Low-temperature anomalies in 1D hard rods with soft attractive nearest-neighbor interactions
Abstract
Previous experiments and numerical simulations have revealed that a limited number of two- and three-dimensional particle systems contract in volume upon heating isobarically. This anomalous phenomenon is known as negative thermal expansion (NTE). Recently, in a study by [I. Trav\v{e}nec and L. \v{S}amaj: J. Phys. A: Math. Theor. {\bf 58}, 195005 (2025)], exactly solvable one-dimensional fluids of hard rods with various types of soft purely repulsive nearest-neighbor interactions were examined at low temperatures. The presence of the NTE anomaly in such systems heavily depends on the shape of the core-softened potential and, in some cases, is associated with jumps in chain spacing of the equidistant ground state at certain pressures. This paper focuses on one-dimensional fluids of hard rods with soft nearest-neighbor interactions that contain a basin of attraction with just one minimum. The ground-state analysis reveals that, for certain potentials, increasing the pressure can lead to a discontinuous jump in the mean spacing between particles. The low-temperature analysis of the exact equation of state indicates that the NTE anomaly is present if the curvature of the interaction potential increases with the distance between particles or if the potential exhibits a singularity within the basin of attraction. Isotherms of the compressibility factor, which measures the deviation of the thermodynamic behavior of a real gas from that of an ideal gas, demonstrate typical plateau or double-plateau shapes in large intervals of particle density.