The direct-to-indirect band gap crossover in two-dimensional van der Waals indium selenide crystals
Description
The electronic band structure of van der Waals (vdW) layered crystals has properties that depend on the composition, thickness and stacking of the component layers. Here we use density functional theory and high field magneto-optics to investigate the metal chalcogenide InSe, a recent addition to the family of vdW layered crystals, which transforms from a direct to an indirect band gap semiconductor as the number of layers is reduced. We investigate this direct-to-indirect bandgap crossover, demonstrate a highly tuneable optical response from the near infrared to the visible spectrum with decreasing layer thickness down to 2 layers, and report quantum dot-like optical emissions distributed over a wide range of energy. Our analysis also indicates that electron and exciton effective masses are weakly dependent on the layer thickness and are significantly smaller than in other vdW crystals. These properties are unprecedented within the large family of vdW crystals and demonstrates the potential of InSe for electronic and photonic technologies.
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Subjects
- Indium compounds
- Semiconductors -- Optical properties
- Energy-band theory of solids
- Layer structure (Solids)
- Magnetooptics
- Physical sciences::Physics::Optical physics, Laser physics
- Q Science::QC Physics::QC170 Atomic physics. Constitution and properties of matter
- Q Science::QC Physics::QC350 Optics. Light, including spectroscopy
- Q Science::QC Physics::QC501 Electricity and magnetism
Divisions
- University of Nottingham, UK Campus::Faculty of Science::School of Physics and Astronomy
Deposit date
2017-01-03Data type
ASCII Data experiment and theoryFunders
- Engineering & Physical Sciences Research Council
- Other
- The Royal Society
- EU Graphene Flagship
Collection dates
- 2014-2016
Resource languages
- en