Simulations of environmental conditions conducive to formation of lake-to-lake bands
Joanna T. George, South Dakota School of Mines and Technology, Rapid City, SD; and M. R. Hjelmfelt, W. J. Capehart, and D. A. R. Kristovich
Lake-effect snow has a large influence on the Great Lakes region, often enhancing snowfall downwind of the lakes. Several different types of lake-effect bands exist, but environmental conditions conducive to lake-to-lake (L2L) bands, bands that extend from one lake across intervening land and a downwind lake, are perhaps the least understood. The purpose of this study is to determine the environmental conditions that lead to the development of L2L bands. The Weather and Research Forecasting-Advanced Research WRF (WRF-ARW) Version 2.2 model is used to simulate and compare two cases of cold air outbreaks over the western Great Lakes. The case of 02 December 2003 produced L2L bands while the case of 15 February 2007 started with broken lake-effect band production and then converted into a L2L band case. Sensitivity studies are also conducted to understand the importance of the lakes and surrounding terrain on the L2L bands. The sensitivity simulations involve both an increase and a decrease of 5°K in the lake surface temperatures, as well as a change in the surface roughness length of the land surrounding the western Great Lakes. Satellite imagery and surface and upper air analyses are utilized for comparison with model output.
Examination of model output reveal that the two cases were accurately simulated by the model. For the December case, the northwesterly flow of air over Lake Superior created superadiabatic lapse rates over the water surfaces with mixing continuing over land surfaces. Only a slight decrease in boundary layer depth occurred as air passed over the Upper Peninsula of Michigan. With the lake surface temperatures increased by 5°K, the well-mixed boundary layer and cloud bands expanded in depth and more lake-effect band formation occurred to the south as more heat and moisture became available from the lake surface. The opposite effect happened when the lake surface temperatures were decreased by 5°K; a reduction in bands over land masses was apparent. The February case showed similar boundary layer conditions to the December case initially. However, when the lake surface temperatures were increased by 5°K, the bands and boundary layer remained very similar to the base simulation as surface air temperatures were already significantly colder than the lake. The decrease in 5°K again produced thinner cloud and boundary layers. For both events, the change in land-surface roughness length produced no variations in the simulations.
Overall, inversion heights were comparable with time between the two cases. Lake surface-850 hPa temperature differences were typically higher for the February simulations, but L2L bands were generally observed to form between 15°C and 24°C when comparing all of the simulations. Wind speeds appear to affect L2L band formation the most in this study, as wind speeds during the start of L2L convection were approximately 15 m s-1 in both events. Lake surface to 2-m land-surface air temperature differences are also presented for each of the simulations.
Extended Abstract (3.0M)
Poster Session 2, Poster session II
Wednesday, 19 August 2009, 2:30 PM-4:00 PM, Arches/Deer Valley
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