Litcius/Paper detail

Probing Anisotropic Deformation and Near-Infrared Emission Tuning in Thin-Layered InSe Crystal under High Pressure

Liyun Zhao, Yingjie Jiang, Chun Li, Yin Liang, Zhongming Wei, Xiaoding Wei, Qing Zhang

2023Nano Letters30 citationsDOI

Abstract

Indium selenide (InSe) exhibits high lattice compressibility and an extraordinary capability of tailoring the optical band gap under pressure beyond other 2D materials. Herein, by applying hydrostatic pressure via a diamond anvil cell, we revealed an anisotropic deformation dynamic and efficient manipulation of near-infrared light emission in thin-layered InSe strongly correlated to layer numbers ( N = 5–30). As N > 20, the InSe lattice is compressed in all directions, and the intralayer compression leads to widening of the band gap, resulting in an emission blue shift (∼120 meV at 1.5 GPa). In contrast, as N ≤ 15, an efficient emission red shift is observed from band gap shrinkage (rate of 100 meV GPa –1 ), which is attributed to the predominant uniaxial interlayer compression because of the high strain resistance along the InSe–diamond interface. These findings advance the understanding of pressure-induced lattice deformation and optical transition evolution in InSe and could be applied to other 2D materials.

Topics & Concepts

Materials scienceAnisotropyIndiumHydrostatic pressureBand gapDeformation (meteorology)BlueshiftInfraredDiamond anvil cellCompressibilityCondensed matter physicsSelenideDiamondLattice (music)Annealing (glass)OptoelectronicsPhotoluminescenceOpticsDiffractionComposite materialAerospace engineeringMetallurgyAcousticsPhysicsThermodynamicsEngineeringSelenium2D Materials and ApplicationsSolid-state spectroscopy and crystallographyChalcogenide Semiconductor Thin Films