Mechanisms controlling primary and new production in a global ecosystem model Part I: Validation of the biological simulation
Mechanisms controlling primary and new production in a global ecosystem model Part I: Validation of the biological simulation
A global general circulation model coupled to a simple six-compartment ecosystem model is used to study the extent to which global variability in primary and export production can be realistically predicted on the basis of advanced parameterizations of upper mixed layer physics, without recourse to introducing extra complexity in model biology. The “K profile parameterization” (KPP) scheme employed, combined with 6-hourly external forcing, is able to capture short-term periodic and episodic events such as diurnal cycling and storm-induced deepening. The model realistically reproduces various features of global ecosystem dynamics that have been problematic in previous global modelling studies, using a single generic parameter set. The realistic simulation of deep convection in the North Atlantic, and lack of it in the North Pacific and Southern Oceans, leads to good predictions of chlorophyll and primary production in these contrasting areas. Realistic levels of primary production are predicted in the oligotrophic gyres due to high frequency external forcing of the upper mixed layer (accompanying paper Popova et al., 2006) and novel parameterizations of zooplankton excretion. Good agreement is shown between model and observations at various JGOFS time series sites: BATS, KERFIX, Papa and HOT. One exception is the northern North Atlantic where lower grazing rates are needed, perhaps related to the dominance of mesozooplankton there. The model is therefore not globally robust in the sense that additional parameterizations are needed to realistically simulate ecosystem dynamics in the North Atlantic. Nevertheless, the work emphasises the need to pay particular attention to the parameterization of mixed layer physics in global ocean ecosystem modelling as a prerequisite to increasing the complexity of ecosystem models.
249-266
Popova, E.E.
3ea572bd-f37d-4777-894b-b0d86f735820
Coward, A.C.
53b78140-2e65-476a-b287-e8384a65224b
Nurser, G.A.
2493ef9a-21e9-4d8b-9c32-08677e7e145a
de Cuevas, B.
01cc697c-2832-4de6-87bf-bf9f16c1f906
Fasham, M.J.R.
7fb86485-8cfc-4199-bde4-2276abefdf2e
Anderson, T.R.
dfed062f-e747-48d3-b59e-2f5e57a8571d
2006
Popova, E.E.
3ea572bd-f37d-4777-894b-b0d86f735820
Coward, A.C.
53b78140-2e65-476a-b287-e8384a65224b
Nurser, G.A.
2493ef9a-21e9-4d8b-9c32-08677e7e145a
de Cuevas, B.
01cc697c-2832-4de6-87bf-bf9f16c1f906
Fasham, M.J.R.
7fb86485-8cfc-4199-bde4-2276abefdf2e
Anderson, T.R.
dfed062f-e747-48d3-b59e-2f5e57a8571d
Popova, E.E., Coward, A.C., Nurser, G.A., de Cuevas, B., Fasham, M.J.R. and Anderson, T.R.
(2006)
Mechanisms controlling primary and new production in a global ecosystem model Part I: Validation of the biological simulation.
Ocean Science, 2 (2), .
Abstract
A global general circulation model coupled to a simple six-compartment ecosystem model is used to study the extent to which global variability in primary and export production can be realistically predicted on the basis of advanced parameterizations of upper mixed layer physics, without recourse to introducing extra complexity in model biology. The “K profile parameterization” (KPP) scheme employed, combined with 6-hourly external forcing, is able to capture short-term periodic and episodic events such as diurnal cycling and storm-induced deepening. The model realistically reproduces various features of global ecosystem dynamics that have been problematic in previous global modelling studies, using a single generic parameter set. The realistic simulation of deep convection in the North Atlantic, and lack of it in the North Pacific and Southern Oceans, leads to good predictions of chlorophyll and primary production in these contrasting areas. Realistic levels of primary production are predicted in the oligotrophic gyres due to high frequency external forcing of the upper mixed layer (accompanying paper Popova et al., 2006) and novel parameterizations of zooplankton excretion. Good agreement is shown between model and observations at various JGOFS time series sites: BATS, KERFIX, Papa and HOT. One exception is the northern North Atlantic where lower grazing rates are needed, perhaps related to the dominance of mesozooplankton there. The model is therefore not globally robust in the sense that additional parameterizations are needed to realistically simulate ecosystem dynamics in the North Atlantic. Nevertheless, the work emphasises the need to pay particular attention to the parameterization of mixed layer physics in global ocean ecosystem modelling as a prerequisite to increasing the complexity of ecosystem models.
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Published date: 2006
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Local EPrints ID: 43919
URI: http://eprints.soton.ac.uk/id/eprint/43919
ISSN: 1812-0792
PURE UUID: fd16b2f0-37b5-4307-874c-02e340bb5943
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Date deposited: 01 Feb 2007
Last modified: 08 Jan 2022 01:08
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Contributors
Author:
E.E. Popova
Author:
A.C. Coward
Author:
G.A. Nurser
Author:
B. de Cuevas
Author:
M.J.R. Fasham
Author:
T.R. Anderson
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