Vertical mixing effects on the phytoplankton bloom in the southeastern Bering Sea midshelf

Vertical mixing effects on the phytoplankton bloom in the southeastern Bering Sea midshelf

A vertically one‐dimensional ecosystem model was developed and applied to the southeastern Bering Sea middle shelf. The physical model includes a 2.5‐level turbulence model. Tidal forcing was introduced to improve representation of tidal mixing in addition to wind stirring and thermal stratification...

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Bibliographic Details
Published in:Journal of Geophysical Research - Oceans Vol. 111; no. C3; pp. C03002 - n/a
Main Authors: Jin, Meibing, Deal, Clara J., Wang, Jia, Tanaka, Nori, Ikeda, Moto
Format: Journal Article
Language:English
Published: Washington, DC American Geophysical Union 01-03-2006
Blackwell Publishing Ltd
Subjects:
Bacillariophyceae
Biogeosciences
Continental shelf and slope processes
Earth sciences
Earth, ocean, space
Ecosystems, structure and dynamics
Exact sciences and technology
Marine
Modeling
Numerical modeling
Oceanography
primary production
vertical mixing
West Pacific
Bering Sea
IN, Bering Sea
modeling
primary production
vertical mixing
sensitivity analysis
springs
mixing
Biological model
algae
aluminum
currents
physical models
winds
Spring(season)
phytoplankton
plankton
Forcing
Thallophyta
biomass
Plantae
thermocline
Thermal stratification
turbulence
Mixed layer
depth
diatoms
standard samples
ecosystems
Pacific Ocean
programs
Timing
primary productivity
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Summary:A vertically one‐dimensional ecosystem model was developed and applied to the southeastern Bering Sea middle shelf. The physical model includes a 2.5‐level turbulence model. Tidal forcing was introduced to improve representation of tidal mixing in addition to wind stirring and thermal stratification. The simulated currents, thermocline and mixed‐layer depth (MLD) agree well with observations. The biological model was adapted from Eslinger et al. (2001) with nine compartments. The onset, magnitude and duration of the spring phytoplankton blooms were realistically reproduced at 12 m, 24 m, and 44 m in the standard run. The spring phytoplankton bloom was dominated by diatoms, and the post blooms by flagellates, which agree with previous studies in the region. The peak phytoplankton biomass reached 8 mmol N m−3, or approximately 16 mg Chl m−3, comparable to that observed in the PROBES program in 1980 and 1981 (Eslinger and Iverson, 2001). The simulated primary productions were within the range of 60 to 200 g C m−2/yr estimated in previous studies. Sensitivity studies revealed distinct effects of tidal mixing, wind stirring, thermal stratification and their impacts on the timing and magnitude of the phytoplankton bloom and the gross and net primary production. Links of MLD with primary production and species were found. If a constant MLD is used in the model, there exists a maximum gross primary production (GPP) at MLD = 24 m. Model results reveals that the predominant phytoplankton species changes from flagellates when MLD < 15 m to diatoms when MLD > 15 m.
Bibliography:Tab-delimited Table 1.Tab-delimited Table 2.Tab-delimited Table 3.Tab-delimited Table 4.Tab-delimited Table 5.Tab-delimited Table 6.
ArticleID:2005JC002994
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content type line 23
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ISSN:0148-0227
2169-9275
2156-2202
2169-9291
DOI:10.1029/2005JC002994