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Main Author: Lester, Daniel
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2506.20387
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author Lester, Daniel
author_facet Lester, Daniel
contents We consider the general problem of mixing of Gaussian solute plumes arising across a range of different flows ranging from two-dimensional (2D) to three-dimensional (3D), steady to unsteady, regular to chaotic, Stokes to turbulent. We consider a a range of infinitesimal injection protocols (point or line sources, continuous or pulsed) which generate solute points, lines and sheets and their finite-sized counterparts (blobs, tubes and slabs). We show that evolution of this broad family of Gaussian plumes is solely governed by the initial solute distribution, the dispersion tensor and the Lagrangian history of the deformation gradient tensor. Significant simplifications arise when the deformation tensor is placed in the Protean (Lester et al, JFM, 2018) coordinate frame (which aligns with the maximum and minimum fluid stretching directions and renders the deformation tensor upper triangular), allowing evolution of the Gaussian covariance matrix to be expressed in physically relevant terms such as Lyapunov exponents, longitudinal and transverse shear rates. We couch these results in terms of evolution of the maximum concentration and scalar entropy of Gaussian plume for a range of flows and injection protocols. These results provide significant insights into the processes that govern mixing in a broad range of flows and provide the building blocks of efficient numerical methods using e.g. radial basis functions for solute transport and mixing in arbitrary flows.
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spellingShingle Mixing of Gaussian Solute Plumes
Lester, Daniel
Fluid Dynamics
We consider the general problem of mixing of Gaussian solute plumes arising across a range of different flows ranging from two-dimensional (2D) to three-dimensional (3D), steady to unsteady, regular to chaotic, Stokes to turbulent. We consider a a range of infinitesimal injection protocols (point or line sources, continuous or pulsed) which generate solute points, lines and sheets and their finite-sized counterparts (blobs, tubes and slabs). We show that evolution of this broad family of Gaussian plumes is solely governed by the initial solute distribution, the dispersion tensor and the Lagrangian history of the deformation gradient tensor. Significant simplifications arise when the deformation tensor is placed in the Protean (Lester et al, JFM, 2018) coordinate frame (which aligns with the maximum and minimum fluid stretching directions and renders the deformation tensor upper triangular), allowing evolution of the Gaussian covariance matrix to be expressed in physically relevant terms such as Lyapunov exponents, longitudinal and transverse shear rates. We couch these results in terms of evolution of the maximum concentration and scalar entropy of Gaussian plume for a range of flows and injection protocols. These results provide significant insights into the processes that govern mixing in a broad range of flows and provide the building blocks of efficient numerical methods using e.g. radial basis functions for solute transport and mixing in arbitrary flows.
title Mixing of Gaussian Solute Plumes
topic Fluid Dynamics
url https://arxiv.org/abs/2506.20387