基于Pt/CdS与InSb光伏型紫外—红外焦平面探测器的双色探测机理

基于新型的时域有限差分光子学分析方法联合有限元电学分析方法研究了Pt/CdS紫外与InSb 红外双色焦平面阵列探测器的双色探测机理.研究发现超薄 Pt金属膜与CdS形成肖特基结可以获得较大的紫外光响应并能更好耦合红外光.采用像元间距为50 μm的Pt/CdS与InSb键合结构, 可以很好地抑制像元间的串音.结果证明了紫外-红外双色探测的可行性, 该方法将为紫外—红外双色探测器的设计提供基础指导.

Abstract

Based on finite difference time domain method (FDTD) and finite element method (FEM), the mechanism of Pt/CdS and InSb ultraviolet-infrared dual-color focal-plane arrays was investigated. It was found that a high ultraviolet photo response can be achieved for Pt/CdS Schottky junction under an ultrathin Pt top contact. Further simulations show that the ultrathin top contact can efficiently couple the infrared radiation for the dual-color focal-plane array detector. The center to center spacing of each pixel of 50 μm in the ultraviolet and infrared dual-color focal-plane array detector based on Pt/CdS and InSb junctions can significantly reduce crosstalk. Our work provides fundamental guidance for optimization and design of ultraviolet and infrared dual-color detector.

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李庆, 白杰, 吕衍秋, 胡伟达, 陈效双, 陆卫. 基于Pt/CdS与InSb光伏型紫外—红外焦平面探测器的双色探测机理[J]. 红外与毫米波学报, 2017, 36(4): 385. LI Qing, BAI Jie, LV Yan-Qiu, HU Wei-Da, CHEN Xiao-Shuang, LU Wei. Analysis of ultraviolet and infrared dual-color focal-plane array detector based on Pt/CdS and InSb junctions[J]. Journal of Infrared and Millimeter Waves, 2017, 36(4): 385.

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