Modeling and Bulk Characterization of 4HSIC Radiation Detector in Sentaurus TCAD Simulation Environment

Dutse Journal of Pure and Applied Sciences Pub Date : 2024-04-24 DOI:10.4314/dujopas.v10i1c.19

I.I. Garba, R. Nasiru, Y.M. Abubakar, U. Shehu

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Abstract

This paper gives an insight into the need for radiation detection and the most commonly flexible and efficient radiation detector. It also examines bulk characteristics of 4H-SiC semiconductor radiation detector with Ni and Ti as metals for the contact. Bulk characterization of the device, including: doping concentration, electrons and holes behaviors, space charge and current densities were carried out. The modeling is conducted using Sentaurus Technology Computer Aided Design (TCAD) to examine charge transport in bulk 4HSiC material. Data obtained were further analyzed through Sentaurus visual, sentaurus Techplot and Excel to clearly determine the characteristics of the device. It is observed that when the semiconductor and metal are in contact, the Fermi-level is established where the doping concentration varied with either magnitude of the doping concentration or nature of the dopant. Similarly, Schottky and ohmic contacts and temperature effect were observed from the device characteristics which demonstrate that, the detector can withstand a temperature from the range of 100K to 700K in no fluctuating state.

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在 Sentaurus TCAD 仿真环境中对 4HSIC 辐射探测器进行建模和批量表征

本文深入探讨了辐射探测的需求以及最常用的灵活高效的辐射探测器。本文还研究了以镍和钛金属为接触材料的 4H-SiC 半导体辐射探测器的体特性。研究还对器件的体积特性进行了分析，包括：掺杂浓度、电子和空穴行为、空间电荷和电流密度。使用 Sentaurus 技术计算机辅助设计（TCAD）进行建模，以检查 4HSiC 块体材料中的电荷传输。获得的数据通过 Sentaurus Visual、sentaurus Techplot 和 Excel 进行了进一步分析，以明确确定器件的特性。结果表明，当半导体和金属接触时，费米级是随着掺杂浓度的大小或掺杂剂的性质而变化的。同样，从器件特性中还观察到肖特基和欧姆接触以及温度效应，这表明探测器可以承受 100K 至 700K 范围内的温度，且无波动状态。

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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Dutse Journal of Pure and Applied Sciences

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