AlGaN Ultraviolet A and Ultraviolet C Photodetectors with Very High Specific Detectivity D<sup>*</sup>

Albrecht, Björn; Kopta, Susanne; John, Oliver; Kirste, Lutz; Driad, R.; Köhler, K.; Walther, M.; Ambacher, O.

doi:10.7567/jjap.52.08jb28

Cited by 27 publications

(21 citation statements)

References 20 publications

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“…1, are grown on c-plane sapphire substrates: a high temperature AlN nucleation, Al x Ga 1-x N buffer layers, a Si-doped n-Al x Ga 1-x N layer, an unintentially doped i-Al x Ga 1-x N layer, and a Mg-doped p-Al x Ga 1-x N layer including a Mg-doped p-GaN cap. Details of material growth, material characterization, and processing into UV photodetector chips have already been published previously [11]. We deliberately avoid the use of epitaxial lateral overgrowth (ELO), homoepitaxy on AlN substrates, selected area growth, or multilayer growth for defect reduction to keep the growth and fabrication of our photodetectors as simple, cost-efficient, and reliable as possible [12]- [17].…”

Section: Methodsmentioning

confidence: 99%

“…The slight increase in dark current of the UV-C photodetector starting at -2 V bias is due to point defect induced hopping of charge carriers [1]. The number of point defects increases in Al x Ga 1-x N with an Al content around 50 % due to non-optimal growth conditions [11], i.e. the effect is enhanced at UV-C photodetectors with an Al content of 45 and 62 % in the active region.…”

Section: B I-v Dependencymentioning

confidence: 99%

“…The noticeable high series resistance of the UV-C photodetectors results from a low conductivity of the n-doped Al x Ga 1-x N layer. Consequently, the n-contact resistance shows non-ohmic behavior [11]. We achieve ohmic behavior for each p-contact by growing a p-doped GaN cap layer on top of the p-Al x Ga 1-x N layer, as demonstrated elsewhere [11].…”

Section: B I-v Dependencymentioning

confidence: 99%

“…Consequently, the n-contact resistance shows non-ohmic behavior [11]. We achieve ohmic behavior for each p-contact by growing a p-doped GaN cap layer on top of the p-Al x Ga 1-x N layer, as demonstrated elsewhere [11]. The ideality factor n of the various Al x Ga 1-x N photodetectors, shown in Table I, can differ from that of Si photodiodes, where n ranges from 1 to 2, for two reasons: First, the recombination current dominates in Al x Ga 1-x N photodiodes.…”

Section: B I-v Dependencymentioning

confidence: 99%

“…These small area pixels are not suitable for various applications such as luminescence spectroscopy or flame sensors due to a small radiation signal leading to a very small photocurrent [1]. Based on our high quality AlN buffer layer concept [11], we process epitaxially grown Al x Ga 1-x N layers into visible-and solar-blind p-i-n photodetectors, specifically designed to the UV-A, UV-B, and UV-C spectral region. We present photocurrent and response time measurements, I-V characterization, and degradation studies of our p-i-n photodiodes, which result in a superior overall performance compared to the state-of-the-art.…”

Section: Introductionmentioning

confidence: 99%

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Improved AlGaN p-i-n Photodetectors for Monitoring of Ultraviolet Radiation

Albrecht

Kopta

John

et al. 2014

IEEE J. Select. Topics Quantum Electron.

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Improved Aluminum-Gallium-Nitride p-i-n photodetectors with different active regions are reported, designed for the measurement of UV-A (315 to 380 nm), UV-B (280 to 315 nm), and UV-C (< 280 nm) radiation. The spectral responsivity of Al x Ga 1-x N photodetectors can be tailored by bandgap engineering of the Al x Ga 1-x N layers and integration of filter layers. Intrinsically visible-blind p-i-n photodetectors are measured on-wafer and packaged in TO-18 headers. Photocurrent measurements in photovoltaic mode result in responsivity values of up to 0.21 A/W for UV-A (EQE = 70 %), 0.14 A/W for UV-B (EQE = 56 %), and 0.11 A/W for UV-C (EQE = 57 %), respectively. Room temperature dark current density values as low as 30 pA/cm² at a reverse bias of -3 V yield a specific detectivity of more than 4×10 14 cmHz 0.5 /W. Response time data of the p-i-n photodiodes indicate a rise time of 1.7 ns and a fall time (1/e) of 4.5 ns. Long term stability tests over 1000 h at an irradiance of 5 W/cm² demonstrate the potential of these photodetectors for demanding applications such as the continuous monitoring of high irradiance ultraviolet light sources. Index Terms-Aluminum gallium nitride, p-i-n diodes, Semiconductor epitaxial layers, Ultraviolet photodetectors. 1077-260X (c)

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Section: Methodsmentioning

confidence: 99%

Section: B I-v Dependencymentioning

confidence: 99%

Section: B I-v Dependencymentioning

confidence: 99%

Section: B I-v Dependencymentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Improved AlGaN p-i-n Photodetectors for Monitoring of Ultraviolet Radiation

Albrecht

Kopta

John

et al. 2014

IEEE J. Select. Topics Quantum Electron.

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Polarization enhanced photoresponse of AlGaN p-i-n photodetectors

Yang

Lai

Zhang

et al. 2015

Phys. Status Solidi A

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We fabricated an enhanced photoresponse AlGaN p-i-n photodetector by introducing a polarization electric field along the growth direction into the active layer. The polarizationenhanced effect was realized by reducing Al composition of the p-AlGaN layer with respect to that of the i-and n-type layers. The simulated results of energy-band structure and electric-field distribution indicate that the polarizationenhanced structure can increase greatly the build-in field in the active region and hence improve the collection efficiency of photogenerated carriers. The measured photocurrent spectra show that the polarization-enhanced photodetector exhibits a nearly three times higher responsivity and a larger UV/visible contrast than its conventional counterpart. 1 Introduction Wide-bandgap Al x Ga 1À x N alloys attract increasing interest in the fabrication of ultraviolet (UV) photodetectors thanks to their direct bandgap energy, which can be tuned from 6.2 to 3.4 eV by changing the Al/ Ga composition ratio [1,2]. This energy region corresponds to a photon wavelength range of 200-365 nm. Particularly in the range of UV-B (320-280 nm) and UV-C (below 280 nm), AlGaN alloys are of irreplaceable advantages in fabricating solid photodetectors because they are intrinsically blind to photons with wavelengths longer than that of the bandgap of the active layer, which is suitable for the operation in the visible-blind or solar-blind regions without filters being needed. Over the past decade, different types of AlGaN detectors, including photoconductors [3], Schottky metal-semiconductor-metal and barrier detectors [4][5][6][7], pi-n photodiodes [8][9][10], and avalanche photodiodes [11][12][13], have been developed successfully and even partially

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Top‐ and bottom‐illumination of solar‐blind AlGaN metal–semiconductor–metal photodetectors

Brendel

Helbling

Knauer

et al. 2015

Physica Status Solidi (a)

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The spectral performance of solar-blind Al x Ga 1-x N based metal-semiconductor-metal ultra-violet photodetectors has been measured for top-as well as bottom-illumination at different bias voltages. In the bottom-illumination case the external quantum efficiency spectra can be tuned between a peak or a broad wavelength spectrum by adjusting absorber layer thickness and applied bias voltage. For thin absorber layers the external quantum efficiency is enhanced by a factor of three, reaching 20% quantum efficiency at 20 V bias, compared to the front-illumination case. Results of twodimensional device simulations are well in agreement with the experimental findings. From these simulations it can be concluded, that the different spectral response for top-and bottom-illumination results from the different overlap of optical carrier generation by absorption and carrier transport by the electric field.Spectra of external quantum efficiency of solar-blind metalsemiconductor-metal photodetectors upon top-illumination (dashed) and bottom-illumination (continuous) at 1 V, 5 V, and 20 V bias voltage. The Al 0.5 Ga 0.5 N absorber layers of different thickness d Abs were grown on AlN/sapphire templates.

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AlGaN Ultraviolet A and Ultraviolet C Photodetectors with Very High Specific Detectivity D^*

Cited by 27 publications

References 20 publications

Improved AlGaN p-i-n Photodetectors for Monitoring of Ultraviolet Radiation

Improved AlGaN p-i-n Photodetectors for Monitoring of Ultraviolet Radiation

Polarization enhanced photoresponse of AlGaN p-i-n photodetectors

Top‐ and bottom‐illumination of solar‐blind AlGaN metal–semiconductor–metal photodetectors

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AlGaN Ultraviolet A and Ultraviolet C Photodetectors with Very High Specific Detectivity D*

Cited by 27 publications

References 20 publications

Improved AlGaN p-i-n Photodetectors for Monitoring of Ultraviolet Radiation

Improved AlGaN p-i-n Photodetectors for Monitoring of Ultraviolet Radiation

Polarization enhanced photoresponse of AlGaN p-i-n photodetectors

Top‐ and bottom‐illumination of solar‐blind AlGaN metal–semiconductor–metal photodetectors

Contact Info

Product

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About

AlGaN Ultraviolet A and Ultraviolet C Photodetectors with Very High Specific Detectivity D^*