TG 沟道中的 Si/SiO2 界面态导致 CMOS 图像传感器中电荷转移不完全

IF 4.8 4区 物理与天体物理 Q2 PHYSICS, CONDENSED MATTER Journal of Semiconductors Pub Date : 2023-11-01 DOI:10.1088/1674-4926/44/11/114104
Xi Lu, Changju Liu, Pinyuan Zhao, Yu Zhang, Bei Li, Zhenzhen Zhang, Jiangtao Xu
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引用次数: 0

摘要

现有 CMOS 制造工艺生产的 CMOS 图像传感器通常难以实现完全的电荷转移,原因是在电荷转移路径中引入了势垒或 Si/SiO2 界面态陷阱,从而降低了电荷转移效率和图像质量。迄今为止,学者们仅从电位势垒和高光照条件下的回溢效应角度考虑了限制电荷转移的机制。然而,迄今为止,现有模型都忽略了转移栅通道中的 Si/SiO2 界面态陷阱所导致的电荷转移限制,尤其是在低照度条件下。因此,本文首次提出了一个分析模型,用于量化低照度条件下转移栅通道中的 Si/SiO2 界面阱所导致的电荷转移不完全。该模型可以预测当陷阱能级遵循高斯分布、指数分布和测量分布时,未转移电荷数量和电荷转移效率的变化规律。该模型通过计算机辅助设计技术仿真进行了验证,结果表明仿真结果与提出的模型一致。
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Incomplete charge transfer in CMOS image sensor caused by Si/SiO2 interface states in the TG channel
CMOS image sensors produced by the existing CMOS manufacturing process usually have difficulty achieving complete charge transfer owing to the introduction of potential barriers or Si/SiO2 interface state traps in the charge transfer path, which reduces the charge transfer efficiency and image quality. Until now, scholars have only considered mechanisms that limit charge transfer from the perspectives of potential barriers and spill back effect under high illumination condition. However, the existing models have thus far ignored the charge transfer limitation due to Si/SiO2 interface state traps in the transfer gate channel, particularly under low illumination. Therefore, this paper proposes, for the first time, an analytical model for quantifying the incomplete charge transfer caused by Si/SiO2 interface state traps in the transfer gate channel under low illumination. This model can predict the variation rules of the number of untransferred charges and charge transfer efficiency when the trap energy level follows Gaussian distribution, exponential distribution and measured distribution. The model was verified with technology computer-aided design simulations, and the results showed that the simulation results exhibit the consistency with the proposed model.
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来源期刊
Journal of Semiconductors
Journal of Semiconductors PHYSICS, CONDENSED MATTER-
CiteScore
6.70
自引率
9.80%
发文量
119
期刊介绍: Journal of Semiconductors publishes articles that emphasize semiconductor physics, materials, devices, circuits, and related technology.
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