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Main Authors: Suzuki, Takayuki, Stephenson, Anna B., Yoon, Jinsik, Bae, Junghyun, Choi, Sung-Eun, Son, Kilho, Burbano, Diego Alba, Khoo, Harrison, Park, Wook, Hur, Soojung Claire
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2511.11955
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author Suzuki, Takayuki
Stephenson, Anna B.
Yoon, Jinsik
Bae, Junghyun
Choi, Sung-Eun
Son, Kilho
Burbano, Diego Alba
Khoo, Harrison
Park, Wook
Hur, Soojung Claire
author_facet Suzuki, Takayuki
Stephenson, Anna B.
Yoon, Jinsik
Bae, Junghyun
Choi, Sung-Eun
Son, Kilho
Burbano, Diego Alba
Khoo, Harrison
Park, Wook
Hur, Soojung Claire
contents The growing use of triaxial particles in microfluidic, microrobotic, and biological systems makes it essential to understand how their rotational dynamics couples with lateral migration in microscale flows. Our experiments in inertial Poiseuille flow reveal that geometric asymmetry in triaxial, multifaceted disks governs their orientation, migration, and rotational period, distinguishing them from classical axisymmetric objects. We identified a Reynolds- and geometry-dependent shift in preferred rotational orientation, arising from the Dzhanibekov effect, with transition modes determined by the particle's principal-axis configuration. We quantified a scalar offset from Jeffery's orbit prediction and introduced a fitting parameter that generalizes the Jeffery equation to include moment-of-inertia effects on rotational dynamics. Finally, we report the diameter of gyration as a predictor of the lateral equilibrium position of inertially focused triaxial particles. Our results link particle asymmetry to migration and rotation in flow, expanding our understanding of particle dynamics.
format Preprint
id arxiv_https___arxiv_org_abs_2511_11955
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Triaxial Asymmetry Driven Rotational Dynamics and Lateral Equilibrium Position in Inertial Flow
Suzuki, Takayuki
Stephenson, Anna B.
Yoon, Jinsik
Bae, Junghyun
Choi, Sung-Eun
Son, Kilho
Burbano, Diego Alba
Khoo, Harrison
Park, Wook
Hur, Soojung Claire
Fluid Dynamics
The growing use of triaxial particles in microfluidic, microrobotic, and biological systems makes it essential to understand how their rotational dynamics couples with lateral migration in microscale flows. Our experiments in inertial Poiseuille flow reveal that geometric asymmetry in triaxial, multifaceted disks governs their orientation, migration, and rotational period, distinguishing them from classical axisymmetric objects. We identified a Reynolds- and geometry-dependent shift in preferred rotational orientation, arising from the Dzhanibekov effect, with transition modes determined by the particle's principal-axis configuration. We quantified a scalar offset from Jeffery's orbit prediction and introduced a fitting parameter that generalizes the Jeffery equation to include moment-of-inertia effects on rotational dynamics. Finally, we report the diameter of gyration as a predictor of the lateral equilibrium position of inertially focused triaxial particles. Our results link particle asymmetry to migration and rotation in flow, expanding our understanding of particle dynamics.
title Triaxial Asymmetry Driven Rotational Dynamics and Lateral Equilibrium Position in Inertial Flow
topic Fluid Dynamics
url https://arxiv.org/abs/2511.11955