高速原子力显微镜的组件。

Components for high speed atomic force microscopy.

作者信息

Fantner Georg E, Schitter Georg, Kindt Johannes H, Ivanov Tzvetan, Ivanova Katarina, Patel Rohan, Holten-Andersen Niels, Adams Jonathan, Thurner Philipp J, Rangelow Ivo W, Hansma Paul K

机构信息

Department of Physics, University of California Santa Barbara, 93106, USA.

出版信息

Ultramicroscopy. 2006 Jun-Jul;106(8-9):881-7. doi: 10.1016/j.ultramic.2006.01.015. Epub 2006 Apr 27.

DOI:10.1016/j.ultramic.2006.01.015

PMID:16730410

Abstract

Many applications in materials science, life science and process control would benefit from atomic force microscopes (AFM) with higher scan speeds. To achieve this, the performance of many of the AFM components has to be increased. In this work, we focus on the cantilever sensor, the scanning unit and the data acquisition. We manufactured 10 microm wide cantilevers which combine high resonance frequencies with low spring constants (160-360 kHz with spring constants of 1-5 pN/nm). For the scanning unit, we developed a new scanner principle, based on stack piezos, which allows the construction of a scanner with 15 microm scan range while retaining high resonance frequencies (>10 kHz). To drive the AFM at high scan speeds and record the height and error signal, we implemented a fast Data Acquisition (DAQ) system based on a commercial DAQ card and a LabView user interface capable of recording 30 frames per second at 150 x 150 pixels.

摘要

材料科学、生命科学和过程控制中的许多应用都将受益于具有更高扫描速度的原子力显微镜（AFM）。要实现这一点，必须提高许多AFM组件的性能。在这项工作中，我们专注于悬臂梁传感器、扫描单元和数据采集。我们制造了宽度为10微米的悬臂梁，其将高共振频率与低弹簧常数相结合（共振频率为160 - 360千赫兹，弹簧常数为1 - 5皮牛/纳米）。对于扫描单元，我们基于叠层压电陶瓷开发了一种新的扫描器原理，这使得能够构建一个扫描范围为15微米的扫描器，同时保持高共振频率（>10千赫兹）。为了以高扫描速度驱动AFM并记录高度和误差信号，我们基于商用数据采集卡和能够以每秒30帧的速度记录150×150像素图像的LabView用户界面实现了一个快速数据采集（DAQ）系统。

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高速原子力显微镜的组件。

Components for high speed atomic force microscopy.

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