Challenges associated with modeling low-oxygen waters in Chesapeake Bay: a multiple model comparison

Challenges associated with modeling low-oxygen waters in Chesapeake Bay: a multiple model comparison

As three-dimensional (3-D) aquatic ecosystem models are used more frequently for operational water quality forecasts and ecological management decisions, it is important to understand the relative strengths and limitations of existing 3-D models of varying spatial resolution and biogeochemical compl...

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Main Authors: I. D. Irby, M. A. M. Friedrichs, C. T. Friedrichs, A. J. Bever, R. R. Hood, L. W. J. Lanerolle, M. Li, L. Linker, M. E. Scully, K. Sellner, J. Shen, J. Testa, H. Wang, P. Wang, M. Xia
Format: Article
Language:English
Published: Copernicus Publications 2016-04-01
Series:Biogeosciences
Online Access:http://www.biogeosciences.net/13/2011/2016/bg-13-2011-2016.pdf
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spelling doaj-6b1c41eb002641e3b58d01e4d16afb822020-11-25T01:50:14ZengCopernicus PublicationsBiogeosciences1726-41701726-41892016-04-011372011202810.5194/bg-13-2011-2016Challenges associated with modeling low-oxygen waters in Chesapeake Bay: a multiple model comparisonI. D. Irby0M. A. M. Friedrichs1C. T. Friedrichs2A. J. Bever3R. R. Hood4L. W. J. Lanerolle5M. Li6L. Linker7M. E. Scully8K. Sellner9J. Shen10J. Testa11H. Wang12P. Wang13M. Xia14Virginia Institute of Marine Science, College of William & Mary, P.O. Box 1346, Gloucester Point, VA 23062, USAVirginia Institute of Marine Science, College of William & Mary, P.O. Box 1346, Gloucester Point, VA 23062, USAVirginia Institute of Marine Science, College of William & Mary, P.O. Box 1346, Gloucester Point, VA 23062, USAAnchor QEA, LLC, 130 Battery Street, Suite 400, San Francisco, CA 94111, USAHorn Point Laboratory, University of Maryland Center for Environmental Science, P.O. Box 775, Cambridge, MD 21613, USANOAA/NOS/OCS Coast Survey Development Laboratory, 1315 East–West Highway, Silver Spring, MD 20910, USAChesapeake Biological Laboratory, University of Maryland Center for Environmental Science, P.O. Box 38, Solomons, MD 20688, USAUS Environmental Protection Agency Chesapeake Bay Program Office, 410 Severn Avenue, Annapolis, MD 21403, USAWoods Hole Oceanographic Institution, Applied Ocean Physics and Engineering Department, Woods Hole, MA 02543, USAChesapeake Research Consortium, 645 Contees Wharf Road, Edgewater, MD 21037, USAVirginia Institute of Marine Science, College of William & Mary, P.O. Box 1346, Gloucester Point, VA 23062, USAChesapeake Biological Laboratory, University of Maryland Center for Environmental Science, P.O. Box 38, Solomons, MD 20688, USAHorn Point Laboratory, University of Maryland Center for Environmental Science, P.O. Box 775, Cambridge, MD 21613, USAVIMS/Chesapeake Bay Program Office, 410 Severn Avenue, Annapolis, MD 21403, USADepartment of Natural Sciences, University of Maryland Eastern Shore, MD, USAAs three-dimensional (3-D) aquatic ecosystem models are used more frequently for operational water quality forecasts and ecological management decisions, it is important to understand the relative strengths and limitations of existing 3-D models of varying spatial resolution and biogeochemical complexity. To this end, 2-year simulations of the Chesapeake Bay from eight hydrodynamic-oxygen models have been statistically compared to each other and to historical monitoring data. Results show that although models have difficulty resolving the variables typically thought to be the main drivers of dissolved oxygen variability (stratification, nutrients, and chlorophyll), all eight models have significant skill in reproducing the mean and seasonal variability of dissolved oxygen. In addition, models with constant net respiration rates independent of nutrient supply and temperature reproduced observed dissolved oxygen concentrations about as well as much more complex, nutrient-dependent biogeochemical models. This finding has significant ramifications for short-term hypoxia forecasts in the Chesapeake Bay, which may be possible with very simple oxygen parameterizations, in contrast to the more complex full biogeochemical models required for scenario-based forecasting. However, models have difficulty simulating correct density and oxygen mixed layer depths, which are important ecologically in terms of habitat compression. Observations indicate a much stronger correlation between the depths of the top of the pycnocline and oxycline than between their maximum vertical gradients, highlighting the importance of the mixing depth in defining the region of aerobic habitat in the Chesapeake Bay when low-oxygen bottom waters are present. Improvement in hypoxia simulations will thus depend more on the ability of models to reproduce the correct mean and variability of the depth of the physically driven surface mixed layer than the precise magnitude of the vertical density gradient.http://www.biogeosciences.net/13/2011/2016/bg-13-2011-2016.pdf
collection DOAJ
language English
format Article
sources DOAJ
author I. D. Irby
M. A. M. Friedrichs
C. T. Friedrichs
A. J. Bever
R. R. Hood
L. W. J. Lanerolle
M. Li
L. Linker
M. E. Scully
K. Sellner
J. Shen
J. Testa
H. Wang
P. Wang
M. Xia
spellingShingle I. D. Irby
M. A. M. Friedrichs
C. T. Friedrichs
A. J. Bever
R. R. Hood
L. W. J. Lanerolle
M. Li
L. Linker
M. E. Scully
K. Sellner
J. Shen
J. Testa
H. Wang
P. Wang
M. Xia
Challenges associated with modeling low-oxygen waters in Chesapeake Bay: a multiple model comparison
Biogeosciences
author_facet I. D. Irby
M. A. M. Friedrichs
C. T. Friedrichs
A. J. Bever
R. R. Hood
L. W. J. Lanerolle
M. Li
L. Linker
M. E. Scully
K. Sellner
J. Shen
J. Testa
H. Wang
P. Wang
M. Xia
author_sort I. D. Irby
title Challenges associated with modeling low-oxygen waters in Chesapeake Bay: a multiple model comparison
title_short Challenges associated with modeling low-oxygen waters in Chesapeake Bay: a multiple model comparison
title_full Challenges associated with modeling low-oxygen waters in Chesapeake Bay: a multiple model comparison
title_fullStr Challenges associated with modeling low-oxygen waters in Chesapeake Bay: a multiple model comparison
title_full_unstemmed Challenges associated with modeling low-oxygen waters in Chesapeake Bay: a multiple model comparison
title_sort challenges associated with modeling low-oxygen waters in chesapeake bay: a multiple model comparison
publisher Copernicus Publications
series Biogeosciences
issn 1726-4170
1726-4189
publishDate 2016-04-01
description As three-dimensional (3-D) aquatic ecosystem models are used more frequently for operational water quality forecasts and ecological management decisions, it is important to understand the relative strengths and limitations of existing 3-D models of varying spatial resolution and biogeochemical complexity. To this end, 2-year simulations of the Chesapeake Bay from eight hydrodynamic-oxygen models have been statistically compared to each other and to historical monitoring data. Results show that although models have difficulty resolving the variables typically thought to be the main drivers of dissolved oxygen variability (stratification, nutrients, and chlorophyll), all eight models have significant skill in reproducing the mean and seasonal variability of dissolved oxygen. In addition, models with constant net respiration rates independent of nutrient supply and temperature reproduced observed dissolved oxygen concentrations about as well as much more complex, nutrient-dependent biogeochemical models. This finding has significant ramifications for short-term hypoxia forecasts in the Chesapeake Bay, which may be possible with very simple oxygen parameterizations, in contrast to the more complex full biogeochemical models required for scenario-based forecasting. However, models have difficulty simulating correct density and oxygen mixed layer depths, which are important ecologically in terms of habitat compression. Observations indicate a much stronger correlation between the depths of the top of the pycnocline and oxycline than between their maximum vertical gradients, highlighting the importance of the mixing depth in defining the region of aerobic habitat in the Chesapeake Bay when low-oxygen bottom waters are present. Improvement in hypoxia simulations will thus depend more on the ability of models to reproduce the correct mean and variability of the depth of the physically driven surface mixed layer than the precise magnitude of the vertical density gradient.
url http://www.biogeosciences.net/13/2011/2016/bg-13-2011-2016.pdf
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