GLORIA — GEOMAR Library Ocean Research Information Access

1

Book

Nutrient trapping in the equatorial Pacific : the ocean circulation solution (1998)

Aumont, O.

Paris

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Type of Medium: Book

Pages: 35 S , Ill

Series Statement: Notes du pole de modelisation 5

Language: English

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2

Electronic Resource

A degradation approach to accelerate simulations to steady-state in a 3-D tracer transport model of the global ocean (1998)

Aumont, O. ; Orr, J. C. ; Jamous, D. ; [et al.]

Springer

Climate dynamics 14 (1998), S. 101-116

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ISSN: 1432-0894

Source: Springer Online Journal Archives 1860-2000

Topics: Geosciences , Physics

Notes: Abstract We have developed a new method to accelerate tracer simulations to steady-state in a 3-D global ocean model, run off-line. Using this technique, our simulations for natural 14C ran 17 times faster when compared to those made with the standard non-accelerated approach. For maximum acceleration we wish to initialize the model with tracer fields that are as close as possible to the final equilibrium solution. Our initial tracer fields were derived by judiciously constructing a much faster, lower-resolution (degraded), off-line model from advective and turbulent fields predicted from the parent on-line model, an ocean general circulation model (OGCM). No on-line version of the degraded model exists; it is based entirely on results from the parent OGCM. Degradation was made horizontally over sets of four adjacent grid-cell squares for each vertical layer of the parent model. However, final resolution did not suffer because as a second step, after allowing the degraded model to reach equilibrium, we used its tracer output to re-initialize the parent model (at the original resolution). After re-initialization, the parent model must then be integrated only to a few hundred years before reaching equilibrium. To validate our degradation-integration technique (DEGINT), we compared 14C results from runs with and without this approach. Differences are less than 10‰ throughout 98.5% of the ocean volume. Predicted natural 14C appears reasonable over most of the ocean. In the Atlantic, modeled Δ14C indicates that as observed, the North Atlantic Deep Water (NADW) fills the deep North Atlantic, and Antartic Intermediate Water (AAIW) infiltrates northward; conversely, simulated Antarctic Bottom Water (AABW) does not penetrate northward beyond the equator as it should. In the Pacific, in surface eastern equatorial waters, the model produces a north–south assymetry similar to that observed; other global ocean models do not, because their resolution is inadequate to resolve equatorial dynamics properly, particularly the intense equatorial undercurrent. The model’s oldest water in the deep Pacific (at −239‰) is close to that observed (−248‰), but is too deep. Surface waters in the Southern Ocean are too rich in natural 14C due to inadequacies in the OGCM’s thermohaline forcing.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/s003820050212

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3

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The significance of the episodic nature of atmospheric deposition to Low Nutrient Low Chlorophyll region (2014)

Guieu, C. ; Aumont, O. ; Paytan, A. ; [et al.]

AGU (American Geophysical Union) | Wiley

In: Global Biogeochemical Cycles, 28 (11). pp. 1179-1198.

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Publication Date: 2021-04-23

Description: In the vast Low Nutrient Low-Chlorophyll (LNLC) Ocean, the vertical nutrient supply from the subsurface to the sunlit surface waters is low, and atmospheric contribution of nutrients may be one order of magnitude greater over short timescales. The short turnover time of atmospheric Fe and N supply (〈1 month for nitrate) further supports deposition being an important source of nutrients in LNLC regions. Yet, the extent to which atmospheric inputs are impacting biological activity and modifying the carbon balance in oligotrophic environments has not been constrained. Here, we quantify and compare the biogeochemical impacts of atmospheric deposition in LNLC regions using both a compilation of experimental data and model outputs. A metadata-analysis of recently conducted field and laboratory bioassay experiments reveals complex responses, and the overall impact is not a simple “fertilization effect of increasing phytoplankton biomass” as observed in HNLC regions. Although phytoplankton growth may be enhanced, increases in bacterial activity and respiration result in weakening of biological carbon sequestration. The application of models using climatological or time-averaged non-synoptic deposition rates produced responses that were generally much lower than observed in the bioassay experiments. We demonstrate that experimental data and model outputs show better agreement on short timescale (days to weeks) when strong synoptic pulse of aerosols deposition, similar in magnitude to those observed in the field and introduced in bioassay experiments, is superimposed over the mean atmospheric deposition fields. These results suggest that atmospheric impacts in LNLC regions have been underestimated by models, at least at daily to weekly timescales, as they typically overlook large synoptic variations in atmospheric deposition and associated nutrient and particle inputs. Inclusion of the large synoptic variability of atmospheric input, and improved representation and parameterization of key processes that respond to atmospheric deposition, is required to better constrain impacts in ocean biogeochemical models. This is critical for understanding and prediction of current and future functioning of LNLC regions and their contribution to the global carbon cycle.

Type: Article , PeerReviewed

Format: text

DOI: 10.1002/2014GB004852

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4

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Influence of mesoscale eddies on biological production in the Mozambique Channel: Several contrasted examples from a coupled ocean-biogeochemistry model (2014)

Jose, Yonss S. ; Aumont, O. ; Machu, E. ; [et al.]

Elsevier

In: Deep Sea Research Part II: Topical Studies in Oceanography, 100 . pp. 79-93.

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Publication Date: 2015-01-12

Description: The impact of mesoscale activity on phytoplankton and nutrient distribution in the Mozambique Channel was simulated by coupling a biogeochemical model (PISCES) with a regional oceanic model (ROMS). Examples of the effects of eddies on the biogeochemistry of the Mozambique Channel are presented to illustrate the complexity of the system. In the model, several cyclonic eddies were found with low concentrations of chlorophyll at their cores, which contrasts with previous studies in the open ocean. In addition, several anticyclonic eddies were simulated with high concentrations of chlorophyll at their cores. Phytoplankton growth within these mesoscale features (both cyclonic and anticyclonic eddies) occurred in response to nutrient injection into the euphotic zone by advection, and subsequent retention of surrounding nutrient-rich waters within eddies. Offshore nutrient distributions depended strongly on lateral advection of nutrient-rich water from the coastal regions, induced by eddy interaction with the shelf. The environmental conditions at the locations where eddies were generated had an important effect on nutrient concentrations within these structures.

Type: Article , PeerReviewed

Format: text

DOI: 10.1016/j.dsr2.2013.10.018

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5

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Modeling the marine aragonite cycle: changes under rising carbon dioxide and its role in shallow water CaCO3 dissolution (2008)

Gangsto, R. ; Gehlen, M. ; Schneider, Birgit ; [et al.]

Copernicus Publications (EGU)

In: Biogeosciences (BG), 5 (4). pp. 1057-1072.

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Publication Date: 2019-09-23

Description: The marine aragonite cycle has been included in the global biogeochemical model PISCES to study the role of aragonite in shallow water CaCO3 dissolution. Aragonite production is parameterized as a function of mesozooplankton biomass and aragonite saturation state of ambient waters. Observation-based estimates of marine carbonate production and dissolution are well reproduced by the model and about 60% of the combined CaCO3 water column dissolution from aragonite and calcite is simulated above 2000 m. In contrast, a calcite-only version yields a much smaller fraction. This suggests that the aragonite cycle should be included in models for a realistic representation of CaCO3 dissolution and alkalinity. For the SRES A2 CO2 scenario, production rates of aragonite are projected to notably decrease after 2050. By the end of this century, global aragonite production is reduced by 29% and total CaCO3 production by 19% relative to pre-industrial. Geographically, the effect from increasing atmospheric CO2, and the subsequent reduction in saturation state, is largest in the subpolar and polar areas where the modeled aragonite production is projected to decrease by 65% until 2100.

Type: Article , PeerReviewed

DOI: 10.5194/bg-5-1057-2008

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6

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Suppressing and enhancing effects of mesoscale dynamics on biological production in the Mozambique Channel (2016)

Jose, Yonss S. ; Penven, P. ; Aumont, O. ; [et al.]

Elsevier

In: Journal of Marine Systems, 158 . pp. 129-139.

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Publication Date: 2019-02-01

Description: We used a coupled physical–biogeochemical model to investigate how the strong eddy activity typical of the Mozambique Channel affects biological production. A numerical experiment was carried out, in which mesoscale dynamics were suppressed by cancelling the nonlinear terms for horizontal momentum in the Naviers–Stokes equation. Mesoscale dynamics were found to be responsible for (1) increased offshore production in the Mozambique Channel as a result of net eddy-induced offshore transport of nutrient-rich coastal waters; (2) decreased shelf production along the central Mozambican and south-west Madagascar coast caused by a reduction in nutrient availability related to the net eddy-induced lateral transport of nutrients; (3) increased coastal production along the northern Mozambican coast caused by eddy-induced nutrient supply. The model results also showed an intensification and shallowing of the subsurface production, related to increased upper layer nutrient concentrations caused by eddy activity. In addition, by driving the detachment of the East Madagascar Current at the southern tip of the island, inertial processes intensify the southern Madagascar upwelling and causes offshore diffusion of the upwelled waters. These results emphasize the complex role played by eddy activity and, more generally, inertial processes on marine ecosystems in this region.

Type: Article , PeerReviewed

Format: text

DOI: 10.1016/j.jmarsys.2016.02.003

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7

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Preformed and regenerated phosphate in ocean general circulation models: can right total concentrations be wrong? (2012)

Duteil, Olaf ; Koeve, Wolfgang ; Oschlies, Andreas ; [et al.]

Copernicus Publications (EGU)

In: Biogeosciences (BG), 9 . pp. 1797-1807.

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Publication Date: 2020-10-16

Description: Phosphate distributions simulated by seven state-of-the-art biogeochemical ocean circulation models are evaluated against observations of global ocean nutrient distributions. The biogeochemical models exhibit different structural complexities, ranging from simple nutrient-restoring to multi-nutrient NPZD type models. We evaluate the simulations using the observed volume distribution of phosphate. The errors in these simulated volume class distributions are significantly larger when preformed phosphate (or regenerated phosphate) rather than total phosphate is considered. Our analysis reveals that models can achieve similarly good fits to observed total phosphate distributions for a very different partitioning into preformed and regenerated nutrient components. This has implications for the strength and potential climate sensitivity of the simulated biological carbon pump. We suggest complementing the use of total nutrient distributions for assessing model skill by an evaluation of the respective preformed and regenerated nutrient components.

Type: Article , PeerReviewed

Format: text

DOI: 10.5194/bg-9-1797-2012

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8

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Impact of Chlorophyll Shading on the Peruvian Upwelling System (2021)

Echevin, V. ; Hauschildt, Jaard ; Colas, F. ; [et al.]

AGU (American Geophysical Union) | Wiley

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Publication Date: 2024-02-07

Description: The influence of chlorophyll shading on ocean dynamics has been usually disregarded in eastern boundary upwelling systems modeling studies in spite of their very high primary productivity. Here, we study how this effect impacts on the Peru upwelling system using a regional mesoscale-resolving physical biogeochemical coupled model. We show that the shading effect leads to a surface cooling of up to 1°C on the shelf due to subsurface cooling of the source waters during their transit toward the shelf. The shading effect leads to a more realistic subsurface stratification, a slowdown of the alongshore currents, and a shoaling of the oxycline. Impacts on the regional model biases show that the shading effect needs to be taken into account in both physical and coupled physical-biogeochemical regional models of upwelling systems.

Type: Article , PeerReviewed , info:eu-repo/semantics/article

Format: text

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9

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Small-scale physical processes are key drivers of annual variations in phytoplankton biomass (2023)

Madhavan Girijakumari, K. ; Levy, M. ; Prend, C. ; [et al.]

In: XXVIII General Assembly of the International Union of Geodesy and Geophysics (IUGG)

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Publication Date: 2023-07-31

Description: Phytoplankton biomass exhibits significant year-to-year changes, and understanding these changes is crucial for fisheries management and projecting future climate. These annual changes are usually attributed to low-frequency climate modes that also lead to variations in sea surface temperature (SST). We evaluate the contribution of small scales to annual fluctuations based on a global analysis of satellite observations of sea surface chlorophyll (SChl), an indicator of phytoplankton biomass, and of SST from 1999 to 2018. To quantitatively disentangle the spatio-temporal scales of variability, we utilize a timeseries decomposition method that isolates distinct frequency bands. We show that besides the prominent seasonal cycle, SChl is dominated by high-frequency fluctuations (〈3 months) at small spatial scales (〈50 km)—which accumulate over annual scales, in contrast to SST. This implies that slow variations in the environment linked to climate modes can’t fully explain the annual variations in phytoplankton biomass. Instead, the cumulative effect of fine-scale variations drives the year-to-year changes. This result is further examined over the Southern Ocean, where large annual variations are evident. We find that the Southern Annular Mode (SAM), the dominant low-frequency climate signal in the region, can explain only 10% of the annual variations in SChl. Rather, most of the annual variations are associated with small spatial-scale, high-frequency fluctuations, which are not correlated with the SAM. Our results suggest that observations and models with high spatio-temporal resolutions are necessary to understand annual variations in phytoplankton biomass and to detect climate change driven trends.

Language: English

Type: info:eu-repo/semantics/conferenceObject

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GFZ OAI

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Ocean CO2 sequestration efficiency from 3-d ocean model comparison (2001)

Orr, J. C. ; Aumont, O. ; Yool, A. ; [et al.]

In: EPIC3Greenhouse Gas Control Technologies, edited by D. Williams, B. Durie, P. McMullan, C. Paulson, and A. Smith, CSIRO, pp. 469-474

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Publication Date: 2019-07-16

Repository Name: EPIC Alfred Wegener Institut

Type: Inbook , peerRev

Format: application/pdf

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