Role of critical points of the skin friction field in formation of plumes in thermal convection

TL;DR

This paper investigates how critical points in the skin friction field influence plume formation in thermal convection, revealing triplet structures and their relation to thermal plumes through numerical simulations.

Contribution

It identifies triplet critical points as fundamental structures in the skin friction field and links them to thermal plume formation in Rayleigh-Bénard convection.

Findings

Triplet critical points are key in skin friction field structure.

Most thermal plume ridges align with unstable manifolds of saddles.

Thermal plumes are associated with hyperbolic Lagrangian Coherent Structures.

Abstract

The dynamics in the thin boundary layers of temperature and velocity is the key to a deeper understanding of turbulent transport of heat and momentum in thermal convection. The velocity gradient at the hot and cold plates of a Rayleigh-B\'{e}nard convection cell forms the two-dimensional skin friction field and is related to the formation of thermal plumes in the respective boundary layers. Our analysis is based on a direct numerical simulation of Rayleigh-B\'{e}nard convection in a closed cylindrical cell of aspect ratio $\Gamma=1$ and focused on the critical points of the skin friction field. We identify triplets of critical points, which are composed of two unstable nodes and a saddle between them, as the characteristic building block of the skin friction field. Isolated triplets as well as networks of triplets are detected. The majority of the ridges of line-like thermal plumes coincide with the unstable manifolds of the saddles. From a dynamical Lagrangian perspective, thermal plumes are formed together with an attractive hyperbolic Lagrangian Coherent Structure of the skin friction field. We also discuss the differences from the skin friction field in turbulent channel flows from the perspective of the Poincar\'{e}-Hopf index theorem for two-dimensional vector fields.