The Four Pillars of Nanopositioning for Scanning Probe Microscopy: The Position Sensor, the Scanning Device, the Feedback Controller, and the Reference Trajectory

Tuma T.; Sebastian A.; Lygeros J.; Pantazi A.

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The Four Pillars of Nanopositioning for Scanning Probe Microscopy: The Position Sensor, the Scanning Device, the Feedback Controller, and the Reference Trajectory

机译：用于扫描探针显微镜的纳米定位的四个支柱：位置传感器，扫描设备，反馈控制器和参考轨迹

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Since its birth in the 1980s, nanotechnology has significantly advanced our understanding and control of physical processes on the nanometer and subnanometer scale. Manipulation and interrogation of matter on these length scales have become indispensable in various fields of engineering and science and have been instrumental in some of the most exciting scientific and engineering breakthroughs of the past decades. Application areas include scanning probe microscopy (SPM) [1], data storage [2], and semiconductor device fabrication [3]. In all these applications, control of motion and position at length scales down to the size of a single atom, often referred to as nanopositioning, is a key enabling tool.

机译：自1980年代诞生以来，纳米技术极大地增进了我们对纳米和亚纳米级物理过程的理解和控制。在这些长度尺度上对物质的操纵和审讯在工程和科学的各个领域中已变得不可或缺，并且在过去几十年中一些最令人兴奋的科学和工程突破中发挥了作用。应用领域包括扫描探针显微镜（SPM）[1]，数据存储[2]和半导体器件制造[3]。在所有这些应用中，长度的运动和位置控制可缩小到单个原子的大小（通常称为纳米定位），这是关键的启用工具。

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《Control Systems, IEEE》 |2013年第6期|68-85|共18页
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Tuma T.; Sebastian A.; Lygeros J.; Pantazi A.;
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IBM Res. - Zurich, Rueschlikon, Switzerland|c|;

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1. A precision device for the positioning of the probe in scanning-probe microscopy [J] . A. V. Zhikharev, S. G. Bystrov, O. V. Karban Instruments and Experimental Techniques . 2003,第3期

机译：用于在扫描探针显微镜中定位探针的精密设备
2. Variable Temperature-Scanning Hall Probe Microscopy With GaN/AlGaN Two-Dimensional Electron Gas (2DEG) Micro Hall Sensors in 4.2–425 K Range Using Novel Quartz Tuning Fork AFM Feedback [J] . Akram A., Dede M., Oral A. IEEE Transactions on Magnetics . 2008,第期

机译：使用新型石英音叉AFM反馈，在4.2–425 K范围内使用GaN / AlGaN二维电子气（2DEG）微型霍尔传感器进行可变温度扫描霍尔探针显微镜
3. Improved accuracy and speed in scanning probe microscopy by image reconstruction from non-gridded position sensor data [J] . Ziegler D., Meyer T.R., Farnham R., Nanotechnology . 2013,第33期

机译：通过从非网格位置传感器数据重建图像，提高了扫描探针显微镜的准确性和速度
4. Position feedback for microrobots based on scanning probe microscopy [C] . Bergander, A., Driesen, Intelligent Robots and Systems, 2004. (IROS 2004). Proceedings. 2004 IEEE/RSJ International Conference on . 2004

机译：基于扫描探针显微镜的微型机器人位置反馈
5. Design, characterization, and control of a high-bandwidth serial-kinematic nanopositioning stage for scanning probe microscopy applications. [D] . Kenton, Brian Jeffrey. 2010

机译：设计，表征和控制用于扫描探针显微镜应用的高带宽串行运动纳米定位平台。
6. Virtual reality visual feedback for hand-controlled scanning probe microscopy manipulation of single molecules [O] . Philipp Leinen, Matthew F B Green, Taner Esat, 2015

机译：虚拟现实视觉反馈用于单分子手控扫描探针显微镜操作
7. Variable temperature-scanning Hall probe microscopy with GaN/AlGaN two-dimensional electron gas (2DEG) micro Hall sensors in 4.2-425 K range using novel quartz tuning fork AFM feedback [O] . Akram, R., Dede, M., Oral, A. 2008

机译：使用新颖的石英音叉AFM反馈，在4.2-425 K范围内使用GaN / AlGaN二维电子气（2DEG）微型霍尔传感器进行可变温度扫描霍尔探针显微镜

The Four Pillars of Nanopositioning for Scanning Probe Microscopy: The Position Sensor, the Scanning Device, the Feedback Controller, and the Reference Trajectory

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