Abstract
Advanced semiconductor superlattices play important roles in critical future high-tech applications such as aerospace, high-energy physics, gravitational wave detection, astronomy, and nuclear related areas. Under such extreme conditions like high irradiative environments, these semiconductor superlattices tend to generate various defects that ultimately may result in the failure of the devices. However, in the superlattice like GaAs/AlAs, the phase stability and impact on the device performance of point defects are still not clear up to date. The present calculations show that in GaAs/AlAs superlattice, the antisite defects are energetically more favorable than vacancy and interstitial defects. The AsX (X = Al or Ga) and XAs defects always induce metallicity of GaAs/AlAs superlattice, and GaAl and AlGa antisite defects have slight effects on the electronic structure. For GaAs/AlAs superlattice with the interstitial or vacancy defects, significant reduction of band gap or induced metallicity is found. Further calculations show that the interstitial and vacancy defects reduce the electron mobility significantly, while the antisite defects have relatively smaller influences. The results advance the understanding of the radiation damage effects of the GaAs/AlAs superlattice, which thus provide guidance for designing highly stable and durable semiconductor superlattice based electronic and optoelectronics for extreme environment applications.
Highlights
Zollo et al have employed density functional theory (DFT) method to investigate the stability of point defects in Gallium arsenide (GaAs), and found that the antisite defects were more favorable [14]
In this work, a hybrid density functional theory study is performed to investigate the effects of point defect on the electrical properties of GaAs/Aluminum arsenide (AlAs) superlattice (SL)
The calculated defect formation energies show that the antisite defects are the most favorable in bulk GaAs and AlAs
Summary
The superlattice (SL) is an artificial material consisting of alternating thin layers of two or more different components. An AIMD simulation of radiation response of GaAs/AlAs SL has been carried out [17], in which the minimum energies for each atom to be permanently displaced from its lattice site have been determined, the pathways for defect generation have been provided, and the types of created defects have been identified. It revealed that the created Ga (or Al or As) Frenkel pair and AsGa-GaAs antisite pair have profound effects on the density of state distribution and band structure of GaAs/AlAs SL [17]
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