对使用双级横向扫描仪获取的原子力显微镜光栅扫描进行线性化处理

IF 2.4 4区物理与天体物理 Q3 MATERIALS SCIENCE, MULTIDISCIPLINARY

Current Applied Physics Pub Date : 2024-07-26 DOI:10.1016/j.cap.2024.07.015

Oyoo Michael Juma , Luke Oduor Otieno , Thi Thu Nguyen, Thi Ngoc Nguyen, Yong Joong Lee

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引用次数: 0

摘要

通过设计和制造两个在静态和动态特性上有显著差异的纳米定位器，双级扫描器可以成功地提高原子力显微镜（AFM）扫描器在空间和/或频率上的扫描范围。在这种情况下，必须拆分定位信号，以满足每个级的位移和频率限制。在没有闭环位移测量传感器的情况下，对使用时间和频率分割信号获取的图像进行线性化处理是一项挑战。一种常见的方法是使用基于反演模型的前馈补偿，这种方法通常既繁琐又耗时。在这项工作中，我们展示了基于图像的线性化方法，可以为使用双级扫描仪采集的光栅扫描获得可接受的结果。特别是，我们将前馈和基于图像的方法应用于自制的双级横向扫描仪和高速原子力显微镜（HS-AFM）系统。两种方法获得的扫描结果对比良好，表明基于图像的光栅扫描线性化可以取代基于逆模型的前馈方法。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

Linearizing AFM raster scans acquired using dual-stage lateral scanners

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Linearizing AFM raster scans acquired using dual-stage lateral scanners

Dual-stage scanners can successfully increase the range of atomic force microscope (AFM) scanners in space and/or frequency by designing and constructing two nanopositioners with significant differences in static and dynamic characteristics. In such cases, the positioning signal has to be split to meet the displacement and frequency limitations of each stage. Without closed-loop displacement measurement sensors, linearizing images acquired using signals split in time and frequency can be challenging. A common method, often cumbersome and time consuming, uses inverse model-based feedforward compensation. In this work, we show that image-based linearization can be used to achieve acceptable results for raster scans acquired using dual-stage scanners. In particular, we apply the feedforward and image-based methods to our homemade dual-stage lateral scanner and high-speed AFM (HS-AFM) system. The acquired scans compare well for the two methods, indicating that image-based raster scan linearization can be used in place of inverse model-based feedforward approaches.

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来源期刊

Current Applied Physics 物理-材料科学：综合

CiteScore

4.80

自引率

0.00%

发文量

213

审稿时长

33 days

期刊介绍： Current Applied Physics (Curr. Appl. Phys.) is a monthly published international journal covering all the fields of applied science investigating the physics of the advanced materials for future applications. Other areas covered: Experimental and theoretical aspects of advanced materials and devices dealing with synthesis or structural chemistry, physical and electronic properties, photonics, engineering applications, and uniquely pertinent measurement or analytical techniques. Current Applied Physics, published since 2001, covers physics, chemistry and materials science, including bio-materials, with their engineering aspects. It is a truly interdisciplinary journal opening a forum for scientists of all related fields, a unique point of the journal discriminating it from other worldwide and/or Pacific Rim applied physics journals. Regular research papers, letters and review articles with contents meeting the scope of the journal will be considered for publication after peer review. The Journal is owned by the Korean Physical Society.