Solitary wave structure of transitional flow in the wake of a sphere

TL;DR

This study investigates the formation and evolution of soliton-like coherent structures in the transitional wake flow behind a sphere across different Reynolds numbers using numerical simulations.

Contribution

It provides detailed insights into the development, shape conservation, and relationship of SCS with vortex and shear structures during flow transition.

Findings

SCS appears as a wave packet during T-S wave stage at early transition.

Maximum SCS amplitude occurs downstream after T-S wave breakdown.

SCS shape and amplitude are conserved over long downstream distances.

Abstract

The soliton-like coherent structure (SCS), which has been verified to exist in both transitional and turbulent boundary layers1-4, still poses a challenge in the understanding of its formation and behavior. In our previous study (Niu et al.5), the SCS was also found to exist in the transitional wake flow behind a sphere. In present study, the formation and evolution of the SCS is further investigated at four Reynolds numbers by numerical simulation. The results show that at the early stage of the turbulence transition, the SCS appears as a form of wave packet during the Tollmien-Schlichting (T-S) wave stage. With the increase of the Reynolds number, the SCS reaches its maximum amplitude downstream where the velocity discontinuity occurs. This position is located after the breakdown of the T-S wave and the three-dimensional structure is formed. Then, the SCS conserves its shape and amplitude over a long distance downstream. The relationships among the SCS, the spikes, the vortex structures, and the high-shear layers are further analyzed. It is found that the SCS in the wake flow has similarities to the phenomena observed in boundary layer flows during the turbulent transition. The vortex structures and high-shear layers mostly wrap around the border of the SCS. The vortex structure is considered to be as a consequence of the development of the SCS rather than its cause.