# Raman and Far Infrared Synchrotron Nanospectroscopy of Layered   Crystalline Talc: Vibrational Properties, Interlayer Coupling and Symmetry   Crossover

**Authors:** Raphael Longuinhos, Alisson R. Cadore, Hans A. Bechtel, Christiano J., S. de Matos, Raul O. Freitas, Jenaina Ribeiro-Soares, and Ingrid D. Barcelos

arXiv: 2302.14107 · 2023-03-01

## TL;DR

This study combines advanced spectroscopic techniques and calculations to explore the vibrational properties, interlayer interactions, and symmetry changes in layered talc crystals from monolayer to bulk, revealing insights for nanoscale applications.

## Contribution

It provides new insights into talc's vibrational modes, interlayer coupling, and symmetry crossover, enhancing understanding of its nanoscale structural properties.

## Key findings

- Symmetry crossover observed from mono to bilayer talc.
- Weak dependence of intralayer modes on layer number.
- Low-frequency modes effectively identify layer count and reveal anisotropy.

## Abstract

Talc is an insulating layered material that is stable at ambient conditions and has high-quality basal cleavage, which is a major advantage for its use in van der Waals heterostructures. Here, we use near-field synchrotron infrared nanospectroscopy, Raman spectroscopy, and first-principles calculations to investigate the structural and vibrational properties of talc crystals, ranging from monolayer to bulk, in the 300-750 cm-1 and <60 cm-1 spectral windows. We observe a symmetry crossover from mono to bilayer talc samples, attributed to the stacking of adjacent layers. The in-plane lattice parameters and frequencies of intralayer modes of talc display weak dependence with the number of layers, consistent with a weak interlayer interaction. On the other hand, the low-frequency (<60 cm-1) rigid-layer (interlayer) modes of talc are suitable to identify the number of layers in ultrathin talc samples, besides revealing strong in-plane and out-of-plane anisotropy in the interlayer force constants and related elastic stiffnesses of single crystals. The shear and breathing force constants of talc are found to be 66% and 28%, respectively, lower than those of graphite, making talc an excellent lubricant that can be easily exfoliated. Our results broaden the understanding of the structural and vibrational properties of talc at the nanoscale regime and serve as a guide for future ultrathin heterostructures applications.

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Source: https://tomesphere.com/paper/2302.14107