Saved in:
Bibliographic Details
Main Authors: Leonelli, Alexandre D., Widmer, Lukas, Meiburg, Eckart
Format: Preprint
Published: 2026
Subjects:
Online Access:https://arxiv.org/abs/2604.20028
Tags: Add Tag
No Tags, Be the first to tag this record!
_version_ 1866917427383631872
author Leonelli, Alexandre D.
Widmer, Lukas
Meiburg, Eckart
author_facet Leonelli, Alexandre D.
Widmer, Lukas
Meiburg, Eckart
contents Due to attractive inter-particle forces, cohesive particles suspended in turbulence undergo a complex process of aggregation, breakup, and restructuring. Despite a growing body of knowledge on the ``flocculation'' of cohesive granular materials suspended in homogeneous isotropic turbulence, little focus has so far been placed on wall-bounded flows where turbulence and shear are inhomogeneous. This study presents a first investigation of a fully developed wall-bounded flow of resolved cohesive particles. Five direct numerical simulations of turbulent channel flows laden with finite-sized particles at successively increasing cohesive strength are performed. A population balance equation (PBE) framework is used to analyze aggregate dynamics. When integrated over the full domain, the PBE is closed by aggregation and breakup alone. However, this balance is found to not hold locally in the wall-normal direction, where regions of net aggregate production and depletion are identified. This imbalance is shown to be compensated by the size-dependent wall-normal transport of aggregates, revealing a mean circulation: larger aggregates are preferentially produced in the channel center and migrate toward the wall where they break, while smaller aggregates are transported away from the wall, grow, and reenter the cycle.
format Preprint
id arxiv_https___arxiv_org_abs_2604_20028
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Aggregation, breakup, and size-dependent transport in a turbulent channel flow with cohesive particles
Leonelli, Alexandre D.
Widmer, Lukas
Meiburg, Eckart
Fluid Dynamics
Due to attractive inter-particle forces, cohesive particles suspended in turbulence undergo a complex process of aggregation, breakup, and restructuring. Despite a growing body of knowledge on the ``flocculation'' of cohesive granular materials suspended in homogeneous isotropic turbulence, little focus has so far been placed on wall-bounded flows where turbulence and shear are inhomogeneous. This study presents a first investigation of a fully developed wall-bounded flow of resolved cohesive particles. Five direct numerical simulations of turbulent channel flows laden with finite-sized particles at successively increasing cohesive strength are performed. A population balance equation (PBE) framework is used to analyze aggregate dynamics. When integrated over the full domain, the PBE is closed by aggregation and breakup alone. However, this balance is found to not hold locally in the wall-normal direction, where regions of net aggregate production and depletion are identified. This imbalance is shown to be compensated by the size-dependent wall-normal transport of aggregates, revealing a mean circulation: larger aggregates are preferentially produced in the channel center and migrate toward the wall where they break, while smaller aggregates are transported away from the wall, grow, and reenter the cycle.
title Aggregation, breakup, and size-dependent transport in a turbulent channel flow with cohesive particles
topic Fluid Dynamics
url https://arxiv.org/abs/2604.20028