Ferroelectric and Dipolar Glass Phases of Non-Crystalline Systems

TL;DR

This study uses simulations to explore ferroelectric and dipolar glass phases in non-crystalline systems, revealing how different models exhibit long-range order or glassy states depending on their dynamics and parameters.

Contribution

It provides a comprehensive analysis of ferroelectric and dipolar glass phases in disordered dipolar systems through simulations of various models and their physical interpretations.

Findings

Ising model shows ferroelectric phases in frozen amorphous systems.

XY and XYZ models form dipolar glass phases at low temperatures.

Critical temperature depends on particle mass in dynamic models.

Abstract

In a recent letter [Phys. Rev. Lett. {\bf 75}, 2360 (1996)] we briefly discussed the existence and nature of ferroelectric order in positionally disordered dipolar materials. Here we report further results and give a complete description of our work. Simulations of randomly frozen and dynamically disordered dipolar soft spheres are used to study ferroelectric ordering in non-crystalline systems. We also give a physical interpretation of the simulation results in terms of short- and long-range interactions. Cases where the dipole moment has 1, 2, and 3 components (Ising, XY and XYZ models, respectively) are considered. It is found that the Ising model displays ferroelectric phases in frozen amorphous systems, while the XY and XYZ models form dipolar glass phases at low temperatures. In the dynamically disordered model the equations of motion are decoupled such that particle translation is completely independent of the dipolar forces. These systems spontaneously develop long-range ferroelectric order at nonzero temperature despite the absence of any fined-tuned short-range spatial correlations favoring dipolar order. Furthermore, since this is a nonequilibrium model we find that the paraelectric to ferroelectric transition depends on the particle mass. For the XY and XYZ models, the critical temperatures extrapolate to zero as the mass of the particle becomes infinite, whereas, for the Ising model the critical temperature is almost independent of mass and coincides with the ferroelectric transition found for the randomly frozen system at the same density. Thus in the infinite mass limit the results of the frozen amorphous systems are recovered.