Nanomanipulation Experiments Exploring Frictional and Mechanical 
Properties of Carbon Nanotubes

Falvo, Michael R.; Clary, Gregory J.; Helser, A.; Paulson, Scott; Taylor, Russell M.; Chi, Vernon; Brooks, Frederick P.; Washburn, S.; Superfine, Richard

doi:10.1017/s1431927698980485

Cited by 69 publications

(34 citation statements)

References 19 publications

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“…While studying the manipulation at nanoscale, sliding friction and tribological behavior play an eminent role (Carpick and Salmeron 1997;Meyer 2002;Persson 2000). Some pioneer work on manipulation of CNTs (Falvo et al 1998Hertel et al 1998) by using a force stylus to feel the CNTs on a surface is available in the literature. Evidences are available for the possibility of cutting of bamboo shaped CNTs (Jang et al 2005) with tip force application.…”

Section: Introductionmentioning

confidence: 99%

Atomic force microscope manipulation of multiwalled and single walled carbon nanotubes with reflux and ultrasonic treatments

et al. 2012

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We are reporting the atomic force microscope (AFM) nanomanipulation of ultrasonically dispersed and reflux-oxidized multiwalled carbon nanotubes (MWCNT) and single walled carbon nanotubes (SWCNT) by controlling the AFM tip with a NanoManipulator on a silicon substrate. The structure and the morphology of the carbon nanotubes (CNT) were confirmed with AFM interfaced with NanoManipulator and transmission electron microscope. The modifying parameter, which controls the force exerted by AFM tip, was set to be 0.5 nA in each case (0.5 nA = 20 nN). Bending was observed in ultrasonically dispersed MWCNTs, whereas, cutting was observed for reflux-oxidized MWCNTs along with the lateral movements. Similar observations were found for SWCNTs with sharp cuts and lateral displacements. The results show that CNTs deform by combining bending and distortion when subjected to large mechanical forces exerted by the tip of the AFM. The magnitude of the force, required to deform the reflux-oxidized CNTs is less than that for the ultrasonically dispersed CNTs, for both MWCNTs and SWCNTs.

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Section: Introductionmentioning

confidence: 99%

Atomic force microscope manipulation of multiwalled and single walled carbon nanotubes with reflux and ultrasonic treatments

et al. 2012

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“…Methods such as colloidal crystallization [10][11][12][13] and template-directed synthesis [14][15][16] have been proposed for achieving particle organization. Additionally, atomic [17][18][19] and scanning force [20,21] microscopy, nanotube nanotweezers [22], and optical tweezers [23][24][25][26] have been used for the manipulation of a small number of individual particles. However, the organization of colloidal particles into ordered assemblies of one, two, or three dimensions, devoid of structural defects, that extend over length scales much larger than the particle size still remains a big challenge.…”

Section: Introductionmentioning

confidence: 99%

One-, two-, and three-dimensional organization of colloidal particles using nonuniform alternating current electric fields

Docoslis

Alexandridis

2002

Electrophoresis

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We demonstrate here the use of nonuniform alternating current (AC) electric fields, generated by planar electrodes, for the organization of num-sized particles into one-, two-, and three-dimensional assemblies. The electrodes, with separations that vary from 35 to 300 num, are made of gold deposited on glass substrata. Latex, silica and graphite particles have been examined inside organic or aqueous media in order to illustrate the general applicability of the technique. Theoretical predictions of the particle response under the electric fields are experimentally confirmed for all the above particle/media combinations and can thus be used as a valuable design tool. The size and shape of the final structures are mainly dependent on the electrode shape and dimensions, but are also subject to the particle type and operating conditions. Particle organization in one dimension (strings) is achieved under conditions of positive or negative dielectrophoresis in the space between two energized electrodes. Two-dimensional particle organization (ordered, planar particles assemblies) was observed under conditions of negative dielectrophoresis, when quadrupole electrodes were employed. Moreover, when negative dielectrophoresis and stronger electric fields are applied (of the order of 50 kV(rms) m(-1)), three-dimensional, pyramid-like structures with a vertical dimension 1000-fold higher than that of the corresponding (planar) electrodes can be assembled. These 3-D structures can grow as free-standing assemblies, or inside templates etched in the substratum. The dielectrophoresis (DEP)-organized particle assemblies can subsequently be rendered permanent via the in situ fixing (cross-linking) of the individual particles.

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“…The manipulation is semi-teleoperated: the operator controls the overall operation, but some tasks are performed automatically [52], [53]. Users can thus concentrate on the main task, while the technical gestures are performed automatically.…”

Section: B Augmented Teleoperationmentioning

confidence: 99%

A Review of Haptic Feedback Teleoperation Systems for Micromanipulation and Microassembly

Bolopion

Régnier

2013

IEEE Trans. Automat. Sci. Eng.

118

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Abstract-This paper presents a review of the major haptic feedback teleoperation systems for micromanipulation. During the last decade, the handling of micrometer-sized objects has become a critical issue. Fields of application from material science to electronics demonstrate an urgent need for intuitive and flexible manipulation systems able to deal with small-scale industrial projects and assembly tasks. Two main approaches have been considered: fully automated tasks and manual operation. The first one require fully pre determined tasks, while the later necessitates highly trained operators. To overcome these issues the use of haptic feedback teleoperation where the user manipulates the tool through a joystick whilst feeling a force feedback, appears to be a promising solution as it allows high intuitiveness and flexibility. Major advances have been achieved during this last decade, starting with systems that enable the operator to feel the substrate topology, to the current state-of-the-art where 3D haptic feedback is provided to aid manipulation tasks. This paper details the major achievements and the solutions that have been developed to propose 3D haptic feedback for tools that often lack 3D force measurements. The use of virtual reality to enhance the immersion is also addressed. The strategies developed provide haptic feedback teleoperation systems with a high degree of assistance and for a wide range of micromanipulation tools. Based on this expertise on haptic for micromanipulation and virtual reality assistance it is now possible to propose microassembly systems for objects as small as 1 to 10 micrometers. This is a mature field and will benefit small-scale industrial projects where precision and flexibility in microassembly are required.Note to Practitioners-This paper is motivated by the urgent need of intuitive and flexible manipulation systems able to deal with assembly tasks on the microscale. A new and promising solution is presented here; teleoperation with force feedback, where an operator uses a joystick to control the tool at the microscale, while experiencing interaction forces between the tool and the environment. Feedback assistance to the user using attractive and repulsive force fields is also be proposed to help achieve the assembly task. Examples are given in this paper to illustrate this approach. The presented techniques can be readily applied to most micromanipulation systems to perform advanced microassembly tasks.

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Nanomanipulation Experiments Exploring Frictional and Mechanical Properties of Carbon Nanotubes

Cited by 69 publications

References 19 publications

Atomic force microscope manipulation of multiwalled and single walled carbon nanotubes with reflux and ultrasonic treatments

Atomic force microscope manipulation of multiwalled and single walled carbon nanotubes with reflux and ultrasonic treatments

One-, two-, and three-dimensional organization of colloidal particles using nonuniform alternating current electric fields

A Review of Haptic Feedback Teleoperation Systems for Micromanipulation and Microassembly

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