Investigating strain between phase-segregated domains in Cu-deficient CuInP2S6

TL;DR

This study investigates the strain between phase-segregated domains in Cu-deficient CuInP2S6, revealing how Cu deficiency induces lattice strains, phase separation, and affects optical properties, with implications for ferroelectric material engineering.

Contribution

The paper provides a detailed analysis of strain evolution in Cu-deficient CuInP2S6 using spectroscopic and computational methods, highlighting the relationship between composition, phase segregation, and lattice strain.

Findings

Maximum strain occurs at Cu/In ratio of 0.33.

Raman and infrared peak shifts correlate with lattice strain.

Optical bandgap decreases with Cu deficiency, reaching ~2.3 eV.

Abstract

CuInP2S6 (CIPS) is an emerging layered ferroelectric material with a TC above room temperature. When synthesized with Cu deficiencies (i.e., Cu1-xIn1+x/3P2S6), the material segregates into CIPS and In4/3P2S6 (IPS) self-assembled heterostructures within the same single crystal. This segregation results in significant in-plane and out-of-plane strains between the CIPS and IPS phases as the volume fraction of CIPS (IPS) domains shrink (grow) with decreasing Cu fraction. Here, we synthesized CIPS with varying amounts of Cu (x = 0, 0.2, 0.3, 0.4, 0.5, 0.7, 0.8 and 1) and measured the strains between the CIPS and IPS phases through the evolution of the respective Raman, infrared, and optical reflectance spectra. Density functional theory calculations revealed vibrational modes unique to the CIPS and IPS phases, which can be used to distinguish between the two phases through two-dimensional Raman mapping. A comparison of the composition-dependent frequencies and intensities of the CIPS and IPS Raman peaks showed interesting trends with decreasing CIPS phase fraction (i.e., Cu/In ratio). Our data reveal red- and blue-shifted Raman and infrared peak frequencies that we correlate to lattice strains arising from the segregation of the material into CIPS and IPS chemical domains. The strain is highest for a Cu/In ratio of 0.33 (Cu0.4In1.2P2S6), which we attribute to equal and opposite strains exerted by the CIPS and IPS phases on each other. In addition, bandgaps extracted from the optical reflectance spectra revealed a decrease in values, with the lowest value (~ 2.3 eV) for Cu0.4In1.2P2S6.