Oscillatory interactions of two spheres in an unbounded couple stress fluid

Oscillatory interactions of two spheres in an unbounded couple stress fluid

Abstract This study investigates the rectilinear oscillations of two coaxially aligned spherical particles in an unbounded couple stress fluid at low Reynolds numbers, addressing a fundamental problem in microfluidics and biomechanics where microstructure effects dominate. The importance lies in app...

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Bibliographic Details
Main Authors: Shreen El-Sapa, Azza M. Algatheem
Format: Article
Language:English
Published: Nature Portfolio 2025-07-01
Series:Scientific Reports
Subjects:
Interaction
Axisymmetric
Frequency
Couple stress theory
Numerical method
Transient
Online Access:https://doi.org/10.1038/s41598-025-11707-2
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Summary:Abstract This study investigates the rectilinear oscillations of two coaxially aligned spherical particles in an unbounded couple stress fluid at low Reynolds numbers, addressing a fundamental problem in microfluidics and biomechanics where microstructure effects dominate. The importance lies in applications such as drug delivery and material processing, where understanding particle-fluid interactions is critical. The unsteady Stokes equations were solved using a superposition of fundamental solutions in spherical coordinates, centered on each particle, with no-slip boundary conditions enforced via a collocation method. Key results include the quantification of in-phase and out-of-phase drag force coefficients, revealing that increasing the couple stress parameter ( $$\bar{\eta }$$ ) enhances drag forces by up to 50% for $$\bar{\eta } = 0.9$$ compared to Newtonian cases ( $$\bar{\eta } = 0$$ ). Numerical simulations demonstrated robust convergence across dimensionless parameters (e.g., separation distance $$\delta$$ , frequency $$\alpha$$ ), with tabulated data showing agreement within % of established solutions for steady-state and single-sphere oscillations. Novelty arises from extending prior work on viscous fluids to couple stress fluids, uncovering how microstructural effects amplify drag and alter oscillation dynamics. For instance, at $$\alpha = 60$$ , drag forces increased by 30% for closely spaced spheres ( $$\delta = 1.05$$ ), highlighting the interplay between frequency and microstructure. This work advances predictive models for complex fluids and provides design insights for microfluidic systems.
ISSN:2045-2322

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