Your search keyword '"Beletsky, Dmitry"' showing total 2 results

1. Modeling a Large Coastal Upwelling Event in Lake Superior.

Author

Li, Yaru, Beletsky, Dmitry, Wang, Jia, Austin, Jay, Kessler, James, Fujisaki‐Manome, Ayumi, and Bai, Peng

Subjects

UPWELLING (Oceanography), OCEAN circulation, OCEAN wave power, OCEANOGRAPHIC observations

Abstract

An extraordinary strong wind‐driven upwelling event occurred in Lake Superior in summer of 2010 when the lake was strongly stratified. In this paper, a detailed three‐dimensional (3‐D) investigation of the current and thermal structures during the upwelling event was conducted using in situ observations, remote sensing products, and the results of a long‐term numerical simulation. A 3‐D finite‐volume coupled ice–ocean model tailored for the Laurentian Great Lakes was employed for this purpose. The model was validated with temperature observations at National Oceanic and Atmospheric Administration buoys and mooring data from 2010. The upwelling event observed in satellite imagery and at a mooring station was reproduced by the model, showing a cooling of as much as 10°C in August 2010 along the northwestern coast. The relationship between the alongshore wind and the offshore thermocline displacement (upwelling front) derived in theoretical work (Csanady, 1977, https://doi.org/10.1029/JC082i003p00397) was used to calculate upwelling front movement offshore and found to be in in close agreement with model prediction. A significant correlation between alongshore wind stress and lake temperature change in the upwelling zone was found with a correlation coefficient of −0.87. A simple linear heat balance model explained most of variability in temperature. Plain Language Summary: An extraordinary strong upwelling event observed during summer 2010 in Lake Superior was reproduced by a numerical ocean model. A detailed three‐dimensional (3‐D) investigation of the current and thermal structures during the upwelling event was conducted using in situ observations, remote sensing products, and the results of a long‐term numerical simulation. A 4‐day long strong, persistent alongshore wind was the major driving force of this event. A significant correlation between alongshore wind stress and lake temperature change in the upwelling zone was found. A simple linear heat balance model explained most of variability in temperature measurements. The relationship between the alongshore wind and the offshore displacement of the upwelling front derived in theoretical work was used to calculate upwelling front movement offshore and found to be in in close agreement with model prediction. Key Points: An extraordinarily strong upwelling event observed during summer 2010 in Lake Superior was reproduced by a coupled ice–ocean modelStrong correlation between lake surface temperature change in the upwelling zone and alongshore wind stress was found (with a correlation coefficient of −0.87); a simple linear heat balance model explained most of time rate of change in temperatureOffshore thermocline displacement (upwelling front) in the model was in good agreement with predictions of an analytical model that employed alongshore wind and initial thermal structure [ABSTRACT FROM AUTHOR]

Published

2021

2. Improving Flood Forecast Guidance for Ports in the Great Lakes Using a Linked Hydrologic-Hydrodynamic Framework.

Author

Fitzpatrick, Lindsay, Titze, Dan, Beletsky, Dmitry, Anderson, Eric J., and Kelley, John G. W.

Subjects

GREAT Lakes (North America), UNITED States. National Oceanic & Atmospheric Administration

Abstract

The NOAA Great Lakes Operational Forecast System (GLOFS), based on the Finite-Volume Community Ocean Model (FVCOM), provides water forecast guidance across the Great Lakes, however, it does not include harbors and navigational ports. While GLOFS does include inflow from some gauged streams, large volumes of water entering the lakes through tributaries are not being accounted for. To examine the benefits of including model coverage over marine infrastructures, a linked hydrologic-hydrodynamic framework was developed for the Twin Ports of Duluth-Superior in western Lake Superior. Simulated streamflow from the National Water Model (NWM) was injected into an extended wet-dry FVCOM grid that covered the harbor and surrounding floodplain. Test cases were conducted for severe flooding events caused by heavy rainfall and/or storm surges to see if the one-way coupled models could capture coastal flooding. Model results compared well against time-series of water level, with root mean square error (RMSE) and bias values small relative to the typical fluctuations. Inclusion of streamflow for NWM-simulated tributaries improved the accuracy of modeled water levels in the harbor and increased simulated current speeds in navigational channels by up to 0.4 ms-1. Modeled inundation and flood extent in the floodplain closely matched surveys conducted in response to a record flood event in 2012. The results demonstrate the capability of the modeling framework to provide flood guidance in a complex coastal setting in the Great Lakes region. [ABSTRACT FROM AUTHOR]

Published

2023