用于表面电学性质纳米级成像的导电原子力显微镜-超低电流测量系统

Conductive Atomic Force Microscopy-Ultralow-Current Measurement Systems for Nanoscale Imaging of a Surface's Electrical Properties.

作者信息

Sikora Andrzej, Gajewski Krzysztof, Badura Dominik, Pruchnik Bartosz, Piasecki Tomasz, Raczkowski Kamil, Gotszalk Teodor

机构信息

Department of Nanometrology, Faculty of Electronics, Photonics and Microsystems, Wrocław University of Science and Technology, 50-370 Wrocław, Poland.

Nokia Solutions and Networks, ul. Lotnicza 12, 54-155 Wroclaw, Poland.

出版信息

Sensors (Basel). 2024 Aug 30;24(17):5649. doi: 10.3390/s24175649.

DOI:10.3390/s24175649

PMID:39275562

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11398235/

Abstract

One of the most advanced and versatile nanoscale diagnostic tools is atomic force microscopy. By enabling advanced imaging techniques, it allows us to determine various assets of a surface, including morphological, electrical, mechanical, magnetic, and thermal properties. Measuring local current flow is one of the very important methods of evaluation for, for instance, photovoltaic materials or semiconductor structures and other nanodevices. Due to contact areas, the current densities can easily reach above 1 kA/m; therefore, special detection/measurement setups are required. They meet the required measurement range, sensitivity, noise level, and bandwidth at the measurement scale. Also, they prevent the sample from becoming damaged and prevent unwanted tip-sample issues. In this paper, we present three different nanoscale current measurement solutions, supported with test results, proving their performance.

摘要

最先进且用途广泛的纳米级诊断工具之一是原子力显微镜。通过启用先进的成像技术，它使我们能够确定表面的各种特性，包括形态、电学、力学、磁学和热学性质。测量局部电流是评估例如光伏材料、半导体结构和其他纳米器件的非常重要的方法之一。由于接触面积，电流密度很容易达到1 kA/m以上；因此，需要特殊的检测/测量装置。它们在测量尺度上满足所需的测量范围、灵敏度、噪声水平和带宽。此外，它们还能防止样品受损，并防止出现不必要的针尖-样品问题。在本文中，我们展示了三种不同的纳米级电流测量解决方案，并给出测试结果以证明其性能。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/8bb0/11398235/4bed1bc28852/sensors-24-05649-g001.jpg

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用于表面电学性质纳米级成像的导电原子力显微镜-超低电流测量系统

Conductive Atomic Force Microscopy-Ultralow-Current Measurement Systems for Nanoscale Imaging of a Surface's Electrical Properties.

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