Ga
                N
                ∕
                Al
                Ga
                N
           ultraviolet/infrared dual-band detector

Ariyawansa, G.; Rinzan, M. B. M.; Alevli, Mustafa; Straßburg, Martin; Dietz, N.; Perera, A. G. U.; Matsik, S. G.; Asghar, Ali; Ferguson, Ian T.; Luo, Hui; Bezinger, A.; Liu, H. C.

doi:10.1063/1.2345226

Cited by 69 publications

(49 citation statements)

References 18 publications

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“…On the other hand, the Si impurity-related transition can lead to an increased dark current for a detector designed to operate in a shorter wavelength region. A similar response was also reported for the previous GaN/Al 0.026 Ga 0.974 N HEIWIP detector [21].…”

Section: Resultssupporting

confidence: 79%

“…In comparison with UV detectors, the reported GaN/ AlGaN HEIWIP UV/IR dual-band detectors (previous [21] and current) have much lower UV responses. The probable cause for the low UV response is the high absorption of UV radiation within the 0.2 lm thick top-contact layer.…”

Section: Resultsmentioning

confidence: 91%

“…The oscillations in the response spectrum can be fitted with Fabri-Perot interference in the structure. The experimental and calculated thresholds of the detector reported in this article and a similar GaN/Al 0.026 Ga 0.974 N detector reported previously [21] in both UV and IR regions is shown in Fig. 6.…”

Section: Resultsmentioning

confidence: 93%

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Performance improvements of ultraviolet/infrared dual-band detectors

Perera

Ariyawansa

Rinzan

et al. 2007

Infrared Physics & Technology

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Section: Resultssupporting

confidence: 79%

Section: Resultsmentioning

confidence: 91%

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Performance improvements of ultraviolet/infrared dual-band detectors

Perera

Ariyawansa

Rinzan

et al. 2007

Infrared Physics & Technology

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“…which should be used for any reference to this work onstrations include solutions based on AlGaN/GaN [3], Si/p-Si [4], and GaAs/p-GaAs layer stacks [5] using interband absorption for the shorter detection wavelength and free-carrier absorption for the longer wavelength. In addition, multi-color detectors based on bias voltage switching and using excited states in either quantum dots or minibands have been proposed and characterized [6][7][8].…”

Section: Published Inmentioning

confidence: 99%

Monolithically integrated UV/IR‐photodetectors based on an AlN/GaN‐based superlattice grown on an AlGaN buffer layer

Hofstetter

Baumann

Giorgetta

et al. 2009

Phys. Status Solidi (c)

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In this article, we demonstrate closely spaced, monolithically integrated photodetectors in two largely different wavelength ranges. The epitaxial structure of the devices was grown by plasma‐assisted molecular‐beam epitaxy on an AlN‐on‐sapphire template; it consists of a Si‐doped AlGaN thin film, and a nearly strain compensated 40 period AlN/GaN superlattice with 1.0 nm thick GaN quantum wells and 2.0 nm thick AlN barriers. The entire structure is covered with an AlGaN cap layer. The superlattice acts as active region for the infrared detector, while the AlGaN buffer layer serves as active area for the ultraviolet detector. While the photovoltaic near‐infrared detector has a center wavelength of 1.37 μm, the photoconductive ultraviolet detector has a long wavelength cutoff at 250 nm. The two detectors could be operated up to room temperature with reasonable sensitivities. (© 2009 WILEY‐VCH Verlag GmbH & Co. KGaA, Weinheim)

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“…Dual band detectors operating in the NIR and MIR/far-infrared (FIR) regions [9][10][11] based on the group III-As material system have been reported. Previously a detector responding in both the UV and MIR ranges was reported, 12 however, the detector needed separate modulation to distinguish UV and IR radiation. Here results are reported on a detector capable of operating in both the UV and 8-14 µm IR spectral ranges simultaneously without separately modulating the incident radiation, thus eliminating the difficulties of assembling several detectors when multiband detection is required.…”

Section: Introductionmentioning

confidence: 99%

Dual band HEIWIP detectors with nitride materials

et al. 2007

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Detection of both UV and IR radiation is useful for numerous applications such as firefighting and military sensing. At present, UV and IR dual wavelength band detection requires separate detector elements. Here results are presented for a GaN/AlGaN single detector element capable of measuring both UV and IR response. The initial detector used to prove the dualband concept consists of an undoped AlGaN barrier layer between two highly doped GaN emitter/contact layers. The UV response is due to interband absorption in the AlGaN barrier region producing electron-hole pairs which are then swept out of the barrier by an applied electric field and collected at the contacts. The IR response is due to free carrier absorption in the emitters and internal photoemission over the work function at the emitter barrier interface, followed by collection at the opposite contact. The UV threshold for the initial detector was 360 nm while the IR response was in the 8-14 micron range. Optimization of the detector to improve response in both spectral ranges will be discussed. Designs capable of distinguishing the simultaneously measured UV and IR by using three contacts and separate IR and UV active regions will be presented. The same approach can be used with other material combinations to cover additional wavelength ranges, e.g. GaAs/AlGaAs NIR-FIR dual band detectors.

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Ga N ∕ Al Ga N ultraviolet/infrared dual-band detector

Cited by 69 publications

References 18 publications

Performance improvements of ultraviolet/infrared dual-band detectors

Performance improvements of ultraviolet/infrared dual-band detectors

Monolithically integrated UV/IR‐photodetectors based on an AlN/GaN‐based superlattice grown on an AlGaN buffer layer

Dual band HEIWIP detectors with nitride materials

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