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Reversible Pressure-Induced Partial Phase Transition in Few-Layer Black Phosphorus. | LitMetric
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Reversible Pressure-Induced Partial Phase Transition in Few-Layer Black Phosphorus.

Anirban Kundu Damien Tristant Natalya Sheremetyeva Anthony Yoshimura Abraao Torres Dias Kiran Shankar Hazra Vincent Meunier Pascal Puech

Nano Lett

Centre d'Elaboration des Matériaux et d'Etudes Structurales (CEMES), UPR-8011 CNRS, Université de Toulouse, 31055 Toulouse, France.

Published: August 2020

AI Article Synopsis

  • Researchers are studying how layered black phosphorus (BP) changes structure under mechanical stress, which is important for its use in microelectromechanical systems (MEMS) in tough environments.
  • Using high-pressure Raman spectroscopy, they found that when BP is subjected to around 4.2 GPa of pressure, it transitions from an orthorhombic structure to a rhombohedral one (also known as blue phosphorus).
  • The experiment showed that the phase change is reversible, and computational analysis helped explain how and why these structural changes occur under pressure, revealing a state where both BP and blue phosphorus can exist simultaneously.

Article Abstract

The experimental identification of structural transitions in layered black phosphorus (BP) under mechanical stress is essential to extend its application in microelectromechanical (MEMS) devices under harsh conditions. High-pressure Raman spectroscopic analysis of BP flakes suggests a transition pressure at ∼4.2 GPa, where the BP's crystal structure progressively transforms from an orthorhombic to a rhombohedral symmetry (blue phosphorus, bP). The phase transition has been identified by observing a transition from blueshift to redshift of the in-plane characteristic Raman modes (B and A) with increasing pressure. Recovery of the vibrational frequencies for all three characteristic Raman modes confirms the reversibility of the structural phase transition. First-principles calculations provide insight into the behavior of the Raman modes of BP under high pressure and reveal the mechanism responsible for the partial phase transition from BP to bP, corresponding to a metastable equilibrium state where both phases coexist.

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 Source
http://dx.doi.org/10.1021/acs.nanolett.0c01784DOI Listing

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