利用低能扫描电子显微镜和传导原子力显微镜量化砷化镓纳米结构中的掺杂。

IF 1.5 4区工程技术 Q3 MICROSCOPY

Journal of microscopy Pub Date : 2024-01-18 DOI:10.1111/jmi.13263

Ran Guo, Thomas Walther

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引用次数: 0

摘要

我们计算出适用于所有掺杂半导体的功函数每10年变化59.4 meV的普遍偏移，并据此使用蒙特卡罗模拟法模拟掺杂砷化镓二次电子产率的变化。然后，我们比较了扫描电子显微镜和传导原子力显微镜对掺杂砷化镓层的实验图像。开尔文探针力显微镜可直接测量和绘制局部功函数变化图，但测量值通常较小，通常只有理论预测的完全清洁表面的一半左右。掺杂：掺杂是指在半导体中有意掺入外来原子，这些外来原子以离子形式融入晶格中，然后捐献（作为供体）额外的电子或（作为受体）电子空穴，从而改变局部电特性。由此产生的材料被称为正掺杂或对掺杂，对掺杂结被用于所有二极管和晶体管中，它们构成了计算机或太阳能电池等更复杂电子设备的基本单元。我们计算掺杂如何改变从半导体中提取电子所需的能量（称为其功函数），以及这如何影响扫描电子显微镜中的二次电子产率和导电原子力显微镜中的电阻或开尔文探针测量。这两种显微镜方法都可用于直接绘制掺杂纳米结构中掺杂剂的空间分布图，但由于表面效应的影响，很难进行定量测量。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

Towards quantification of doping in gallium arsenide nanostructures by low-energy scanning electron microscopy and conductive atomic force microscopy

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Towards quantification of doping in gallium arsenide nanostructures by low-energy scanning electron microscopy and conductive atomic force microscopy

We calculate a universal shift in work function of 59.4 meV per decade of dopant concentration change that applies to all doped semiconductors and from this use Monte Carlo simulations to simulate the resulting change in secondary electron yield for doped GaAs. We then compare experimental images of doped GaAs layers from scanning electron microscopy and conductive atomic force microscopy. Kelvin probe force microscopy allows to directly measure and map local work function changes, but values measured are often smaller, typically only around half, of what theory predicts for perfectly clean surfaces.

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来源期刊

Journal of microscopy 工程技术-显微镜技术

CiteScore

4.30

自引率

5.00%

发文量

审稿时长

1 months

期刊介绍： The Journal of Microscopy is the oldest journal dedicated to the science of microscopy and the only peer-reviewed publication of the Royal Microscopical Society. It publishes papers that report on the very latest developments in microscopy such as advances in microscopy techniques or novel areas of application. The Journal does not seek to publish routine applications of microscopy or specimen preparation even though the submission may otherwise have a high scientific merit. The scope covers research in the physical and biological sciences and covers imaging methods using light, electrons, X-rays and other radiations as well as atomic force and near field techniques. Interdisciplinary research is welcome. Papers pertaining to microscopy are also welcomed on optical theory, spectroscopy, novel specimen preparation and manipulation methods and image recording, processing and analysis including dynamic analysis of living specimens. Publication types include full papers, hot topic fast tracked communications and review articles. Authors considering submitting a review article should contact the editorial office first.