Scaling Laws and Paradoxical Metastable States in Nanofilament Entropic Separation

TL;DR

This paper develops an analytical theory revealing how entropic forces can both separate and attract nanofilament bundles, depending on a key dimensionless parameter, challenging traditional views of entropic disaggregation.

Contribution

The study introduces a new scaling law and analytical framework for entropic nanofilament separation, uncovering paradoxical attractive metastable states.

Findings

A single parameter determines filament attraction or repulsion.

Entropic forces can stabilize attractive bundles, contrary to usual expectations.

Simulations confirm the existence of metastable states.

Abstract

Entropic forces play a fundamental role in nanoscale phenomena, from colloidal self-assembly to biomolecular disaggregation. Here, we develop an exact analytical theory and find general scaling laws for the entropic separation of tether-mediated nanofilament bundles, revealing that a single dimensionless parameter--the ratio of the excluded-volume radius to the tether length--dictates whether filaments are pushed apart or, contrary to the usual expectation, pulled together. This unexpected regime challenges the view that entropic forces invariably promote disaggregation, instead uncovering conditions under which the bundles can remain in attractive metastable states. Brownian dynamics simulations confirm this paradoxical effect, offering predictive insights for applications in biophysics, soft matter physics, and nanotechnology.