A Statistical-Mechanical Model for Dipolar Chain Formation

Abstract

Dipolar fluids are known to exhibit complex self-assembly at low temperatures, yet a compact thermodynamic description of their aggregate statistics has remained elusive. Using molecular dynamics simulations of Stockmayer particles with a purely repulsive WCA core, we show that over broad regions of the (, T) phase space the chain-size distribution follows an exponential decay with characteristic size s0. Within this regime, we find that s0 can be accurately described by an effective thermodynamic potential φ that incorporates bonding energy, a crowding penalty, and translational entropy. Identifying deviations from this ideal scaling provides a further division of the phase space into four regions. Therefore, our results locate a regime of relatively simple chain statistics and offer an alternative regime-based perspective on dipolar self-assembly.