Nitrogen uptake and regeneration pathways in the equatorial Pacific: a basin scale modeling study

Wang, X. J.; Murtugudde, Ragu; Borgne, Robert Le

doi:10.5194/bg-6-2647-2009

Cited by 11 publications

(14 citation statements)

References 48 publications

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“…The influence of these processes on NPP variability and the resulting spatial repartition of regenerated versus new production (respectively in the western and eastern part of the tropical Pacific) are in agreement with previous regional modeling studies forced by atmospheric reanalyses (37,38). Thus, the model predictive skill Fig.…”

Section: What Mechanisms or Properties Could Be Responsible For The Dsupporting

confidence: 77%

Multiyear predictability of tropical marine productivity

Séférian

Bopp

Gehlen

et al. 2014

Proc. Natl. Acad. Sci. U.S.A.

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With the emergence of decadal predictability simulations, research toward forecasting variations of the climate system now covers a large range of timescales. However, assessment of the capacity to predict natural variations of relevant biogeochemical variables like carbon fluxes, pH, or marine primary productivity remains unexplored. Among these, the net primary productivity (NPP) is of particular relevance in a forecasting perspective. Indeed, in regions like the tropical Pacific (30°N-30°S), NPP exhibits natural fluctuations at interannual to decadal timescales that have large impacts on marine ecosystems and fisheries. Here, we investigate predictions of NPP variations over the last decades (i.e., from 1997 to 2011) with an Earth system model within the tropical Pacific. Results suggest a predictive skill for NPP of 3 y, which is higher than that of sea surface temperature (1 y). We attribute the higher predictability of NPP to the poleward advection of nutrient anomalies (nitrate and iron), which sustain fluctuations in phytoplankton productivity over several years. These results open previously unidentified perspectives to the development of science-based management approaches to marine resources relying on integrated physical-biogeochemical forecasting systems.forecast | ecosystem management | marine biogeochemistry

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Section: What Mechanisms or Properties Could Be Responsible For The Dsupporting

confidence: 77%

Multiyear predictability of tropical marine productivity

Séférian

Bopp

Gehlen

et al. 2014

Proc. Natl. Acad. Sci. U.S.A.

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show abstract

“…The soilcarbon scheme will be further improved to simulate the large carbon accumulations in organic peat soils, the stocks and dynamics of organic matter in permafrost. A dynamic marine ecosystem scheme will replace the current iBGC module, the new marine ecosystem scheme has improved parameterizations of dissolved organic materials and detritus , a phytoplankton dynamic module that produces a variable of carbon to chlorophyll ratio (Wang et al, 2009a), and refined nitrogen regeneration pathways (Wang et al, 2009b). Additionally, a three-dimensional canopy radiative transfer model (Yuan et al, 2014) will be adopted to replace the traditional one-dimensional two-stream approximation scheme in the land component to calculate terrestrial canopy radiation more realistically.…”

Section: Ji Et Al: Description and Basic Evaluation Of Bnu-esmmentioning

confidence: 99%

Description and basic evaluation of Beijing Normal University Earth System Model (BNU-ESM) version 1

et al. 2014

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Abstract. An earth system model has been developed at Beijing Normal University (Beijing Normal University Earth System Model, BNU-ESM); the model is based on several widely evaluated climate model components and is used to study mechanisms of ocean-atmosphere interactions, natural climate variability and carbon-climate feedbacks at interannual to interdecadal time scales. In this paper, the model structure and individual components are described briefly. Further, results for the CMIP5 (Coupled Model Intercomparison Project phase 5) pre-industrial control and historical simulations are presented to demonstrate the model's performance in terms of the mean model state and the internal variability. It is illustrated that BNU-ESM can simulate many observed features of the earth climate system, such as the climatological annual cycle of surface-air temperature and precipitation, annual cycle of tropical Pacific sea surface temperature (SST), the overall patterns and positions of cells in global ocean meridional overturning circulation. For example, the El Niño-Southern Oscillation (ENSO) simulated in BNU-ESM exhibits an irregular oscillation between 2 and 5 years with the seasonal phase locking feature of ENSO. Important biases with regard to observations are presented and discussed, including warm SST discrepancies in the major upwelling regions, an equatorward drift of midlatitude westerly wind bands, and tropical precipitation bias over the ocean that is related to the double Intertropical Convergence Zone (ITCZ).

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“…Figure 3 shows comparisons of the total nitrogen uptake, nitrate uptake, export production and net community production between the standard and NITR3 simulations for the equatorial Pacific. While the total nitrogen uptake was not expected to change (see details in [20]), our results also show little change in export production and net community production. However, there is a pronounced increase (20-50%) in the integrated nitrate uptake in the euphotic zone when nitrification rate is increased from 0 to 0.06 d −1 .…”

Section: Resultsmentioning

confidence: 60%

“…Ammonium, revealing considerable spatial and temporal variations with relatively low concentrations, may provide a sensitive and realistic check on the performance of biogeochemical models [30]. Moreover, an approach with integrated validations of concentrations and uptake rates of both nitrate and ammonium would provide an overall assessment on biogeochemical model skills [20], which requires integrated observations of different nitrogen forms and fluxes such as Raimbault et al [6].…”

Section: Discussionmentioning

confidence: 99%

“…Phytoplankton growth (thus nitrogen uptake) is a function of nitrogen, iron, temperature and light conditions. Parameterizations of nitrogen uptake and regeneration were described by Wang et al [20]. Our modeling effort has included extensive use of observational data for model calibration and validation; e.g., dissolved and particulate organic nitrogen [19], basinscale chlorophyll distribution [21], nitrate and ammonium uptake, and ammonium regeneration [20].…”

Section: Methodsmentioning

confidence: 99%

See 1 more Smart Citation

Distributions of inorganic nitrogen and biological production in the equatorial Pacific: a basin-scale model sensitivity study of nitrification

Wang

Murtugudde

2015

Geoscience Letters

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Recent evidence indicates that there is stronger nitrification in the euphotic zone than previously thought. We employ a physical-biogeochemical model to study the implications of nitrification for basin-scale distributions of nitrate, ammonium, and biological production in the equatorial Pacific. The model can faithfully reproduce observed features in nitrate distribution, with or without photoinhibition of nitrification in the euphotic zone. In addition, new production, net community production and export production are not very sensitive to the parameterization of nitrification in this model. However, simulated ammonium distribution, nitrate uptake and ammonium uptake are sensitive to this parameterization. High nitrification results in low ammonium concentration, low ammonium uptake rate, and high nitrate uptake rate in the euphotic zone. This study suggests that nitrification may be responsible for up to 40% of nitrate uptake in the equatorial Pacific. This modeling study also demonstrates large differences (in terms of the magnitude and spatial distribution) between nitrate uptake, new production and export production, reflecting decoupling of upward nutrient supply, biological uptake and downward export.

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Nitrogen uptake and regeneration pathways in the equatorial Pacific: a basin scale modeling study

Cited by 11 publications

References 48 publications

Multiyear predictability of tropical marine productivity

Multiyear predictability of tropical marine productivity

Description and basic evaluation of Beijing Normal University Earth System Model (BNU-ESM) version 1

Distributions of inorganic nitrogen and biological production in the equatorial Pacific: a basin-scale model sensitivity study of nitrification

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