Litcius/Paper detail

InAs/InAsSb type‐II superlattice with near room‐temperature long‐wave emission through interface engineering

Bowen Zhang, Dan Fang, Xuan Fang, Hongbin Zhao, Dengkui Wang, Jinhua Li, Xiaohua Wang, Dongbo Wang

2021Rare Metals56 citationsDOI

Abstract

Abstract Ga‐free InAs/InAsSb type‐II superlattices (T2SL) have extensive application prospective in infrared photodetectors. Achieving higher operation temperature is critical to its commercial applications. Here, a fractional monolayer alloy method was used to grow InAsSb alloy with better controlled alloy composition. The as‐grown T2SL gave eleven satellite peaks and a first satellite peak with a narrow full‐width‐half‐maximum (FWHM) of 20.5 arcsec (1 arcsec= 0.01592°). Strain mapping results indicated limited Sb diffusion through the As‐Sb exchange process at the interface. Moreover, unlike interface states caused by the As‐Sb exchange effect, this relatively clear interface was distinctive with localized states with higher activation energies of the non‐radiative recombination process ((18 ±1) meV and (84 ±12) meV at different temperature ranges), which means that this interface state introduced by fractional monolayer alloy growth method can effectively suppress Auger recombination process in T2SL. Through this interface engineering of InAs/InAsSb Type‐II superlattice, it achieved detective photoluminescence (PL) signal with the center wavelength of 9 μm at 250K.

Topics & Concepts

Materials sciencePhotoluminescenceSuperlatticeMonolayerAlloyOptoelectronicsSpontaneous emissionOpticsNanotechnologyPhysicsComposite materialLaserAdvanced Semiconductor Detectors and MaterialsChalcogenide Semiconductor Thin FilmsSemiconductor Quantum Structures and Devices
InAs/InAsSb type‐II superlattice with near room‐temperature long‐wave emission through interface engineering | Litcius