Deep centers in n-GaN grown by reactive molecular beam epitaxy

Fang, Z-Q.; Look, David C.; Kim, Wonsuck; Fan, Z.; Botchkarev, A.; Morkoç̌, H.

doi:10.1063/1.121274

Cited by 141 publications

(73 citation statements)

References 10 publications

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“…Therefore, in our case, we believe that the plasma treatments do not cause any meaningful increase in dislocation density, even under an etching biasvoltage of Ϫ150 V. Trap D, with E T ϭ0.23-0.27 eV and n ϭ(1 -2)ϫ10 Ϫ15 cm 2 , has been observed in thin GaN layers by many groups, using various techniques, including hydride vapor phase epitaxy ͑HPVE͒, [8][9][10] MOCVD, [11][12][13] and MBE. 14,15 Three of these studies are consistent with the proposition that trap D is at least sometimes related to threading dislocations. For example, the concentration of trap D in HVPE GaN increases with increasing dislocation density, corresponding to decreasing epilayer thickness.…”

supporting

confidence: 72%

Plasma-etching-enhanced deep centers in n-GaN grown by metalorganic chemical-vapor deposition

Fang

Wang

Han

et al. 2003

Applied Physics Letters

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By using deep-level transient spectroscopy (DLTS), deep centers have been characterized in unintentionally doped n-GaN samples grown by metalorganic chemical-vapor deposition and subjected to inductively coupled plasma reactive ion etching. At least six DLTS traps exist in the control sample: A1 (∼0.90 eV), Ax (∼0.72 eV), B (0.61 eV), C1 (0.44 eV), D (0.25 eV), and E1 (0.17 eV), with B dominant. Then, as the etching bias-voltage increases from −50 to −150 V, trap D increases strongly and becomes dominant, while traps A1, C (0.34 eV), and E1 increase at a slower rate. Trap B, on the other hand, is nearly unchanged. Previous electron-irradiation studies are consistent with the E1 traps being N-vacancy related. It is likely that the D traps are also, except that they are in the regions of dislocations.

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confidence: 72%

Plasma-etching-enhanced deep centers in n-GaN grown by metalorganic chemical-vapor deposition

Fang

Wang

Han

et al. 2003

Applied Physics Letters

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“…Presently, the main wide band gap materials for space applications are considered to be the III-V nitrides, SiC, and diamond. Whereas the effect of high-energy electron irradiation has been reported for ZnO, 3 GaN, 4,5 and SiC, 6 no data are yet available regarding the exposure of ZnO to heavier particles such as protons and He-ions, as was reported for GaN. 7,8 In particular, to our knowledge, data pertaining to radiation-and implantation-induced deep level defects in ZnO are not yet available.…”

mentioning

confidence: 63%

Electrical characterization of 1.8 MeV proton-bombarded ZnO

Auret

Goodman

Hayes

et al. 2001

Applied Physics Letters

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177

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We report on the electrical characterization of single-crystal ZnO and Au Schottky contacts formed thereon before and after bombarding them with 1.8 MeV protons. From capacitance–voltage measurements, we found that ZnO is remarkably resistant to high-energy proton bombardment and that each incident proton removes about two orders of magnitude less carriers than in GaN. Deep level transient spectroscopy indicates a similar effect: the two electron traps detected are introduced in extremely low rates. One possible interpretation of these results is that the primary radiation-induced defects in ZnO may be unstable at room temperature and anneal out without leaving harmful defects that are responsible for carrier compensation.

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“…Evaluating this ex-pression requires knowledge of the room temperature capture cross section of the traps being investigated in this work. While such data are not available for the traps considered here, capture cross sections in HR and n-type GaN have been reported [23][24][25] in a broad range from roughly 10 Ϫ23 cm 2 to 10 Ϫ15 cm 2 . Polyakov et al 25 have reported capture cross sections for GaN near room temperature for the E2 center ͓ c (278 K)ϭ4ϫ10 Ϫ20 cm 2 ] and the E4 center ͓ c (385 K)ϭ3.3ϫ10 Ϫ23 cm 2 ].…”

Section: ͑29͒mentioning

confidence: 99%

Photoionization spectroscopy of traps in GaN metal-semiconductor field-effect transistors

Klein¹,

Binari²,

Freitas³

et al. 2000

Journal of Applied Physics

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Measurements of the spectral and intensity dependences of the optically-induced reversal of current collapse in a GaN metal-semiconductor field-effect transistor ͑MESFET͒ have been compared to calculated results. The model assumes a net transfer of charge from the conducting channel to trapping states in the high-resistivity region of the device. The reversal, a light-induced increase in the trap-limited drain current, results from the photoionization of trapped carriers and their return to the channel under the influence of the built-in electric field associated with the trapped charge distribution. For a MESFET in which two distinct trapping centers have been spectrally resolved, the experimentally measured dependence upon light intensity was fitted using this model. The two traps were found to have very different photoionization cross-sections but comparable concentrations (4ϫ10 11 cm Ϫ2 and 6ϫ10 11 cm Ϫ2 ͒, suggesting that both traps contribute comparably to the observed current collapse. ͓S0021-8979͑00͒00417-5͔

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Deep centers in n-GaN grown by reactive molecular beam epitaxy

Cited by 141 publications

References 10 publications

Plasma-etching-enhanced deep centers in n-GaN grown by metalorganic chemical-vapor deposition

Plasma-etching-enhanced deep centers in n-GaN grown by metalorganic chemical-vapor deposition

Electrical characterization of 1.8 MeV proton-bombarded ZnO

Photoionization spectroscopy of traps in GaN metal-semiconductor field-effect transistors

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