Optimized structure of single photon avalanche diode with low dark count rate

Jing Pan, Guilan Feng, Tianqi Zhao, Chunlan Lin, T. Chu, Kaiyue Guo, Liangqiang Xu, Jiabao Li, Wankang Wu
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Abstract

In this paper, an optimized structure of single photon avalanche diode (SPAD) with p-i-n construction is presented, and the device is compatible with standard CMOS technology. TCAD software and accurate calculation method based on physics mechanism are employed for the device structure design and DCR calculation, respectively. The characteristic parameters of the device, such as electric field and electron and hole triggering probability, are available through TCAD Atlas device simulation. The central region of P-sub doping is designed as a part of avalanche region, which achieves a lower electric field, and makes the band-to-band tunneling suppressed simultaneously. The breakdown voltage of the SPAD is 38.5 V. At excess bias voltage of 5 V, DCR is 0.88 Hz/μm2 at room temperature. The maximum electric field of the optimized structure is 3.8×105 V/cm. As for PDE, at room temperature with 5.0 V excess bias, the PDE is greater than 30% in the 400 nm-675 nm range, with a peak PDE of 40% at 550 nm. At 850 nm, there is still a photon detection efficiency of more than 10%, making the SPAD still have a certain detection capability. The superior performance of this structure makes it suitable for wide applications.
低暗计数率单光子雪崩二极管的优化结构
本文提出了一种p-i-n结构的单光子雪崩二极管(SPAD)的优化结构,该器件与标准CMOS技术兼容。器件结构设计采用TCAD软件,DCR计算采用基于物理机理的精确计算方法。通过TCAD Atlas器件仿真得到器件的电场、电子和空穴触发概率等特征参数。将P-sub掺杂的中心区域设计为雪崩区的一部分,实现了较低的电场,同时抑制了带间隧道效应。SPAD的击穿电压为38.5 V。在超偏置电压为5 V时,室温DCR为0.88 Hz/μm2。优化后结构的最大电场为3.8×105 V/cm。PDE方面,在室温下5.0 V偏置下,400 nm-675 nm范围内PDE大于30%,在550 nm处峰值PDE为40%。在850 nm处,仍有10%以上的光子探测效率,使得SPAD仍具有一定的探测能力。该结构的优越性能使其具有广泛的应用前景。
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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