<i>Ab initio</i> study of the bandgap engineering of Al1−xGaxN for optoelectronic applications

Amin, B.; Ahmad, Iftikhar; Maqbool, Muhammad; Goumri‐Said, Souraya; Ahmad, Rashid

doi:10.1063/1.3531996

Cited by 176 publications

(45 citation statements)

References 45 publications

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“…Guerrero et al 23 carried out room temperature reflectivity measurements on MBE grown zb-Al An analysis of reported theoretical data reveals inconsistencies in the numerical description of the composition dependence of the fundamental zb-Al x Ga 1−x N band gaps as well. Recently, Amin et al 27 employed the Wu-Cohen generalized gradient approximation (GGA) within a full-potential linearized augmented plane wave approach (FLAPW) to calculate the zb-Al x Ga 1−x N band gaps over the entire composition range. Consistent with the band gap data of Okumura et al, the alloy band gap was found to be direct for the entire composition range, increasing linearly from a direct band gap of 3.00 eV in zb-GaN to a direct band gap of 5.50 eV in zb-AlN.…”

Section: Introductionmentioning

confidence: 99%

Transition energies and direct-indirect band gap crossing in zinc-blende AlxGa1−xN

et al. 2013

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The electronic and optical properties of zinc-blende (zb) Al x Ga 1−x N over the whole alloy composition range are presented in a joint theoretical and experimental study. Because zb-GaN is a direct ( v → c ) semiconductor and zb-AlN shows an indirect ( v → X c ) fundamental band gap, the ternary alloy exhibits a concentration-dependent direct-indirect band gap crossing point the position of which is highly controversial. The dielectric functions of zb-Al x Ga 1−x N alloys are measured employing synchrotron-based ellipsometry in an energy range between 1 and 20 eV. The experimentally determined fundamental energy transitions originating from the , X, and L points are identified by comparison to theoretical band-to-band transition energies. In order to determine the direct-indirect band gap crossing point, the measured transition energies at the X point have to be aligned by the calculated position of the highest valence state. Thereby density-functional theory (DFT) based approaches to the electronic structure, ranging from the standard (semi)local generalized gradient approximation (GGA), self-energy corrected local density approximation (LDA-1/2), and meta-GGA DFT (TB-mBJLDA) to hybrid functional DFT and many-body perturbation theory in the GW approximation, are applied to random and special quasirandom structure models of zb-Al x Ga 1−x N. This study provides interesting insights into the accuracy of the various numerical approaches and contains reliable ab initio data on the electronic structure and fundamental alloy band gaps of zb-Al x Ga 1−x N. Nonlocal Heyd-Scuseria-Ernzerhof-type hybrid-functional DFT calculations or, alternatively, GW quasiparticle calculations are required to reproduce prominent features of the electronic structure. The direct-indirect band gap crossing point of zb-Al x Ga 1−x N is found in the Al rich composition range at an Al content between x = 0.64 and 0.69 in hybrid functional DFT, which is in good agreement with x = 0.71 determined from the aligned experimental transition energies. Thus our study solves the long-standing debate on the nature of the fundamental zb-Al x Ga 1−x N alloy band gap.

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Section: Introductionmentioning

confidence: 99%

Transition energies and direct-indirect band gap crossing in zinc-blende AlxGa1−xN

et al. 2013

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“…The imaginary part of the dielectric function, ε 2 (ω), represents the light absorption in the crystal, which can be obtained by calculating the momentum matrix elements between the occupied and the unoccupied states [26], obeying the selection rule. Then, the real part of the dielectric function, ε 1 (ω), governs the propagation behaviour of electromagnetic field in a material, is derived from the imaginary part using the Kramers-Kronig transformation [27].…”

Section: X= Sn Ti and Zr)mentioning

confidence: 99%

Ab initio study on the electronic, optical and electrical properties of Ti-, Sn- and Zr-doped ZnO

Slassi

Lakouari

Ziat

et al. 2015

Solid State Communications

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“…5, wavelength of tangent of transmittance upheaval place was at about 367-375 nm, indicating that characteristics of wavelength was¯rst blue shift and then red shift. A detailed research about the variations in the optical properties, bandgap, and nonlinear behavior of the compound with the change in the Ga doping concentration was carried out by Amin 14 and Maqbool. 17 The above conclusion was similar to Dai Jielin's, 18 who prepared ZnO thin¯lms with doping In.…”

Section: Transmittance Analysismentioning

confidence: 99%

EFFECT OF Al DOPING CONCENTRATION ON MICROSTRUCTURE, PHOTOELECTRIC PROPERTIES AND DOPED MECHANISM OF AZO FILMS

Cai

Hou

et al. 2014

Surf. Rev. Lett.

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Al doped ZnO (AZO) thin¯lms were deposited on a glass substrate by atmospheric pressure chemical vapor deposition (APCVD) method. E®ect of Al doping concentration on microstructure, photoelectric properties and doped mechanism of AZO thin¯lms were investigated. The analysis results revealed that the structural properties of the¯lms possessed crystalline structure with a preferred (002) orientation. The best crystallization quality and minimum electrical resistivity was obtained at 5 at.% Al doped¯lms and the minimum resistivity was 6:6 Â 10 À4 Á cm. Uniform granular grains were observed on the surface of AZO¯lms, and the average optical transmittance was above 80% in the visible range. The doped mechanism of AZO¯lms was analyzed as follows. With Al doping in ZnO¯lms, Al Zn substitute and Al i interstice were produced, which decreased the resistivity of¯lms. While after the limit value and with the continuing increase of Al doping concentration, free electrons were consumed and the resistivity of¯lms increased.

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Ab initio study of the bandgap engineering of Al1−xGaxN for optoelectronic applications

Cited by 176 publications

References 45 publications

Transition energies and direct-indirect band gap crossing in zinc-blende AlxGa1−xN

Transition energies and direct-indirect band gap crossing in zinc-blende AlxGa1−xN

Ab initio study on the electronic, optical and electrical properties of Ti-, Sn- and Zr-doped ZnO

EFFECT OF Al DOPING CONCENTRATION ON MICROSTRUCTURE, PHOTOELECTRIC PROPERTIES AND DOPED MECHANISM OF AZO FILMS

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