Temperature dependent Raman spectroscopy of titanium trisulfide (TiS3) nanoribbons and nanosheets

TL;DR

This study investigates how the vibrational properties of TiS3 nanoribbons and nanosheets change with temperature using Raman spectroscopy, revealing significant softening of modes and potential for non-invasive thermal sensing.

Contribution

First temperature-dependent Raman analysis of TiS3 nanoribbons and nanosheets, highlighting their vibrational behavior and differences related to interlayer coupling.

Findings

Raman modes soften linearly with temperature from 88 K to 570 K

TiS3 shows more pronounced temperature dependence than other 2D materials

Nanosheets exhibit stronger temperature dependence than nanoribbons

Abstract

Titanium trisulfide (TiS3) has recently attracted the interest of the 2D community as it presents a direct bandgap of ~1.0 eV, shows remarkable photoresponse, and has a predicted carrier mobility up to 10000 cm2V-1 s-1. However, a study of the vibrational properties of TiS3, relevant to understanding the electron-phonon interaction which can be the main mechanism limiting the charge carrier mobility, is still lacking. In this work, we take the first steps to study the vibrational properties of TiS3 through temperature dependent Raman spectroscopy measurements of TiS3 nanoribbons and nanosheets. Our investigation shows that all the Raman modes linearly soften (red shift) as the temperature increases from 88 K to 570 K, due to the anharmonic vibrations of the lattice which also includes contributions from the lattice thermal expansion. This softening with the temperature of the TiS3 modes is more pronounced than that observed in other 2D semiconductors such as MoS2, MoSe2, WSe2 or black phosphorus (BP). This marked temperature dependence of the Raman could be exploited to determine the temperature of TiS3 nanodevices by using Raman spectroscopy as a non-invasive and local thermal probe. Interestingly, the TiS3 nanosheets show a stronger temperature dependence of the Raman modes than the nanoribbons, which we attribute to a lower interlayer coupling in the nanosheets.