Transport of inertial spherical particles in compressible turbulent boundary layers

Abstract: In the present study, we perform direct numerical simulations of compressible turbulent boundary layers at the free stream Mach number of 2 ~ 6 laden with dilute phase of spherical particles to investigate the Mach number effects on particle transport and dynamics. Most of the phenomena observed and well-recognized for inertia particles in incompressible wall-bounded turbulent flows, such as the near-wall preferential accumulation and clustering beneath the low-speed streaks, the flatter mean velocity profiles and the trend variation of the particle velocity fluctuations, are identified in the compressible turbulent boundary layer as well. However, we find that the compressibility effects are significant for large inertia particles. As the Mach number increases, the near-wall accumulation and the small-scale clustering are alleviated, which is probably caused by the variation of the fluid density and viscosity that are crucial to particle dynamics. This can be affected by the fact that the forces acting on the particles with the viscous Stokes number greater than 500 are modulated by the comparatively high particle Mach numbers in the near-wall region. This is also the reason for the abatement of the streamwise particle velocity fluctuation intensities with the Mach numbers.