Evaluating and improving modeled turbulent heat fluxes across the North American Great Lakes
<p>Turbulent fluxes of latent and sensible heat are important physical processes that influence the energy and water budgets of the North American Great Lakes. These fluxes can be measured in situ using eddy covariance techniques and are regularly included as a component of lake–atmosphere...
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Copernicus Publications
2018-10-01
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| Series: | Hydrology and Earth System Sciences |
| Online Access: | https://www.hydrol-earth-syst-sci.net/22/5559/2018/hess-22-5559-2018.pdf |
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doaj-2eab3df2a88e491784819a67ff82812f2020-11-24T23:06:00ZengCopernicus PublicationsHydrology and Earth System Sciences1027-56061607-79382018-10-01225559557810.5194/hess-22-5559-2018Evaluating and improving modeled turbulent heat fluxes across the North American Great LakesU. Charusombat0A. Fujisaki-Manome1A. Fujisaki-Manome2A. D. Gronewold3B. M. Lofgren4E. J. Anderson5P. D. Blanken6C. Spence7J. D. Lenters8C. Xiao9L. E. Fitzpatrick10G. Cutrell11NOAA Great Lakes Environmental Research Laboratory, Ann Arbor, Michigan 48108, USAUniversity of Michigan, Cooperative Institute for Great Lakes Research, Ann Arbor, Michigan 48108, USAUniversity of Michigan, Climate & Space Sciences and Engineering Department, Ann Arbor, Michigan 48109, USANOAA Great Lakes Environmental Research Laboratory, Ann Arbor, Michigan 48108, USANOAA Great Lakes Environmental Research Laboratory, Ann Arbor, Michigan 48108, USANOAA Great Lakes Environmental Research Laboratory, Ann Arbor, Michigan 48108, USAUniversity of Colorado, Department of Geography, Boulder, Colorado 80309, USAEnvironment and Climate Change Canada, Saskatoon, Saskatchewan, S7N 5C5, CanadaUniversity of Wisconsin-Madison, Center for Limnology, Boulder Junction, Wisconsin 54512, USAUniversity of Michigan, Cooperative Institute for Great Lakes Research, Ann Arbor, Michigan 48108, USAUniversity of Michigan, Cooperative Institute for Great Lakes Research, Ann Arbor, Michigan 48108, USALimnoTech, Ann Arbor, Michigan 48108, USA<p>Turbulent fluxes of latent and sensible heat are important physical processes that influence the energy and water budgets of the North American Great Lakes. These fluxes can be measured in situ using eddy covariance techniques and are regularly included as a component of lake–atmosphere models. To help ensure accurate projections of lake temperature, circulation, and regional meteorology, we validated the output of five algorithms used in three popular models to calculate surface heat fluxes: the Finite Volume Community Ocean Model (FVCOM, with three different options for heat flux algorithm), the Weather Research and Forecasting (WRF) model, and the Large Lake Thermodynamic Model. These models are used in research and operational environments and concentrate on different aspects of the Great Lakes' physical system. We isolated only the code for the heat flux algorithms from each model and drove them using meteorological data from four over-lake stations within the Great Lakes Evaporation Network (GLEN), where eddy covariance measurements were also made, enabling co-located comparison. All algorithms reasonably reproduced the seasonal cycle of the turbulent heat fluxes, but all of the algorithms except for the Coupled Ocean–Atmosphere Response Experiment (COARE) algorithm showed notable overestimation of the fluxes in fall and winter. Overall, COARE had the best agreement with eddy covariance measurements. The four algorithms other than COARE were altered by updating the parameterization of roughness length scales for air temperature and humidity to match those used in COARE, yielding improved agreement between modeled and observed sensible and latent heat fluxes.</p>https://www.hydrol-earth-syst-sci.net/22/5559/2018/hess-22-5559-2018.pdf |
| collection |
DOAJ |
| language |
English |
| format |
Article |
| sources |
DOAJ |
| author |
U. Charusombat A. Fujisaki-Manome A. Fujisaki-Manome A. D. Gronewold B. M. Lofgren E. J. Anderson P. D. Blanken C. Spence J. D. Lenters C. Xiao L. E. Fitzpatrick G. Cutrell |
| spellingShingle |
U. Charusombat A. Fujisaki-Manome A. Fujisaki-Manome A. D. Gronewold B. M. Lofgren E. J. Anderson P. D. Blanken C. Spence J. D. Lenters C. Xiao L. E. Fitzpatrick G. Cutrell Evaluating and improving modeled turbulent heat fluxes across the North American Great Lakes Hydrology and Earth System Sciences |
| author_facet |
U. Charusombat A. Fujisaki-Manome A. Fujisaki-Manome A. D. Gronewold B. M. Lofgren E. J. Anderson P. D. Blanken C. Spence J. D. Lenters C. Xiao L. E. Fitzpatrick G. Cutrell |
| author_sort |
U. Charusombat |
| title |
Evaluating and improving modeled turbulent heat fluxes across the North American Great Lakes |
| title_short |
Evaluating and improving modeled turbulent heat fluxes across the North American Great Lakes |
| title_full |
Evaluating and improving modeled turbulent heat fluxes across the North American Great Lakes |
| title_fullStr |
Evaluating and improving modeled turbulent heat fluxes across the North American Great Lakes |
| title_full_unstemmed |
Evaluating and improving modeled turbulent heat fluxes across the North American Great Lakes |
| title_sort |
evaluating and improving modeled turbulent heat fluxes across the north american great lakes |
| publisher |
Copernicus Publications |
| series |
Hydrology and Earth System Sciences |
| issn |
1027-5606 1607-7938 |
| publishDate |
2018-10-01 |
| description |
<p>Turbulent fluxes of latent and sensible heat are important physical processes
that influence the energy and water budgets of the North American Great
Lakes. These fluxes can be measured in situ using eddy covariance techniques
and are regularly included as a component of lake–atmosphere models. To help
ensure accurate projections of lake temperature, circulation, and regional
meteorology, we validated the output of five algorithms used in three popular
models to calculate surface heat fluxes: the Finite Volume Community Ocean
Model (FVCOM, with three different options for heat flux algorithm), the
Weather Research and Forecasting (WRF) model, and the Large Lake
Thermodynamic Model. These models are used in research and operational
environments and concentrate on different aspects of the Great Lakes'
physical system. We isolated only the code for the heat flux algorithms from
each model and drove them using meteorological data from four over-lake
stations within the Great Lakes Evaporation Network (GLEN), where eddy
covariance measurements were also made, enabling co-located comparison. All
algorithms reasonably reproduced the seasonal cycle of the turbulent heat
fluxes, but all of the algorithms except for the Coupled Ocean–Atmosphere
Response Experiment (COARE) algorithm showed notable overestimation of the
fluxes in fall and winter. Overall, COARE had the best agreement with eddy
covariance measurements. The four algorithms other than COARE were altered by
updating the parameterization of roughness length scales for air temperature
and humidity to match those used in COARE, yielding improved agreement
between modeled and observed sensible and latent heat fluxes.</p> |
| url |
https://www.hydrol-earth-syst-sci.net/22/5559/2018/hess-22-5559-2018.pdf |
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