Power-law scaling of asymmetries in viscous flow with PT-symmetric inflow and outflow

TL;DR

This study explores how viscous flow asymmetries in PT-symmetric inflow-outflow configurations follow power-law scaling with Reynolds number, revealing potential for flow control in fluid dynamics.

Contribution

The paper introduces a numerical analysis of flow asymmetries in viscous fluids with PT-symmetric boundary conditions, uncovering a universal power-law scaling across a wide Reynolds number range.

Findings

Flow asymmetries scale with Reynolds number via a single power-law exponent.

Scaling behavior is robust even at high Reynolds numbers.

PT-symmetric configurations offer new ways to tune flow properties.

Abstract

In recent years, open systems with balanced loss and gain, that are invariant under the combined parity and time-reversal ($\mathcal{PT}$) operations, have been studied via asymmetries of their solutions. They represent systems as diverse as coupled optical waveguides and electrical or mechanical oscillators. We numerically investigate the asymmetries of incompressible viscous flow in two and three dimensions with "balanced" inflow-outflow ($\mathcal{PT}$-symmetric) configurations. By introducing configuration-dependent classes of asymmetry functions in velocity, kinetic energy density, and vorticity fields, we find that the flow asymmetries exhibit power-law scaling with a single exponent in the laminar regime with the Reynolds number ranging over four decades. We show that such single-exponent scaling is expected for small Reynolds numbers, although its robustness at large values of Reynolds numbers is unexpected. Our results imply that $\mathcal{PT}$-symmetric inflow-outflow configurations provide a hitherto unexplored avenue to tune flow properties.