Elasticity of 2D ferroelectrics across their paraelectric phase transformation

Abstract

The mechanical behavior of two-dimensional (2D) materials across 2D phase changes is unknown, and the finite temperature (T) elasticity of paradigmatic SnSe monolayers -- ferroelectric 2D materials turning paraelectric as their unit cell (u.c.) turns from a rectangle onto a square -- is described here in a progressive manner. To begin with, their zero-T elastic energy landscape gives way to (Boltzmann-like) averages from which the elastic behavior is determined. These estimates are complemented with results from the strain-fluctuation method, which employs the energy landscape or ab initio molecular dynamics (MD) data. Both approaches capture the coalescence of elastic moduli C11(T)= C22(T) due to the structural transformation. The broad evolution and sudden changes of elastic parameters C11(T), C22(T), and C12(T) of these atomically-thin phase-change membranes establishes a heretofore overlooked connection among 2D materials and soft matter.