Photoluminescence properties of AlN homoepilayers with different orientations

Sedhain, A.; Nepal, Neeraj; Nakarmi, M. L.; Tahtamouni, T. M. Al; Lin, J. Y.; Jiang, Hao; Gu, Zheng; Edgar, James H.

doi:10.1063/1.2965613

Cited by 30 publications

(30 citation statements)

References 19 publications

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“…This explanation is consistent with the previously reported results of transparent AlN, in which a ͑V Al -2O N ͒ 1− related absorption band around 4.7 eV emerged, while the 2.8 eV band completely disappeared in samples containing the highest oxygen concentrations ͑1.2ϫ 10 21 cm −3 ͒. 8,9 In summary, we have carried out optical studies on different AlN samples by PL measurement to address the question of why bulk AlN crystals appear yellow in color. We propose that the absorption band centered around 2.8 eV, which corresponds to the excitation of electrons from the valence band to the V Al 2− state of ͑V Al ͒ 3−/2− , is responsible for the yellowish color of bulk AlN substrates.…”

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confidence: 82%

“…The AlN epilayer and polycrystalline AlN exhibit dominant free exciton ͑FX͒ emission peaks at 5.98 and 5.96 eV, respectively. 8,12,13 However, the FX transition at 5.95 eV and broad emission lines at 4.0 and 2.76 eV have comparable emission intensities in bulk m-AlN. The impurity band around 4.0 eV was previously identified as a donor-acceptor-pair type transition involving a shallow donor and an aluminum vacancy ͑V Al ͒ complex with 2/1 negative charges, either 14 Figure 1͑b͒ compares the 10 K PL spectra of the same set of samples, which shows an obvious blue shift of the FX line to 6.06 ͑6.04͒ eV in the AlN epilayer sample ͑polycrystalline AlN͒.…”

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confidence: 99%

“…Samples studied included c-AlN epilayers grown on sapphire by metal organic chemical vapor deposition, polycrystalline c-textured AlN grown by physical vapor transport, and bulk m-AlN single crystals produced by sublimation crystal growth using polycrystalline AlN wafers as seeds. 8 The epilayer, polycrystalline, and bulk AlN samples appear in transparent, light yellow, and amber colors under room light. These samples were determined to contain about 1.5ϫ 10 17 , 1.0ϫ 10 18 , and 2 ϫ 10 18 cm −3 of oxygen impurities, respectively, via SIMS measurements.…”

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confidence: 99%

“…Currently, several groups are developing various techniques for the growth of bulk AlN crystals. [1][2][3][4][5][6][7][8] Recent reports of homoepitaxial layer growth and device fabrication using bulk AlN substrates have already demonstrated potential applications. [6][7][8] Despite recent progress made in nitride epilayers and devices on AlN substrates, critical issues remain.…”

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confidence: 99%

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The origin of 2.78 eV emission and yellow coloration in bulk AlN substrates

Sedhain

Du²,

Edgar³

et al. 2009

Applied Physics Letters

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The yellow color of bulk AlN crystals was found to be caused by the optical absorption of light with wavelengths shorter than that of yellow. This yellow impurity limits UV transparency and hence restricts the applications of AlN substrates for deep UV optoelectronic devices. Here, the optical properties of AlN epilayers, polycrystalline AlN, and bulk AlN single crystals have been investigated using photoluminescence ͑PL͒ spectroscopy to address the origin of this yellow appearance. An emission band with a linewidth of ϳ0.3 eV ͑at 10 K͒ was observed at ϳ2.78 eV. We propose that the origin of the yellow color in bulk AlN is due to a band-to-impurity absorption involving the excitation of electrons from the valence band to the doubly negative charged state, ͑V Al 2− ͒, of isolated aluminum vacancies, ͑V Al ͒ 3−/2− described by V Al 2− +h =V Al 3− +h + . In such a context, the reverse process is responsible for the 2.78 eV PL emission.

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confidence: 82%

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confidence: 99%

mentioning

confidence: 99%

mentioning

confidence: 99%

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The origin of 2.78 eV emission and yellow coloration in bulk AlN substrates

Sedhain

Du²,

Edgar³

et al. 2009

Applied Physics Letters

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“…From samples with non-and semipolar surfaces, however, energies at or below 6.035 eV are found. [16][17][18] These differences cannot be explained by changes in strain and/or impurity concentrations alone. In the following, we will show that a natural and physical interpretation is possible in terms of spin-exchange splitting by distinguishing between C 1 and C 5 excitons.…”

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confidence: 99%

Negative spin-exchange splitting in the exciton fine structure of AlN

Feneberg

Romero

Neuschl

et al. 2013

Applied Physics Letters

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Tuning energy levels in magnesium modified Alq3 J. Appl. Phys. 109, 083541 (2011) Disorder-induced exciton localization and violation of optical selection rules in supramolecular nanotubes J. Chem. Phys. 134, 114507 (2011) Exciton-polariton transmission in quantum dot waveguides and a new transmission path due to thermal relaxation J. Chem. Phys. 134, 044108 (2011) Double excitations in correlated systems: A many-body approach J. Chem. Phys. 134, 034115 (2011) Additional information on Appl. Phys. Lett.

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Valence-band splitting and optical anisotropy of AlN

Rossbach

Röppischer²,

Schley

et al. 2010

phys. stat. sol. (b)

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The dielectric function (DF) of hexagonal AlN on Si (111) is determined in the range between 1 and 9.8 eV by spectroscopic ellipsometry (SE). Due to its large negative crytal-field splitting wurtzite AlN features large dichroism. Showing that SE is sensitive to both components of the DF around the absorption edge, a uniaxial model is applied which yields transition energies for the free excitonic state. The in-plane tensile stress leads to a red-shift of these transitions and to an enlarged splitting. The experimental data are compared to the results of band-structure calculations demonstrating excellent overall agreement. In addition, two high-energy critical points in the ordinary DF were determined at energies of about 7.75 and 8.85 eV.

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Photoluminescence properties of AlN homoepilayers with different orientations

Cited by 30 publications

References 19 publications

The origin of 2.78 eV emission and yellow coloration in bulk AlN substrates

The origin of 2.78 eV emission and yellow coloration in bulk AlN substrates

Negative spin-exchange splitting in the exciton fine structure of AlN

Valence-band splitting and optical anisotropy of AlN

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