Electron Traps in n-GaN Grown on Si (111) Substrates by MOVPE

Ito, Tsuneo; Terada, Yutaka; Egawa, Takashi

doi:10.1557/proc-1068-c06-09

Cited by 5 publications

(4 citation statements)

References 11 publications

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“…The activation energy of further ionisation N Ga (+1| + 2)e can be estimated to lie between 0.43 and 0.56 eV. It is unlikely that this process is responsible for the ubiquitous E c − 0.56 eV trap discussed above-we expect the antisite to be only a small minority defect, but it is consistent with the behaviour of rare ET8 traps at E c − 0.49 eV [126], which have previously been associated with N Ga, and show a barrier of about 0.15 eV for electron capture (see discussion in [120]). Finally, the hole capture by N +3 Ga at 1.71 eV is again consistent with the position of H5 traps [119], for which, however, we have already seen more candidates.…”

Section: Defect As Trapssupporting

confidence: 72%

Donor and acceptor characteristics of native point defects in GaN

Xie

Sui

Buckeridge

et al. 2019

J. Phys. D: Appl. Phys.

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The semiconducting behaviour and optoelectronic response of gallium nitride is governed by point defect processes, which, despite many years of research, remain poorly understood. The key difficulty in the description of the dominant charged defects is determining a consistent position of the corresponding defect levels, which is difficult to derive using standard supercell calculations. In a complementary approach, we take advantage of the embedded cluster methodology that provides direct access to a common zero of the electrostatic potential for all point defects in all charge states. Charged defects polarise a host dielectric material with long-range forces that strongly affect the outcome of defect simulations; to account for the polarisation we couple embedding with the hybrid quantum mechanical/molecular mechanical (QM/MM) approach and investigate the structure, formation and ionisation energies, and equilibrium concentrations of native point defects in wurtzite GaN at a chemically accurate hybrid-density-functional-theory level. N vacancies are the most thermodynamically favourable native defects in GaN, which contribute to the n-type character of as-grown GaN but are not the main source, a result that is consistent with experiment. Our calculations show no native point defects can form thermodynamically stable acceptor states. GaN can be easily doped n-type, but, in equilibrium conditions at moderate temperatures acceptor dopants will be compensated by N vacancies and no significant hole concentrations will be observed, indicating non-equilibrium processes must dominate in p-type GaN. We identify spectroscopic signatures of native defects in the infrared, visible and ultraviolet luminescence ranges and complementary spectroscopies. Crucially, we calculate the effective-mass-like-state levels associated with electrons and holes bound in diffuse orbitals. These levels may be accessible in competition with more stronglylocalised states in luminescence processes and allow the attribution of the observed 3.46 and 3.27 eV UV peaks in a broad range of GaN samples to the presence of N vacancies.

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Section: Defect As Trapssupporting

confidence: 72%

Donor and acceptor characteristics of native point defects in GaN

Xie

Sui

Buckeridge

et al. 2019

J. Phys. D: Appl. Phys.

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“…ET8 traps at E c À(0.47-0.49) eV are sometimes reported for MOCVD grown undoped n-GaN [212]. The traps were observed to increase in concentration when moving inside the samples grown by epitaxial lateral overgrowth [213].…”

Section: Deep Traps In Ganmentioning

confidence: 84%

“…The traps were observed to increase in concentration when moving inside the samples grown by epitaxial lateral overgrowth [213]. They are the rare traps for which the normal, not logarithmic, dependence of the traps peak magnitude in DLTS was observed [212]. The capture of electrons to the traps required overcoming a relatively high barrier of about 0.15 eV so that the room temperature persistent photoconductivity in undoped n-GaN observed in many cases has been partly attributed to these traps [214].…”

Section: Deep Traps In Ganmentioning

confidence: 99%

Deep traps in GaN-based structures as affecting the performance of GaN devices

Polyakov

Lee

2015

Materials Science and Engineering: R: Reports

205

177

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“…And net doping concentration of n-GaN on GaN substrates is studied in relation to dislocation density [6]. However, currently there are few reports available on study of the defects such as deep traps in GaN grown on Si substrates [7,8]. In this paper, we have examined electrical properties, especially net doping characteristics in n-GaN grown on Si(111), and c-sapphire substrates, clarified that crystal qualities, impurity concentrations and investigated the deep traps by means of DLTS measurement.…”

Section: Introductionmentioning

confidence: 99%