High-responsivity photoconductive ultraviolet sensors based on insulating single-crystal GaN epilayers

Khan, M. Asif; Kuznia, J. N.; Olson, D. T.; Hove, J. M. Van; Blasingame, M.; Reitz, Larry F.

doi:10.1063/1.106819

Cited by 379 publications

(157 citation statements)

References 7 publications

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“…A frequency dependence of the responsivity has also been detected [7] [11]. Reported data also indicate a very non-linear behavior, with a photoconductive gain decreasing with the optical power [5] [7]. In this work we present a study of the physical mechanism of photoconductive gain in GaN epitaxial layers, and the computer implementation of a novel model that matches our experimental results quite precisely.…”

Section: Introductionmentioning

confidence: 52%

“…Some of the characteristics of GaN photoconductors have been reported. There is a general agreement on the presence of an abnormally high responsivity [5] [6] [9] and persistent photoconductivity [7] [10] [11], which have been tentatively attributed either to deep levels [9] or to Mg-doping related centers [8]. A frequency dependence of the responsivity has also been detected [7] [11].…”

Section: Introductionmentioning

confidence: 78%

“…Photocoductive GaN detectors have early attracted a significant interest [5] [6] [7] [8] [9]. For their simplicity, they are candidates as low cost UV detectors in consumer and environmental applications.…”

Section: Introductionmentioning

confidence: 99%

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Characterization and Modeling of Photoconductive GaN Ultraviolet Detectors

Monroy

Garrido

Muñoz

et al. 1997

MRS Internet j. nitride semicond. res.

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In this work high gain GaN photoconductive UV detectors have been fabricated and characterized, and a novel gain mechanism, dominant in these detectors, is described. DC responsivities higher than 10 3 A/W have been measured for an incident power of lW/m 2 at room temperature. The photoconductive gain depends directly on the bias voltage and scales with incident power as P -k (k ≈ 0.9) for more than five decades. A decrease of both gain and k parameter with temperature has also been observed. As a consequence of the slow non-exponential transient response, AC gain measurements result in lower values for gain and k parameter, which are frequency dependent. The high responsivity, non-linear behavior and slow non-exponential transient response, are all modeled taking into account a modulation mechanism of the layer conductive volume. Such spatial modulation is due to the photovoltaic response of the potential barriers related to the surface and charged dislocations arrays.

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Section: Introductionmentioning

confidence: 52%

Section: Introductionmentioning

confidence: 78%

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Characterization and Modeling of Photoconductive GaN Ultraviolet Detectors

Monroy

Garrido

Muñoz

et al. 1997

MRS Internet j. nitride semicond. res.

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“…A new market thus emerges in the field of telecommunications with High Electronic Mobility Transistors (HEMT's) which can support power densities 10 times higher than those accessible with the silicon and gallium arsenide technologies as reported by Dumka et al [6], as well as cut-off frequencies higher than 100 GHz were reported in a previous paper [7]. These HEMT's structures are essential to meet the increasing needs for the communication systems requiring high power and frequency applications [8][9][10] (radars, stations of bases, connection satellite). Due to their strong thermal conductivity and good performance stability in a hostile environment, GaN-based HEMT devices are excellent candidates especially in high power/frequencies domain.…”

Section: Introductionmentioning

confidence: 99%

Electrical Characterization of Traps in AlGaN/GaN FAT-HEMT’s on Silicon Substrate by C-V and DLTS Measurements

Charfeddine¹,

Gassoumi²,

Mosbahi³

et al. 2011

JMP

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We investigate high electron mobility transistors (HEMT's) based on AlGaN/GaN grown by molecular beam epitaxy on Silicon substrates. The improvement of the performances of such transistors is still subject to the influence of threading dislocations and point defects which are commonly observed in these devices. Deep levels in FAT-HEMT's are characterized by using Capacitance-Voltage (C-V) measurements, from which we can extract the barrier height and the donor concentration in the AlGaN layer. Deep Level Transient Spectroscopy (DLTS) Technique is also employed to identify defects in the heterostructure. Measurements reveal the presence of one electron trap with the activation energy E 1 = 0.30 eV and capture cross-section σ n = 3.59 × 10 -19 cm 2 . The localization and the identification of this trap have been discussed.

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“…These electronic and optoelectronic devices included visible light-emitting diodes (LED) [1], metal semiconductor field effects transistors (MESFET) [2], high electron mobility transistors (HEMT) [3], UV photoconductive detectors [4], and UV photovoltaic detectors [5]. The fabrication of the devices requires performing a controlled and reproducible n-and p-type doping.…”

Section: Introductionmentioning

confidence: 99%

Fabrication and Characterization of GaN/Polymer Composite p-n Junction with PEDOT Nanoparticle Interface Layer

et al. 2011

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A heavily Si-doped GaN/polymer hybrid structure with p-type poly(3,4-ethylene-dioxythiophene):beta-1,3--glucan (PEDOT nanoparticle) interface layer has been fabricated. The Si-doped GaN thin film with carrier concentration of 1 × 10 19 cm −3 was grown by metal-organic chemical vapor deposition. The PEDOT nanoparticle with various sizes ranging from 60 to 120 nm was synthesized via a miniemulsion polymerization process. The electrical conductivity of the PEDOT nanoparticle is less than 1.2 S/cm. The current-voltage (I-V ) characteristic of the hybrid structure shows diode-like behavior. The I-V characteristic was examined in the framework of the thermionic emission model. The ideality factor of the structure without PEDOT nanoparticle interface layer is 12.9. However, the ideality factor of the hybrid structure with PEDOT nanoparticle interface layer is obtained as 1.9. The value of ideality factor is dramatically decreased by inserting the PEDOT nanoparticle interface layer.

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High-responsivity photoconductive ultraviolet sensors based on insulating single-crystal GaN epilayers

Cited by 379 publications

References 7 publications

Characterization and Modeling of Photoconductive GaN Ultraviolet Detectors

Characterization and Modeling of Photoconductive GaN Ultraviolet Detectors

Electrical Characterization of Traps in AlGaN/GaN FAT-HEMT’s on Silicon Substrate by C-V and DLTS Measurements

Fabrication and Characterization of GaN/Polymer Composite p-n Junction with PEDOT Nanoparticle Interface Layer

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