Abstract
Gallium Telluride (GaTe), a layered material with monoclinic crystal structure, has recently attracted a lot of attention due to its unique physical properties and potential applications for angle-resolved photonics and electronics, where optical anisotropies are important. Despite a few reports on the in-plane anisotropies of GaTe, a comprehensive understanding of them remained unsatisfactory to date. In this work, we investigated thickness-dependent in-plane anisotropies of the 13 Raman-active modes and one Raman-inactive mode of GaTe by using angle-resolved polarized Raman spectroscopy, under both parallel and perpendicular polarization configurations in the spectral range from 20 to 300 cm−1. Raman modes of GaTe revealed distinctly different thickness-dependent anisotropies in parallel polarization configuration while nearly unchanged for the perpendicular configuration. Especially, three Ag modes at 40.2 ({text{A}}_{text{g}}^{1}), 152.5 ({text{A}}_{text{g}}^{7}), and 283.8 ({text{A}}_{text{g}}^{12}) cm−1 exhibited an evident variation in anisotropic behavior as decreasing thickness down to 9 nm. The observed anisotropies were thoroughly explained by adopting the calculated interference effect and the semiclassical complex Raman tensor analysis.
Highlights
Gallium Telluride (GaTe), a layered material with monoclinic crystal structure, has recently attracted a lot of attention due to its unique physical properties and potential applications for angle-resolved photonics and electronics, where optical anisotropies are important
The in-plane anisotropy in electrical, optical, thermal, and phonon properties is associated with the low in-plane symmetry of crystal structure
We have investigated the in-plane anisotropies of the 13 Raman-active modes and one Ramaninactive mode of GaTe flakes with different thicknesses by using angle-resolved polarized Raman spectroscopy (ARPRS) in the spectral range from 20 to 300 cm−1
Summary
Gallium Telluride (GaTe), a layered material with monoclinic crystal structure, has recently attracted a lot of attention due to its unique physical properties and potential applications for angle-resolved photonics and electronics, where optical anisotropies are important. Two-dimensional (2D) materials such as graphene and transition metal dichalcogenides (TMDCs) attracted massive attention These materials frequently displayed diverse optical and electronic properties with a high in-plane isotropy[1,2,3]. The in-plane anisotropy in electrical, optical, thermal, and phonon properties is associated with the low in-plane symmetry of crystal structure. Among many experimental methods used to study its anisotropic properties, the angle-resolved polarized Raman spectroscopy (ARPRS) was quite useful to investigate the in-plane polarization anisotropy of its phonon m odes[22,25]. Systematic study on the layer-thickness-dependent in-plane anisotropy of GaTe phonon modes is yet to be done
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