A methodology to characterize the energy transfer and inter-scale transport of coherent structures using mode decomposition

TL;DR

This paper introduces a new mode decomposition-based methodology to quantify energy transfer and transport across scales of coherent structures in turbulent flows, demonstrated on a wake behind a square cylinder.

Contribution

It develops a spectral mode decomposition approach to identify scale-specific energy transfer and transport in coherent structures, advancing understanding of multi-scale flow dynamics.

Findings

Energy initially in the near wake transfers to higher harmonics.

Inter-scale transfer is homogeneous in the far wake.

Transport and dissipation are dominated by large scales.

Abstract

A methodology is developed to quantify the transfer and transport of kinetic energy of specific scales associated with coherent structures. Coherent motions are characterized by the triple decomposition of a multi-scale flow and used to define mean, coherent, and random kinetic energy. Specific scales of individual coherent structures are identified through mode decomposition, whereby the total coherent velocity is separated into a set of velocities classified by the scale of the mode based on frequency to embed spectral characteristics. The set of scale-specific coherent velocities are used to identify scale-specific coherent kinetic energy, which quantifies the kinetic energy of a specific scale, and an equation for the balance of scale-specific coherent kinetic energy. Each equation includes terms with velocity triads, which represent the inter-scale transfer. The methodology is assessed in the wake behind a square cylinder, where scales of the flow are related to the vortex shedding. The scale-specific inter-scale transfer identifies that kinetic energy initially in the near wake is transferred from vortex shedding to scales associated with higher harmonics of the vortex shedding. In the far wake, inter-scale transfer is homogeneous and transfer occurs over many frequencies. While the inter-scale transfer is identified over a range of scales, the scale-specific transport, convection, and dissipation of coherent kinetic energy are associated with only the largest, dominant scales. The wake flow is subjected to unsteady inflow at various frequencies to identify the changes to inter-scale transfer and coherent kinetic energy induced by other frequencies.