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Scalewise invariant analysis of the anisotropic Reynolds stress tensor for atmospheric surface layer and canopy sublayer turbulent flows

Publication ,  Journal Article
Brugger, P; Katul, GG; De Roo, F; KröNiger, K; Rotenberg, E; Rohatyn, S; Mauder, M
Published in: Physical Review Fluids
May 1, 2018

Anisotropy in the turbulent stress tensor, which forms the basis of invariant analysis, is conducted using velocity time series measurements collected in the canopy sublayer (CSL) and the atmospheric surface layer (ASL). The goal is to assess how thermal stratification and surface roughness conditions simultaneously distort the scalewise relaxation towards isotropic state from large to small scales when referenced to homogeneous turbulence. To achieve this goal, conventional invariant analysis is extended to allow scalewise information about relaxation to isotropy in physical (instead of Fourier) space to be incorporated. The proposed analysis shows that the CSL is more isotropic than its ASL counterpart at large, intermediate, and small (or inertial) scales irrespective of the thermal stratification. Moreover, the small (or inertial) scale anisotropy is more prevalent in the ASL when compared to the CSL, a finding that cannot be fully explained by the intensity of the mean velocity gradient acting on all scales. Implications to the validity of scalewise Rotta and Lumley models for return to isotropy as well as advantages to using barycentric instead of anisotropy invariant maps for such scalewise analysis are discussed.

Duke Scholars

Published In

Physical Review Fluids

DOI

EISSN

2469-990X

Publication Date

May 1, 2018

Volume

3

Issue

5

Related Subject Headings

  • 4012 Fluid mechanics and thermal engineering
  • 0913 Mechanical Engineering
  • 0203 Classical Physics
  • 0102 Applied Mathematics
 

Citation

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Brugger, P., Katul, G. G., De Roo, F., KröNiger, K., Rotenberg, E., Rohatyn, S., & Mauder, M. (2018). Scalewise invariant analysis of the anisotropic Reynolds stress tensor for atmospheric surface layer and canopy sublayer turbulent flows. Physical Review Fluids, 3(5). https://doi.org/10.1103/PhysRevFluids.3.054608
Brugger, P., G. G. Katul, F. De Roo, K. KröNiger, E. Rotenberg, S. Rohatyn, and M. Mauder. “Scalewise invariant analysis of the anisotropic Reynolds stress tensor for atmospheric surface layer and canopy sublayer turbulent flows.” Physical Review Fluids 3, no. 5 (May 1, 2018). https://doi.org/10.1103/PhysRevFluids.3.054608.
Brugger P, Katul GG, De Roo F, KröNiger K, Rotenberg E, Rohatyn S, et al. Scalewise invariant analysis of the anisotropic Reynolds stress tensor for atmospheric surface layer and canopy sublayer turbulent flows. Physical Review Fluids. 2018 May 1;3(5).
Brugger, P., et al. “Scalewise invariant analysis of the anisotropic Reynolds stress tensor for atmospheric surface layer and canopy sublayer turbulent flows.” Physical Review Fluids, vol. 3, no. 5, May 2018. Scopus, doi:10.1103/PhysRevFluids.3.054608.
Brugger P, Katul GG, De Roo F, KröNiger K, Rotenberg E, Rohatyn S, Mauder M. Scalewise invariant analysis of the anisotropic Reynolds stress tensor for atmospheric surface layer and canopy sublayer turbulent flows. Physical Review Fluids. 2018 May 1;3(5).

Published In

Physical Review Fluids

DOI

EISSN

2469-990X

Publication Date

May 1, 2018

Volume

3

Issue

5

Related Subject Headings

  • 4012 Fluid mechanics and thermal engineering
  • 0913 Mechanical Engineering
  • 0203 Classical Physics
  • 0102 Applied Mathematics