First principles modeling of defects in the Al2O3/In0.53Ga0.47As system

Abstract: Density functional theory paired with a first order many-body perturbation theory correction is applied to determine formation energies and charge transition energies for point defects in bulk In0.53Ga0.47As and for models of the In0.53Ga0.47As/Al2O3 interface. The results are consistent with previous computational studies that AsGa antisites are candidates for defects observed in capacitance voltage measurements on metal-oxide-semiconductor capacitors, as the AsGa antisite introduces energy states near the va… Show more

“…The origin of the trap state cannot be determined at the moment, and a dedicated study is needed to obtain more information on this trap. Based on ab-initio calculations, also employing the correction of many-body perturbation theory, the H1 trap could be associated with a gallium vacancy level or gallium antisite 15,47,48 .…”

Impact of band to band tunneling in In0.53Ga0.47As tunnel diodes on the deep level transient spectra

“…The origin of the trap state cannot be determined at the moment, and a dedicated study is needed to obtain more information on this trap. Based on ab-initio calculations, also employing the correction of many-body perturbation theory, the H1 trap could be associated with a gallium vacancy level or gallium antisite 15,47,48 .…”

Impact of band to band tunneling in In0.53Ga0.47As tunnel diodes on the deep level transient spectra

Efficient device simulations using density functional theory Hamiltonian and non-equilibrium Green’s function: heterostructure mode space method and core charge approximation

Electrical and mechanical properties variation of Al2O3–CaO-CNT(3,3) nanomaterial due to Al vacancy and temperature: DFT approach