High Speed 1550 nm Indium Gallium Arsenide-Indium Phosphide Photodetector

Q4 Engineering

International Journal of High Speed Electronics and Systems Pub Date : 2023-07-20 DOI:10.1142/s0129156423500131

Erik Perez, R. Lacomb, F. Jain

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引用次数: 0

Abstract

This paper presents preliminary results of a high speed 1550 nm indium gallium arsenide (InGaAs)-based mesa-type modified uni-traveling carrier photodiode (M-UTC-PD) structure. Conventional UTC-PD refers to P-I-N type photodiodes which selectively use electrons as active carriers. Photons absorbed in the relatively thin P-type absorber create minority carriers which are field accelerated toward a depleted collector thereby establishing high velocity ballistic transport, making these structures applicable for high speed applications. The M-UTC-PD structure presented uses spatially tailored P-type absorber regions to limit minority carrier generation both in the lateral and axial dimensions. Utilizing an otherwise conventional UTC-PD epitaxial structure where the top P-type layers are undoped, the spatially tailored P-type regions are defined by closed ampoule Zinc diffusion techniques. The M-UTC-PD structure presented utilizes a series of nested p-doped rings within a mesa structure to limit dark current and reduce overall capacitance to improve high speed operation. Two photodiode structures will be investigated for this research project, a conventional UTC-PD structure and a modified structure, utilizing similar device designs, epitaxial designs and fabrication processes. The conventional structure will be utilized for fabrication process development, verification of epi quality and development of rapid prototyping approach toward chip-based testing and subsequent high speed RF testing procedures. Conventional UTC-PD device results will be used as a comparison to quantify the performance of the M-UTC-PD structure utilizing Zn-doped defined p-type absorber regions. Results are given for chip tests of UTC-PD chips verifying epitaxial quality and fabrication process, subsequent testing of packaged devices and RF analysis remains. Process development of the Zn-doped devices is underway, once completed, these devices will be compared to the base design to quantify performance enhancement associated with the modified design.

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1550nm高速铟镓砷化铟磷化铟光电探测器

本文介绍了一种基于高速1550nm砷化铟镓（InGaAs）的台面型改性单行波载流子光电二极管（M-UTC-PD）结构的初步结果。传统的UTC-PD是指选择性地使用电子作为有源载流子的P-I-N型光电二极管。在相对薄的P型吸收体中吸收的光子产生少数载流子，这些载流子被场加速朝向耗尽的收集器，从而建立高速弹道传输，使这些结构适用于高速应用。所提出的M-UTC-PD结构使用空间定制的P型吸收区来限制横向和轴向尺寸中的少数载流子产生。利用传统的UTC-PD外延结构，其中顶部P型层未掺杂，通过封闭安瓿锌扩散技术来定义空间定制的P型区域。所提出的M-UTC-PD结构利用台面结构内的一系列嵌套p掺杂环来限制暗电流并降低总电容以提高高速操作。本研究项目将研究两种光电二极管结构，一种是传统的UTC-PD结构，另一种是改进的结构，利用类似的器件设计、外延设计和制造工艺。传统结构将用于制造工艺开发、epi质量验证以及基于芯片的测试和随后的高速RF测试程序的快速原型方法的开发。常规的UTC-PD器件结果将被用作比较，以量化利用Zn掺杂的限定的p型吸收区的M-UTC-PD结构的性能。给出了UTC-PD芯片测试的结果，验证了外延质量和制造工艺，随后对封装器件进行了测试，并保留了RF分析。Zn掺杂器件的工艺开发正在进行中，一旦完成，这些器件将与基础设计进行比较，以量化与修改设计相关的性能增强。

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来源期刊

International Journal of High Speed Electronics and Systems Engineering-Electrical and Electronic Engineering

CiteScore

0.60

自引率

0.00%

发文量

期刊介绍： Launched in 1990, the International Journal of High Speed Electronics and Systems (IJHSES) has served graduate students and those in R&D, managerial and marketing positions by giving state-of-the-art data, and the latest research trends. Its main charter is to promote engineering education by advancing interdisciplinary science between electronics and systems and to explore high speed technology in photonics and electronics. IJHSES, a quarterly journal, continues to feature a broad coverage of topics relating to high speed or high performance devices, circuits and systems.