English

Microgel Translocation Through Narrow Capillaries

Soft Condensed Matter 2026-02-24 v1

Abstract

The transport of soft viscoelastic gels through confined geometries underlies critical processes in biomedical, biological, and industrial systems. Here, we examine the translocation of a spherical microgel through a narrow capillary whose diameter is smaller than the equilibrium gel size. Using coarse-grained molecular dynamics simulations in tandem with mean-field theory and mechanical analysis, we uncover a critical threshold diameter dcd_c below which the microgel cannot enter, regardless of the applied pressure. This geometric limit emerges from the interplay between gel elasticity and its internal network connectivity, captured quantitatively by a graph-theoretic model. We construct a phase diagram in the parameter space of tube diameter dd, applied force fgf_g, and gel stiffness YY (Young's modulus), which delineates the regimes of successful translocation and mechanical arrest. Under negligible wall friction, gel mobility scales with the applied force; however, beyond a cutoff set by the network topology, progressive densification in the constriction stalls the microgel. Our results reveal the mechanical and topological determinants of soft-gel transport in confinement and provide predictive guidelines for engineering gel-based systems in microfluidics, drug delivery, and tissue-level filtration.

Keywords

Cite

@article{arxiv.2602.19205,
  title  = {Microgel Translocation Through Narrow Capillaries},
  author = {Subhadip Biswas and Buddhapriya Chakrabarti},
  journal= {arXiv preprint arXiv:2602.19205},
  year   = {2026}
}

Comments

13 pages, 13 figures (SI not added - please request by email)

R2 v1 2026-07-01T10:46:19.488Z