Turbulence collapse in a suction boundary layer

Khapko T, Schlatter P, Duguet Y, Henningson DS (2016)

Publication Type: Journal article

Publication year: 2016

Journal

Journal of Fluid Mechanics Cambridge University Press (CUP)

Book Volume: 795

Pages Range: 356-379

DOI: 10.1017/jfm.2016.205

Abstract

Turbulence in the asymptotic suction boundary layer is investigated numerically at the verge of laminarisation using direct numerical simulation. Following an adiabatic protocol, the Reynolds number Re is decreased in small steps starting from a fully turbulent state until laminarisation is observed. Computations in a large numerical domain allow in principle for the possible coexistence of laminar and turbulent regions. However, contrary to other subcritical shear flows, no laminar-turbulent coexistence is observed, even near the onset of sustained turbulence. High-resolution computations suggest a critical Reynolds number Reg ∼ 270, below which turbulence collapses, based on observation times of O(105) inertial time units. During the laminarisation process, the turbulent flow fragments into a series of transient streamwise-elongated structures, whose interfaces do not display the characteristic obliqueness of classical laminar-turbulent patterns. The law of the wall, i.e. logarithmic scaling of the velocity profile, is retained down to Reg, suggesting a large-scale wall-normal transport absent in internal shear flows close to the onset. In order to test the effect of these large-scale structures on the near-wall region, an artificial volume force is added to damp spanwise and wall-normal fluctuations above y+ = 100, in viscous units. Once the largest eddies have been suppressed by the forcing, and thus turbulence is confined to the near-wall region, oblique laminar-turbulent interfaces do emerge as in other wall-bounded flows, however only transiently. These results suggest that oblique stripes at the onset are a prevalent feature of internal shear flows, but will not occur in canonical boundary layers, including the spatially growing ones.

Authors with CRIS profile

Philipp Schlatter

Involved external institutions

Royal Institute of Technology / Kungliga Tekniska Högskolan (KTH) SE Sweden (SE) École Polytechnique - Université Paris-Saclay FR France (FR)

How to cite

APA:

Khapko, T., Schlatter, P., Duguet, Y., & Henningson, D.S. (2016). Turbulence collapse in a suction boundary layer. Journal of Fluid Mechanics, 795, 356-379. https://doi.org/10.1017/jfm.2016.205

MLA:

Khapko, T., et al. "Turbulence collapse in a suction boundary layer." Journal of Fluid Mechanics 795 (2016): 356-379.

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