Carrier-Resolved Photo-Hall Effect: Unlocking a 140-year-old secret in Hall effect

2020 47th IEEE Photovoltaic Specialists Conference (PVSC) Pub Date : 2020-06-14 DOI:10.1109/PVSC45281.2020.9300483

O. Gunawan, S. Pae, Douglas M. Bishop, B. Shin, Yudistira Virgus, D. Mitzi

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引用次数: 1

Abstract

Majority and minority carrier properties such as type, density and mobility represent fundamental yet difficult to access parameters governing semiconductor device performance, most notably solar cells. Obtaining this information simultaneously under light illumination would unlock many critical parameters such as recombination lifetime, recombination coefficient, and diffusion length; while deeply interesting for optoelectronic devices, this goal has remained elusive. We demonstrate here a new carrier-resolved photo-Hall technique that rests on a new equation relating hole-electron mobility difference ($\Delta\mu$), Hall coefficient ($H$), and conductivity ($\sigma$), and a rotating parallel dipole line ac-field Hall system with Fourier/lock-in detection for clean Hall signal measurement [1]. We successfully apply this technique to recent world-record-quality perovskite film and map the results against varying light intensities, demonstrating unprecedented simultaneous access to the above-mentioned parameters.

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载波分辨率照片霍尔效应:在霍尔效应中解开140年的秘密

多数载流子和少数载流子的性质，如类型、密度和迁移率，代表了控制半导体器件性能的基本但难以获得的参数，尤其是太阳能电池。在光照条件下同时获得这些信息将解锁许多关键参数，如复合寿命、复合系数和扩散长度;虽然光电器件非常有趣，但这一目标仍然难以实现。我们在这里展示了一种新的载流子分辨光霍尔技术，该技术基于一个新的空穴电子迁移率差($\Delta\mu$)、霍尔系数($H$)和电导率($\sigma$)的方程，以及一个旋转平行偶极子线交流场霍尔系统，该系统具有用于清洁霍尔信号测量的傅里叶/锁定检测[1]。我们成功地将这项技术应用于最近的世界纪录质量的钙钛矿薄膜，并在不同的光强度下绘制结果，展示了前所未有的同时访问上述参数。

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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2020 47th IEEE Photovoltaic Specialists Conference (PVSC)

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