Photo-mechanical actuation of carbon nanotubes: mechanisms and applications in micro and nano-devices

Lu, Shoaxin; Ahir, S. V.; Velasco, Vanessa; King, Ben; Xu, Peng; Terentjev, Eugene M.; Panchapakesan, Balaji

doi:10.1007/s12213-009-0021-6

Cited by 23 publications

(26 citation statements)

References 55 publications

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“…[22][23][24][25] As shown in Figure 1f, when the CNTs content was less than 15 wt%, both tensile strength and relative elongation of the PNC increased as more CNTs were added. Synthesized via a straightforward two-step method based on sacrificial templates, the porous nanocomposite exhibits a spongelike structure that can be stretched to 243% elongation.…”

Section: Doi: 101002/adma201603115mentioning

confidence: 99%

Stretchable Porous Carbon Nanotube‐Elastomer Hybrid Nanocomposite for Harvesting Mechanical Energy

et al. 2016

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A stretchable porous nanocomposite (PNC) is reported based on a hybrid of a multiwalled carbon nanotubes network and a poly(dimethylsiloxane) matrix for harvesting energy from mechanical interactions. The deformation-enabled energy-generating process makes the PNC applicable to various mechanical interactions, including pressing, stretching, bending, and twisting. It can be potentially used as an energy solution for wearable electronics.

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Section: Doi: 101002/adma201603115mentioning

confidence: 99%

Stretchable Porous Carbon Nanotube‐Elastomer Hybrid Nanocomposite for Harvesting Mechanical Energy

et al. 2016

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“…While polymers themselves are interesting, recently it has been recognized that their composites often exhibit remarkably superior traits and perform better in certain applications. Accordingly, many varieties of polymer composites have been developed and explored and in the recent years polymer nanocomposites containing CNTs, graphene and graphene derivatives have been paid special attention . It has been noticed that carbon based nanomaterials often enhance the optical, electrical and mechanical properties of polymer nanocomposites and introduce new capabilities into the hybrid polymer systems.…”

Section: Polymers Driven By Photothermal Effectmentioning

confidence: 99%

Soft Materials Driven by Photothermal Effect and Their Applications

Bisoyi

Urbas

2018

Advanced Optical Materials

132

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Remote driving of functional hybrid soft materials for various applications is emerging as an enabling pursuit. Toward this end, soft materials driven by photothermal agents have been attracting tremendous attention from both fundamental science and technological applications points of view. These stimuli‐responsive materials combine the beneficial attributes of both classes of promising materials, i.e., soft materials and photothermal agents. Both inorganic and organic photothermal agents have been incorporated into the matrices of soft materials. Metal nanoparticles, carbon nanomaterials, and organic photothermal agents have been impregnated into the matrices of liquid crystals, polymers, and gels that can be remotely driven by light irradiation. In this review, the remote driving of functional hybrid soft materials and their various applications are discussed. Photothermal functional nanocomposites are demonstrated to act as actuators, therapeutic agents, drug delivery systems, microvalves, etc. Smart and adaptive systems are realized by dispersing photothermal agents into soft matter matrices. Challenges and opportunities in this fascinating frontier are outlined.

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“…[10]. One of the earliest, well-known examples is the heat engine described in the Feynmann Lectures on Physics, where lamps heat stretched rubber bands and the added stress on the heated bands causes a bicycle wheel to rotate.…”

Section: Photoelastic Actuatorsmentioning

confidence: 99%

Ultraflexible nanostructures and implications for future nanorobots

Cohn

Panchapakesan

2016

Sensors for Next-Generation Robotics III

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Several high aspect ratio nanostructures have been made by capillary force directed self-assembly including polymeric nanofiber air-bridges, trampoline-like membranes, microsphere-beaded nanofibers, and intermetallic nanoneedles. Arrays of polymer air-bridges form in seconds by simply hand brushing a bead of polymeric liquid over an array of micropillars. The domination of capillary force that is thinning unstable capillary bridges leads to uniform arrays of nanofiber air-bridges. Similarly, arrays of vertically oriented Ag 2 Ga nanoneedles have been formed by dipping silvercoated arrays of pyramidal silicon into melted gallium. Force-displacement measurements of these structures are presented. These nanostructures, especially when compressively or torsionally buckled, have extremely low stiffnesses, motion due to thermal fluctuations that is relatively easily detected, and the ability to move great distances for very small changes in applied force. Nanofibers with bead-on-a-string structure, where the beads are micron diameter and loaded with magnetic iron oxide (maghemite), are shown to be simply viewable under optical microscopes, have micronewton/m stiffness, and have ultralow torsional stiffnesses enabling the bead to be rotated numerous revolutions without breaking. Combination of these high aspect ratio structures with stretched elastomers offer interesting possibilities for robotic actuation and locomotion. Polydimethylsiloxane loaded with nanomaterials, e.g. nanotubes, graphene or MoS 2 , can be efficiently heated with directed light. Heating produces considerable force through the thermoelastic effect, and this force can be used for continuous translation or to trigger reversible elastic buckling of the nanostructures. The remote stimulation of motion with light provides a possible mechanism for producing cooperative behavior between swarms of semiautonomous nanorobots.

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Photo-mechanical actuation of carbon nanotubes: mechanisms and applications in micro and nano-devices

Cited by 23 publications

References 55 publications

Stretchable Porous Carbon Nanotube‐Elastomer Hybrid Nanocomposite for Harvesting Mechanical Energy

Stretchable Porous Carbon Nanotube‐Elastomer Hybrid Nanocomposite for Harvesting Mechanical Energy

Soft Materials Driven by Photothermal Effect and Their Applications

Ultraflexible nanostructures and implications for future nanorobots

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