Mesoscale Modeling

Graduate students and post-docs from my research group are identified by * and + signs, respectively.

[12] Li*, B., Basu, S., Watson, S. J., and Russchenberg, H. W. J. (2021). "Mesoscale modeling of a `Dunkelflaute' event", Wind Energy, 24, 5-23.

Li*, B., Basu, S., Watson, S. J., and Russchenberg, H. W. J. (2020). "Quantifying the predictability of a `Dunkelflaute' event by utilizing a mesoscale model", Journal of Physics: Conference Series, 1618, 062042, doi: 10.1088/1742-6596/1618/6/062042.

[11] Basu, S., Osborn, J., He, P., and DeMarco, A. W. (2020). "Mesoscale modeling of optical turbulence in the atmosphere: The need for ultrahigh vertical grid resolution", Monthly Notices of the Royal Astronomical Society, 497, 2302-2308.

[10] Durán, P., Basu, S., Meißner, C., and Adaramola, M. S. (2019). "Automated classification of simulated wind field patterns from multi-physics ensemble forecasts". Wind Energy, doi: 10.1002/we.2462.

[9] Hawbecker*, P., Basu, S., and Manuel, L. (2017). "Realistic simulations of the July 1, 2011 severe wind event over the Buffalo Ridge Wind Farm", Wind Energy, 20(11), 1803-1822.

[8] Basu, S. (2017). "Simulating an extreme over-the-horizon optical propagation event over lake Michigan using a coupled mesoscale modeling and ray tracing framework", Optical Engineering (Special Issue: Long-Range Imaging), 56, 071505.

[7] He⁺, P., Nunalee*, C. G., Basu, S., Minet, J., Vorontsov, M. A., and Fiorino, S. T. (2015). "Influence of heterogeneous refractivity on optical wave propagation in coastal environments", Meteorology and Atmospheric Physics, 127(6), 685-699.

[6] Nunalee*, C. G., Horvath, A., and Basu, S. (2015). "High resolution numerical modeling of mesoscale island wakes and sensitivity to static topographic relief data", Geoscientific Model Development, 8, 2645-2653.

[5] Nunalee*, C. G., He⁺, P., Basu, S., Minet, J., and Vorontsov, M. A. (2015). "Mapping optical ray trajectories through island wake vortices", Meteorology and Atmospheric Physics, 127(3), 355-368.

Nunalee*, C. G., He⁺, P., Basu, S., Vorontsov, M. A., and Fiorino, S. T. (2014). "Impact of large-scale atmospheric refractive structures on optical wave propagation", Proceedings of SPIE Optics & Photonics, doi: 10.1117/12.2063022.

Basu, S., Nunalee*, C. G., He⁺, P., Fiorino, S. T. and Vorontsov, M. A. (2014). "Reconstructing the prevailing meteorological and optical environment during the time of the Titanic disaster", Proceedings of SPIE Optics & Photonics, doi: 10.1117/12.2063195.

Nunalee*, C. G., and Basu, S. (2014). "Mesoscale modeling of low-level jets over the North Sea", WindEnergy - Impact of Turbulence: Proceedings of the Euromech Colloquium, edited by Michael Hölling, Joachim Pienke and Stefan Ivanell, Springer, pages: 197-202.

[4] Nunalee*, C. G., and Basu, S. (2014). "On the periodicity of atmospheric von Karman vortex streets", Environmental Fluid Mechanics, 14(6), 1335-1355.

[3] Nunalee*, C. G., and Basu, S. (2013). "Mesoscale modeling of coastal low-level jets: Implications for offshore wind resource estimation", Wind Energy, 17(8), 1199-1216.

[2] Storm*, B. and Basu, S. (2010). "The WRF model forecast-derived low-level wind shear climatology over the United States Great Plains", Energies (invited paper), 3, 258-276.

[1] Storm*, B., Dudhia, J., Basu, S., Swift, A., and Giammanco, I. (2008). "Evaluation of the Weather Research and Forecasting (WRF) model on forecasting low-level jets: Implications for wind energy", Wind Energy. 12(1), 81-90.