Analysis and modeling of AlxGa1−xN-based Schottky barrier photodiodes

Monroy, E.; Calle, F.; Pau, J. L.; Sánchez, F. J.; Muñoz, E.; Omnès, F.; Beaumont, B.; Gibart, P.

doi:10.1063/1.1305838

Cited by 104 publications

(64 citation statements)

References 44 publications

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“…It can be seen from the left inset of Fig. 14 that the inverse square root of intensity increases linearly for all temperatures. The temperature dependence of rate, R, can be used to determine the activation energy of the irradiation-induced processes according to equation (15). On the other hand, our earlier studies of the temperature-induced CL intensity decay (Sec.…”

Section: Optical Studies Of Bulk Znomentioning

confidence: 99%

“…The relationship between minority carrier diffusion length and responsivity of Schottky photodiodes has been examined in great detail in Ref. [15]. Schottky photodiodes are among the simplest photovoltaic devices, where the non-equilibrium minority carriers, generated in the bulk of the semiconductor due to light absorption, are collected by the built-in field of the Schottky barrier deposited on the surface of the semiconductor.…”

Section: Cathodoluminescencementioning

confidence: 99%

“…Since only the carriers within a few diffusion lengths of the space-charge region contribute to photocurrent, the responsivity at below-bandgap energies is limited by the diffusion length (unless the diffusion length exceeds the thickness of the absorber layer, in which case the latter is the limiting factor) [15].…”

Section: Cathodoluminescencementioning

confidence: 99%

See 2 more Smart Citations

Cathodoluminescence Studies of Electron Injection Effects in Wide-Band-Gap Semiconductors

Schwarz¹,

Chernyak²,

Flitsiyan³

2012

Cathodoluminescence

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Section: Optical Studies Of Bulk Znomentioning

confidence: 99%

Section: Cathodoluminescencementioning

confidence: 99%

See 1 more Smart Citation

Cathodoluminescence Studies of Electron Injection Effects in Wide-Band-Gap Semiconductors

Schwarz¹,

Chernyak²,

Flitsiyan³

2012

Cathodoluminescence

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“…[2][3][4][15][16][17][18][19] One interest of electrical studies is to confirm the presence of the Mg dopants and their electrical activity, and to deduce microscopic parameters such as ionization energies, capture cross sections, spatial concentration profiles, etc. Another interest is to contribute to the basic understanding of the conduction mechanism in these structures as the performances of the various electronic and optoelectronic devices depend on the efficiency of the current injection and of the carrier generation or carrier recombination.…”

Section: Introductionmentioning

confidence: 99%

Thermal admittance spectroscopy of Mg-doped GaN Schottky diodes

Nguyen

Germain

Schmeits

et al. 2001

Journal of Applied Physics

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Thermal admittance spectroscopy measurements at temperatures ranging from room temperature to 90 K are performed on Schottky structures based on Mg-doped GaN layers grown by metalorganic vapor phase epitaxy on sapphire. The analysis of the experimental data is made by a detailed theoretical study of the steady-state and small-signal electrical characteristics of the structures. Numerical simulations are based on the solution of the basic semiconductor equations for the structure consisting of two Schottky diodes connected back to back by a conduction channel formed by the GaN layer. The description explicitly includes the Mg-related acceptor level, with its temperature-and position-dependent incomplete occupation state, leading to a dynamic exchange with the valence band. It fully reproduces the variations with temperature of the capacitancefrequency and conductance over frequency curves, allowing to give for all temperature ranges the origin of the various contributions to the junction capacitance and of the microscopic mechanisms responsible for the capacitance-frequency cutoff. Series resistance effects are shown to be dominant at temperatures above 230 K, whereas the Mg-related acceptor level governs the electrical behavior below 230 K. The existence of a second acceptor level with an activation energy of several tens of meV is revealed from the analysis of the characteristics at low temperature. An optimized fitting procedure based on the comparison of the electrical characteristics obtained from the numerical simulations to the experimental data allows one to determine the microscopic parameters describing the structure, among which the acceptor activation energies, thermal capture cross sections, concentrations, and the Schottky contact barrier heights are the most important ones. The obtained activation energy of the Mg-acceptor level of 210 meV is by a factor of 2 larger than that obtained from a classical Arrhenius plot, showing that a complete description of Mg-doped GaN junctions requires the correct treatment of the Mg level, acting as a dopant and as deep impurity, as well as the inclusion of series resistance effects.

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“…2 Moreover, its intrinsic solar blindness ͑for x у0.38) and the ability of operation under harsh conditions ͑high-temperature and high power levels͒ due to its wide band gap makes Al x Ga 1Ϫx N-based photodetectors attractive for high-performance solar-blind detection applications. Several research groups have demonstrated successful solarblind operation with Al x Ga 1Ϫx N photodetectors using photoconductive, 3,4 p -i -n, [5][6][7][8][9][10][11][12][13][14] metal-semiconductormetal ͑MSM͒, 15,16 and Schottky [17][18][19][20] detector structures. Cutoff wavelengths ( c ) as short as ϳ225 nm, an ultraviolet/ visible rejection over 5 orders of magnitude along with responsivities as high as 0.12 A/W at 232 nm were reported using a Al 0.7 Ga 0.3 N p -i -n detector structure.…”

mentioning

confidence: 99%

Solar-blind AlGaN-based Schottky photodiodes with low noise and high detectivity

Bıyıklı

Aytür

Kimukin

et al. 2002

Applied Physics Letters

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Cataloged from PDF version of article.We report on the design, fabrication, and characterization of solar-blind Schottky photodiodes with low noise and high detectivity. The devices were fabricated on n-/n+ AlGaN/GaN heterostructures using a microwave compatible fabrication process. True solar-blind operation with a cutoff wavelength of similar to274 nm was achieved with Al(x)Ga(1-x)N (x=0.38) absorption layer. The solar-blind detectors exhibited <1.8 nA/cm(2) dark current density in the 0-25 V reverse bias regime, and a maximum quantum efficiency of 42% around 267 nm. The photovoltaic detectivity of the devices were in excess of 2.6x10(12) cm Hz(1/2)/W, and the detector noise was 1/f limited with a noise power density less than 3x10(-29) A(2)/Hz at 10 kHz. (C) 2002 American Institute of Physics

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Analysis and modeling of AlxGa1−xN-based Schottky barrier photodiodes

Cited by 104 publications

References 44 publications

Cathodoluminescence Studies of Electron Injection Effects in Wide-Band-Gap Semiconductors

Cathodoluminescence Studies of Electron Injection Effects in Wide-Band-Gap Semiconductors

Thermal admittance spectroscopy of Mg-doped GaN Schottky diodes

Solar-blind AlGaN-based Schottky photodiodes with low noise and high detectivity

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