Design of high sensitivity detector for underwater communication system

Optics/Photonics in Security and Defence Pub Date : 2013-11-05 DOI:10.1117/12.2031953

J. S. Cheong, J. Ong, J. S. Ng, A. Krysa, F. Bastiman, J. David

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引用次数: 5

Abstract

Al0.52In0.48P is the largest bandgap material in III-V non-nitride semiconductors that is lattice matched to a readily available substrate (GaAs). Having a bandgap narrower than that of GaN enables it to detect wavelengths around 480 nm. Such wavelengths have the best transmittance underwater and may be used as a carrier in underwater communication systems. We present an Al0.52In0.48P homo-junction Separate-Absorption-Multiplication-Avalanche-Photodiode (SAMAPD) as a high sensitivity detector for such an application. By increasing the neutral and space-charge region thicknesses, the peak response wavelength can be tuned to longer wavelengths with a narrower full-width-half-maximum (FWHM). The quantum efficiency of the detector reduces with FWHM and this is compensated by having an avalanche gain. At room temperature, the SAM-APD has a dark current of <20 pA for a 210 μm radius device up to 99.9% of breakdown voltage. The structure gives a narrow spectral FWHM of 22 nm with centre wavelength of 482 nm. An external quantum efficiency of 33% and 6410% at 482 nm is obtained at bias voltage of -19 V and -92.6 V respectively.

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水下通信系统高灵敏度探测器的设计

Al0.52In0.48P是III-V非氮化物半导体中最大的带隙材料，它与现成的衬底(GaAs)晶格匹配。具有比GaN更窄的带隙，使其能够检测约480 nm的波长。这种波长在水下具有最佳的透过率，可以用作水下通信系统中的载波。我们提出了一种Al0.52In0.48P同质结分离吸收倍增雪崩光电二极管(SAMAPD)作为这种应用的高灵敏度探测器。通过增加中性区和空间电荷区厚度，可以将峰值响应波长调谐到更长的波长，并减小全宽半最大值(FWHM)。探测器的量子效率随着FWHM的减小而降低，这可以通过雪崩增益来补偿。在室温下，对于半径为210 μm的器件，SAM-APD的暗电流<20 pA，可达击穿电压的99.9%。该结构的FWHM为22 nm，中心波长为482 nm。在偏置电压为-19 V和-92.6 V时，在482 nm处的外量子效率分别为33%和6410%。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Optics/Photonics in Security and Defence

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