Skip to main content

Aerodynamic resistance parameterization for heterogeneous surfaces using a covariance function approach in spectral space

Publication ,  Journal Article
Kröniger, K; Katul, GG; de Roo, F; Brugger, P; Mauder, M
Published in: Journal of the Atmospheric Sciences
January 1, 2019

Simulating the influence of heterogeneous surfaces on atmospheric flow using mesoscale models (MSM) remains a challenging task, as the resolution of these models usually prohibits resolving important scales of surface heterogeneity. However, surface heterogeneity impacts fluxes of momentum, heat, or moisture, which act as lower boundary conditions for MSM. Even though several approaches for representing subgrid-scale heterogeneities in MSM exist, many of these approaches rely on Monin–Obukhov similarity theory, preventing those models from resolving all scales of surface heterogeneity. To improve upon these residual heterogeneity scales, a novel heterogeneity parameterization is derived by linking the heterogeneous covariance function in spectral space to an associated homogeneous one. This covariance function approach is subsequently used to derive a parameterization of the aerodynamic resistance to heat transfer of the surface layer. Here, the effect of surface heterogeneity enters as a factor applied to the stability correction functions of the bulk similarity approach. To perform a first comparison of the covariance function approach against the conventional bulk similarity and tile approaches, large-eddy simulations (LESs) of distinct surface heterogeneities are conducted. The aerodynamic resistances from these three parameterizations are subsequently tested against the LES reference by resolving the surface heterogeneities with six different test-MSM grids of varying cell dimension. The results of these comparisons show that the covariance function approach proposed here yields the smallest deviations from the LES reference. In addition, the smallest deviation of the covariance function approach to the reference is observed for the LES with the largest surface heterogeneity, which illustrates the advantage of this novel parameterization.

Duke Scholars

Published In

Journal of the Atmospheric Sciences

DOI

EISSN

1520-0469

ISSN

0022-4928

Publication Date

January 1, 2019

Volume

76

Issue

10

Start / End Page

3191

Related Subject Headings

  • Meteorology & Atmospheric Sciences
  • 3701 Atmospheric sciences
  • 0401 Atmospheric Sciences
 

Citation

APA
Chicago
ICMJE
MLA
NLM
Kröniger, K., Katul, G. G., de Roo, F., Brugger, P., & Mauder, M. (2019). Aerodynamic resistance parameterization for heterogeneous surfaces using a covariance function approach in spectral space. Journal of the Atmospheric Sciences, 76(10), 3191. https://doi.org/10.1175/JAS-D-18-0150.1
Kröniger, K., G. G. Katul, F. de Roo, P. Brugger, and M. Mauder. “Aerodynamic resistance parameterization for heterogeneous surfaces using a covariance function approach in spectral space.” Journal of the Atmospheric Sciences 76, no. 10 (January 1, 2019): 3191. https://doi.org/10.1175/JAS-D-18-0150.1.
Kröniger K, Katul GG, de Roo F, Brugger P, Mauder M. Aerodynamic resistance parameterization for heterogeneous surfaces using a covariance function approach in spectral space. Journal of the Atmospheric Sciences. 2019 Jan 1;76(10):3191.
Kröniger, K., et al. “Aerodynamic resistance parameterization for heterogeneous surfaces using a covariance function approach in spectral space.” Journal of the Atmospheric Sciences, vol. 76, no. 10, Jan. 2019, p. 3191. Scopus, doi:10.1175/JAS-D-18-0150.1.
Kröniger K, Katul GG, de Roo F, Brugger P, Mauder M. Aerodynamic resistance parameterization for heterogeneous surfaces using a covariance function approach in spectral space. Journal of the Atmospheric Sciences. 2019 Jan 1;76(10):3191.

Published In

Journal of the Atmospheric Sciences

DOI

EISSN

1520-0469

ISSN

0022-4928

Publication Date

January 1, 2019

Volume

76

Issue

10

Start / End Page

3191

Related Subject Headings

  • Meteorology & Atmospheric Sciences
  • 3701 Atmospheric sciences
  • 0401 Atmospheric Sciences