was characterized from physico-chemical parameters based on samplings obtained during seasonal research cruises carried out on board the INIDEP vessels from springtime 1999 through wintertime 2000. Spatial and seasonal variations of temperature, salinity, density, oxygen content and chlorophyll-a in bottom water and concentration of total organic matter, total organic carbon, total nitrogen, chlorophyll-a and phaeopigments in sediments were analysed. The origin and nutritional value of the deposited organic matter were also assessed. The behaviour of the physico-chemical characteristics of the benthic habitat, studied applying statistical techniques, de¢ned three sectors with particular characteristics and minimum seasonal variations: sector 1, the largest and deepest one, comprises the central area of the gulf and corresponds to a depositional environment; sector 2 comprises the areas next to the extremes of the gulf and corresponds to a £ow or erosive environment; sector 3 includes the coastal area and south-east part of the gulf and belongs to a transitional environment.

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Section: Discussionsupporting

confidence: 90%

Physico-chemical characterization of the benthic environment of the Golfo San Jorge, Argentina

et al. 2005

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“…10, 11), where near bottom DIN concentrations were often significantly elevated. Gibbs et al (2002) have calculated that up to 80% of the annual DIN supply for Beatrix Bay (a large embayment within the Marlborough Sounds, New Zealand) may come from sediment recycling. However, as they point out, during strongly stratified periods much of this DIN may not be accessible to phytoplankton within the upper water column.…”

Section: Discussionmentioning

confidence: 99%

River inputs, re‐mineralisation and the spatial and temporal distribution of inorganic nutrients in Tasman Bay, New Zealand

MacKenzie¹

2004

New Zealand Journal of Marine and Freshwater Research

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To improve understanding of the temporal and spatial variability of biological productivity relevant to fisheries enhancement within Tasman Bay, New Zealand, it is necessary to evaluate the importance of variations in river inflows on inorganic nutrient dynamics. To achieve this, a series of synoptic surveys of surface and water column salinity fields and inorganic nutrient concentrations were carried out over a 1-year period, at seasonally representative times, during, and soon after, a range of flow regimes in the major freshwater tributaries of Tasman Bay. An assessment was made of the relative importance of external (i.e., river borne) and internal (i.e., recycling) nutrient sources that control the fertility of the Tasman Bay water column. Flood events in the bay's catchment cause significant changes in the levels of dissolved nitrogen, phosphorus, and silica in surface waters, and on an annual basis 60-70% of the input of "new" dissolved inorganic nitrogen from freshwater tributaries is contributed by the Motueka River. As a consequence there is a pronounced east to west gradient in nutrient enrichment, and oceanic water most frequently intrudes along the eastern shore. Surface salinity and inorganic nutrient distribution patterns and inferred water movements are consistent with the left hand deflection of buoyant river plumes. The predictable timing and magnitude of the winter nitrate/nitrite maxima suggests that light is the main factor limiting phytoplankton production and nutrient assimilation during the winter, and that benthic and pelagic re-mineralisation processes are the dominant mechanism generating the annual nutrient maxima within M03065; Online publication date 5 August 2004 Received 3 October 2003; accepted 23 April 2004the water column as a whole. Calculations suggest that the net accumulation of inorganic nitrogen via endogenous re-mineralisation over the autumn-winter period is of a similar order of magnitude to the annual introduction of new nitrogen from freshwater sources. How this compares to inputs of new nitrogen by advection from oceanic sources has yet to be determined.

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“…On three sampling occasions (August andNovember 2003, andJanuary 2004), in situ DO sensors (Van Essen Instruments) were also used to record changes in DO concentration at 15 min intervals in a light and a dark chamber (sites 1 and 2) or in all chambers (site 3). Sediment NH 4 and SRP fluxes were calculated from the slope of linear regressions of chamber nutrient concentrations with time (Gibbs et al, 2002). After correcting for the effect of dilution associated with sample removal, rates of change of nutrient concentrations in the chamber were divided by the sediment surface area in the chambers, to give an aerial release rate.…”

Section: Sediment Nutrient Fluxesmentioning

confidence: 99%

Benthic nutrient fluxes in a eutrophic, polymictic lake

et al. 2007

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Sediment release rates of soluble reactive phosphorus (SRP) and ammonium (NH 4 ) were determined seasonally at three sites (water depth 7, 14 and 20 m) in Lake Rotorua using in situ benthic chamber incubations. Rates of release of SRP ranged from 2.2 to 85.6 mg P m -2 d -1 and were largely independent of dissolved oxygen (DO) concentration. Two phases of NH 4 release were observed in the chamber incubations; high initial rates of up to 2,200 mg N m -2 d -1 in the first 12 h of deployment followed by lower rates of up to 270 mg N m -2 d -1 in the remaining 36 h of deployment. Releases of SRP and NH 4 were highest in summer and at the deepest of the three sites. High organic matter supply rates to the sediments may be important for sustaining high rates of sediment nutrient release. A nutrient budget of Lake Rotorua indicates that internal nutrient sources derived from benthic fluxes are more important than external nutrient sources to the lake.

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Nutrient cycling and fluxes in Beatrix Bay, Pelorus Sound, New Zealand

Cited by 14 publications

References 41 publications

Physico-chemical characterization of the benthic environment of the Golfo San Jorge, Argentina

Physico-chemical characterization of the benthic environment of the Golfo San Jorge, Argentina

River inputs, re‐mineralisation and the spatial and temporal distribution of inorganic nutrients in Tasman Bay, New Zealand

Benthic nutrient fluxes in a eutrophic, polymictic lake

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