Modeling and analyzing nano-rod pushing with an AFM

10th IEEE International Conference on Nanotechnology Pub Date : 2010-08-01 DOI:10.1109/NANO.2010.5697758

J. Hou, Chengdong Wu, Lianqing Liu, Zhidong Wang, Z. Dong

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引用次数: 10

Abstract

In developing nano-devices and nano-structures, traditional methodologies on MEMS meet the difficulty from the scale restriction. With the strategy of objects assembly, using AFM to handle nano-rods and other nano-objects is considered as an important and high potential technology in constructing nano-structures. However most of AFM only has one tip as the end effector and cannot control both translational and rotational motions during manipulation, this makes it be difficult to realize posture controllable manipulation especially in nano environment. In this paper, the behavior of nano-rod under pushing is theoretically analyzed and modeled. Viscous friction is incorporated in the model and the two situations that the pivot of the nanorod is either inside or outside the rod are addressed. By modeling, the pivot can be determined at each manipulation in real time, and the pushing points can be planned to realize posture controllable manipulation by using nano-hand strategy which is inspired by stable pushing theory of object manipulation in macro world, and to improve the reliability and the precision of manipulation.

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用原子力显微镜模拟和分析纳米棒的推力

在纳米器件和纳米结构的开发中，传统的MEMS方法受到规模的限制而遇到困难。采用物体组装策略，利用原子力显微镜处理纳米棒和其他纳米物体被认为是构建纳米结构的一项重要而有潜力的技术。然而，大多数AFM只有一个末端执行器，在操作过程中不能同时控制平移和旋转运动，这给实现姿态可控操作带来了困难，尤其是在纳米环境下。本文对纳米棒在推力作用下的行为进行了理论分析和建模。在模型中引入了粘性摩擦，并解决了纳米棒轴心在纳米棒内部和外部的两种情况。通过建模，在每次操作时实时确定支点，并规划推点，利用纳米手策略实现姿态可控操作，该策略受宏观世界物体操纵稳定推理论的启发，提高了操作的可靠性和精度。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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10th IEEE International Conference on Nanotechnology

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