Electromechanical actuator with controllable motion, fast response rate, and high-frequency resonance based on graphene and polydiacetylene.

Although widely investigated, novel electromechanical actuators with high overall actuation performance are still in urgent need for various practical and scientific applications, such as robots, prosthetic devices, sensor switches, and sonar projectors. In this work, combining the properties of unique environmental perturbations-actuated deformational isomerization of polydiacetylene (PDA) and the outstanding intrinsic features of graphene together for the first time, we design and fabricate an electromechanical bimorph actuator composed of a layer of PDA crystal and a layer of flexible graphene paper through a simple yet versatile solution approach. Under low applied direct current (dc), the graphene-PDA bimorph actuator with strong mechanical strength can generate large actuation motion (curvature is about 0.37 cm(-1) under a current density of 0.74 A/mm(2)) and produce high actuation stress (more than 160 MPa/g under an applied dc of only 0.29 A/mm(2)). When applying alternating current (ac), this actuator can display reversible swing behavior with long cycle life under high frequencies even up to 200 Hz; significantly, while the frequency and the value of applied ac and the state of the actuators reach an appropriate value, the graphene-PDA actuator can produce a strong resonance and the swing amplitude will jump to a peak value. Moreover, this stable graphene-PDA actuator also demonstrates rapidly and partially reversible electrochromatic phenomenon when applying an ac. Two mechanisms-the dominant one, electric-induced deformation, and a secondary one, thermal-induced expansion of PDA-are proposed to contribute to these interesting actuation performances of the graphene-PDA actuators. On the basis of these results, a mini-robot with controllable direction of motion based on the graphene-PDA actuator is designed to illustrate the great potential of our discoveries for practical use. Combining the unique actuation mechanism and many outstanding properties of graphene and PDA, this novel kind of graphene-PDA actuator exhibits compelling advantages to traditional electromechanical actuation technology and may provide a new avenue for actuation applications.

[1]  R. A. Suleimanov,et al.  The nature of negative linear expansion of graphite crystals , 1993 .

[2]  Klaus Kern,et al.  Electronic transport properties of individual chemically reduced graphene oxide sheets. , 2007, Nano letters.

[3]  J. Kysar,et al.  Measurement of the Elastic Properties and Intrinsic Strength of Monolayer Graphene , 2008, Science.

[4]  Jefferson Z. Liu,et al.  Graphene actuators: quantum-mechanical and electrostatic double-layer effects. , 2011, Journal of the American Chemical Society.

[5]  Ji Won Suk,et al.  Graphene-based actuators. , 2010, Small.

[6]  Huisheng Peng,et al.  Chromatic polydiacetylene with novel sensitivity. , 2010, Chemical Society reviews.

[7]  R. Ruoff,et al.  Graphene-based ultracapacitors. , 2008, Nano letters.

[8]  J. Jang,et al.  Flexible and transparent graphene films as acoustic actuator electrodes using inkjet printing. , 2011, Chemical communications.

[9]  R. Stoltenberg,et al.  Evaluation of solution-processed reduced graphene oxide films as transparent conductors. , 2008, ACS nano.

[10]  Yongsheng Chen,et al.  Flexible, Magnetic, and Electrically Conductive Graphene/Fe3O4 Paper and Its Application for Magnetic-Controlled Switches , 2010 .

[11]  A. Rinzler,et al.  Carbon nanotube actuators , 1999, Science.

[12]  K. Uchino Materials issues in design and performance of piezoelectric actuators: an overview , 1998 .

[13]  G. Wallace,et al.  Processable aqueous dispersions of graphene nanosheets. , 2008, Nature nanotechnology.

[14]  Ron Dagani,et al.  CARBON-BASED ELECTRONICS , 1999 .

[15]  Ron Pelrine,et al.  Interpenetrating Polymer Networks for High‐Performance Electroelastomer Artificial Muscles , 2006 .

[16]  Xuli Chen,et al.  Electrochromatic carbon nanotube/polydiacetylene nanocomposite fibres. , 2009, Nature nanotechnology.

[17]  R. Langer,et al.  Light-induced shape-memory polymers , 2005, Nature.

[18]  Andre K. Geim,et al.  Electric Field Effect in Atomically Thin Carbon Films , 2004, Science.

[19]  Ying Hu,et al.  Electromechanical actuation with controllable motion based on a single-walled carbon nanotube and natural biopolymer composite. , 2010, ACS nano.

[20]  R. Vaia,et al.  Remotely actuated polymer nanocomposites—stress-recovery of carbon-nanotube-filled thermoplastic elastomers , 2004, Nature materials.

[21]  Deborah H. Charych,et al.  Color and Chromism of Polydiacetylene Vesicles , 1998 .

[22]  Luzhuo Chen,et al.  High-performance, low-voltage, and easy-operable bending actuator based on aligned carbon nanotube/polymer composites. , 2011, ACS nano.

[23]  Loon-Seng Tan,et al.  Electrothermal Polymer Nanocomposite Actuators , 2010, Advanced materials.

[24]  Alan R. Burns,et al.  Polydiacetylene films: a review of recent investigations into chromogenic transitions and nanomechanical properties , 2004 .

[25]  Raymond C. Stevens,et al.  Charge-Induced Chromatic Transition of Amino Acid-Derivatized Polydiacetylene Liposomes , 1998 .

[26]  Kanghyun Kim,et al.  Electric property evolution of structurally defected multilayer graphene. , 2008, Nano letters.

[27]  J. Mizuno,et al.  Conductivity Measurement of Polydiacetylene Thin Films by Double-Tip Scanning Tunneling Microscopy , 2004 .

[28]  R. Baughman Conducting polymer artificial muscles , 1996 .

[29]  S. Fang,et al.  Electromechanical Actuators Based on Graphene and Graphene/Fe3O4 Hybrid Paper , 2011 .

[30]  C. N. Lau,et al.  Superior thermal conductivity of single-layer graphene. , 2008, Nano letters.

[31]  I. Hunter,et al.  Fast contracting polypyrrole actuators , 2000 .

[32]  Jong-Hyun Ahn,et al.  Graphene-based bimorph microactuators. , 2011, Nano letters.

[33]  L. Qu,et al.  An asymmetrically surface-modified graphene film electrochemical actuator. , 2010, ACS nano.

[34]  S. Stankovich,et al.  Preparation and characterization of graphene oxide paper , 2007, Nature.

[35]  Tsuyoshi Ikehara,et al.  Optically driven actuator using photo-induced phase-transition polymer , 2002 .

[36]  Ron Pelrine,et al.  High-Strain Actuator Materials Based on Dielectric Elastomers , 2000 .

[37]  Elisabeth Smela,et al.  Polyaniline actuators: Part 1. PANI(AMPS) in HCl , 2005 .

[38]  L. Brinson,et al.  Functionalized graphene sheets for polymer nanocomposites. , 2008, Nature nanotechnology.

[39]  Q. Pei,et al.  High-speed electrically actuated elastomers with strain greater than 100% , 2000, Science.

[40]  Eugene M. Terentjev,et al.  Photomechanical actuation in polymer–nanotube composites , 2005, Nature materials.

[41]  G. Wallace,et al.  Mechanically Strong, Electrically Conductive, and Biocompatible Graphene Paper , 2008 .

[42]  C. Brinker,et al.  Self-assembly of mesoscopically ordered chromatic polydiacetylene/silica nanocomposites , 2001, Nature.

[43]  K. R. Atkinson,et al.  Multifunctional Carbon Nanotube Yarns by Downsizing an Ancient Technology , 2004, Science.

[44]  Masahiro Fujiwara,et al.  Thin-film particles of graphite oxide 1:: High-yield synthesis and flexibility of the particles , 2004 .

[45]  S. Stankovich,et al.  Graphene-based composite materials , 2006, Nature.

[46]  Jannik C. Meyer,et al.  The structure of suspended graphene sheets , 2007, Nature.

[47]  Andre K. Geim,et al.  The rise of graphene. , 2007, Nature materials.

[48]  Thomas R. Shrout,et al.  Relaxor based ferroelectric single crystals for electro-mechanical actuators , 1997 .

[49]  C. Brinker,et al.  Functional nanocomposites prepared by self-assembly and polymerization of diacetylene surfactants and silicic acid. , 2003, Journal of the American Chemical Society.