Study The Responsory And Quantum Efficiency of Silicon P-N Junction by Using Pulse Plasma

Journal of Education Science Pub Date : 2020-12-01 DOI:10.33899/edusj.2020.167287

Salah Sheet, Mohammad N. Abdulwahab

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Abstract

In this work we have used plasma pulsed injector to prepare a P-N junction. Antimony was deposited on P-type silicon wafer and Indium was deposited on N-type silicon wafer. They were considered as thin film which was bombarded with accelerated hydrogen-ions from the pulsed plasma injector. Optical tests were conducted for the both junctions to evaluate their performance as optical detectors. These include the spectral response quantum efficiency and detectivity. They showed high response and efficiency for the long wavelength in the near IR region. It showed a relatively higher detectivity which increased with the number of discharges. For antimony and indium implanted samples we have noticed an increase in the response time of the detector with the number of discharges. These findings allow the possibility to use them in the near IR-detector and semiconductor lasers in the wavelength range 850-950nm as well as in the applications of optical communication systems. This work also revealed the possibility of using the pulsed plasma injection to modify the material surfaces as well as the ultering the semiconductor surfaces.

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用脉冲等离子体研究硅P-N结的响应和量子效率

在这项工作中，我们使用等离子体脉冲注入器制备了一个P-N结。在p型硅片上沉积了锑，在n型硅片上沉积了铟。它们被认为是被脉冲等离子体注入器的加速氢离子轰击的薄膜。对这两个结进行了光学测试，以评估它们作为光学探测器的性能。这包括光谱响应、量子效率和探测性。它们在近红外波段表现出较高的响应和效率。它显示出相对较高的检出率，检出率随放电次数的增加而增加。对于注入锑和铟的样品，我们注意到探测器的响应时间随着放电次数的增加而增加。这些发现使它们有可能用于近红外探测器和波长范围850-950nm的半导体激光器以及光通信系统的应用。这项工作还揭示了使用脉冲等离子体注入来修饰材料表面以及半导体表面的可能性。

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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Journal of Education Science

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