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The role of physical forcing in initiation of spring blooms in the northeast Atlantic

The role of physical forcing in initiation of spring blooms in the northeast Atlantic
The role of physical forcing in initiation of spring blooms in the northeast Atlantic
In this paper, the relationship between changes in the intensity of the spring bloom and changes in the physical forcing, mediated by the upper ocean mixing, is examined and illustrated. An idealized mixed-layer model coupled with an NPZD model with two different detritus compartments provides a conceptual framework, predicting the biological response to vertical mixing anomalies in the ocean–surface boundary layer. The model of coupled biological–hydrodynamic processes is used to search for general physical principles of phytoplankton bloom regulation in open ocean waters. The study addresses three questions: How does an individual winter differ from climatologically averaged ones? What are the dynamics of stratification in open ocean systems as influenced by variable atmospheric forcing? How does phytoplankton growth respond to these dynamics?
The calculations suggest that changes in the balance of the atmospheric forcing on a daily scale could lead to less pronounced fluctuations of the mixed layer in winter as during most of the day the heat input by the sun exceeds or compensates the heat loss by nonsolar heat flux components (i.e. transient or moderate conditions). Furthermore, the model results show that the springtime shallowing of the mixed layer is not typically a smooth transition, but is interrupted by mixing events stimulated by passage of weather systems. The frequency and intensity of these synoptic events varies from year to year due to shift in storm tracks and modes of atmospheric circulation. The simulations suggest that such synoptic events (storms) associated with time scales of several days, and the period of the year when the heat flux changes sign, are important for the development of the phytoplankton population. Enhanced or reduced storm frequency associated with changes in vertical mixing intensity during the late winter/spring period leads to an increase/decrease in amplitude and duration of the bloom caused by enhanced/reduced nutrient supply or retard it due to light limitation. Finally, supported by the model results and observations, the role of interannual variability in physical forcing on timing, amplitude and structure of the phytoplankton bloom for the period 1989–1997 is examined.
BIOGEOCHEMICAL CYCLE, ATLANTIC OCEAN, PHYTOPLANKTON, BIOMASS, BIOLOGY
0924-7963
57-82
Waniek, J.J.
749b55a4-c736-4961-a522-37645dd73b45
Waniek, J.J.
749b55a4-c736-4961-a522-37645dd73b45

Waniek, J.J. (2003) The role of physical forcing in initiation of spring blooms in the northeast Atlantic. Journal of Marine Systems, 39 (1-2), 57-82. (doi:10.1016/S0924-7963(02)00248-8).

Record type: Article

Abstract

In this paper, the relationship between changes in the intensity of the spring bloom and changes in the physical forcing, mediated by the upper ocean mixing, is examined and illustrated. An idealized mixed-layer model coupled with an NPZD model with two different detritus compartments provides a conceptual framework, predicting the biological response to vertical mixing anomalies in the ocean–surface boundary layer. The model of coupled biological–hydrodynamic processes is used to search for general physical principles of phytoplankton bloom regulation in open ocean waters. The study addresses three questions: How does an individual winter differ from climatologically averaged ones? What are the dynamics of stratification in open ocean systems as influenced by variable atmospheric forcing? How does phytoplankton growth respond to these dynamics?
The calculations suggest that changes in the balance of the atmospheric forcing on a daily scale could lead to less pronounced fluctuations of the mixed layer in winter as during most of the day the heat input by the sun exceeds or compensates the heat loss by nonsolar heat flux components (i.e. transient or moderate conditions). Furthermore, the model results show that the springtime shallowing of the mixed layer is not typically a smooth transition, but is interrupted by mixing events stimulated by passage of weather systems. The frequency and intensity of these synoptic events varies from year to year due to shift in storm tracks and modes of atmospheric circulation. The simulations suggest that such synoptic events (storms) associated with time scales of several days, and the period of the year when the heat flux changes sign, are important for the development of the phytoplankton population. Enhanced or reduced storm frequency associated with changes in vertical mixing intensity during the late winter/spring period leads to an increase/decrease in amplitude and duration of the bloom caused by enhanced/reduced nutrient supply or retard it due to light limitation. Finally, supported by the model results and observations, the role of interannual variability in physical forcing on timing, amplitude and structure of the phytoplankton bloom for the period 1989–1997 is examined.

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Published date: 2003
Keywords: BIOGEOCHEMICAL CYCLE, ATLANTIC OCEAN, PHYTOPLANKTON, BIOMASS, BIOLOGY

Identifiers

Local EPrints ID: 2250
URI: http://eprints.soton.ac.uk/id/eprint/2250
ISSN: 0924-7963
PURE UUID: 08d2d37b-efa9-4360-8efb-2e02078c7e37

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Date deposited: 21 May 2004
Last modified: 15 Mar 2024 04:45

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Author: J.J. Waniek

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