H. Helava scite author profile

In high-purity GaN grown by hydride vapor phase epitaxy, the commonly observed yellow luminescence (YL) band gives way to a green luminescence (GL) band at high excitation intensity. We propose that the GL band with a maximum at 2.4 eV is caused by transitions of electrons from the conduction band to the 0/+ level of the isolated C N defect. The YL band, related to transitions via the −/0 level of the same defect, has a maximum at 2.1 eV and can be observed only for some high-purity samples. However, in less pure GaN samples, where no GL band is observed, another YL band with a maximum at 2.2 eV dominates the photoluminescence spectrum. The latter is attributed to the C N O N complex.

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Sublimation growth of AlN bulk crystals in Ta crucibles

Мохов¹,

Avdeev²,

Barash³

et al. 2005

Journal of Crystal Growth

104

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Determination of the electron-capture coefficients and the concentration of free electrons in GaN from time-resolved photoluminescence

Reshchikov

McNamara

Toporkov

et al. 2016

Sci Rep

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Point defects in high-purity GaN layers grown by hydride vapor phase epitaxy are studied by steady-state and time-resolved photoluminescence (PL). The electron-capture coefficients for defects responsible for the dominant defect-related PL bands in this material are found. The capture coefficients for all the defects, except for the green luminescence (GL1) band, are independent of temperature. The electron-capture coefficient for the GL1 band significantly changes with temperature because the GL1 band is caused by an internal transition in the related defect, involving an excited state acting as a giant trap for electrons. By using the determined electron-capture coefficients, the concentration of free electrons can be found at different temperatures by a contactless method. A new classification system is suggested for defect-related PL bands in undoped GaN.

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Zero-phonon line and fine structure of the yellow luminescence band in GaN

et al. 2016

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The yellow luminescence band was studied in undoped and Si-doped GaN samples by steady-state and time-resolved photoluminescence. At low temperature (18 K), the zerophonon line (ZPL) for the yellow band is observed at 2.57 eV and attributed to electron transitions from a shallow donor to a deep-level defect. At higher temperatures, the ZPL at 2.59 eV emerges, which is attributed to electron transitions from the conduction band to the same defect. In addition to the ZPL, a set of phonon replicas is observed, which is caused by the emission of phonons with energies of 39.5 meV and 91.5 meV. The defect is called the YL1 center. The possible identity of the YL1 center is discussed. The results indicate that the same defect is responsible for the strong YL1 band in undoped and Si-doped GaN samples.

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High-Density Discharges in the Alcator Tokamak

et al. 1977

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H. Helava

Carbon defects as sources of the green and yellow luminescence bands in undoped GaN

Sublimation growth of AlN bulk crystals in Ta crucibles

Determination of the electron-capture coefficients and the concentration of free electrons in GaN from time-resolved photoluminescence

Zero-phonon line and fine structure of the yellow luminescence band in GaN

High-Density Discharges in the Alcator Tokamak

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