Strain-programmable fiber-based artificial muscle

Getting the most out of muscles Materials that convert electrical, chemical, or thermal energy into a shape change can be used to form artificial muscles. Such materials include bimetallic strips or host-guest materials or coiled fibers or yarns (see the Perspective by Tawfick and Tang). Kanik et al. developed a polymer bimorph structure from an elastomer and a semicrystalline polymer where the difference in thermal expansion enabled thermally actuated artificial muscles. Iterative cold stretching of clad fibers could be used to tailor the dimensions and mechanical response, making it simple to produce hundreds of meters of coiled fibers. Mu et al. describe carbon nanotube yarns in which the volume-changing material is placed as a sheath outside the twisted or coiled fiber. This configuration can double the work capacity of tensile muscles. Yuan et al. produced polymer fiber torsional actuators with the ability to store energy that could be recovered on heating. Twisting mechanical deformation was applied to the fibers above the glass transition temperature and then stored via rapid quenching. Science, this issue p. 145, p. 150, p. 155; see also p. 125 Iterative fiber drawing of a two-material ribbon enables strain-programmable artificial muscles. Artificial muscles may accelerate the development of robotics, haptics, and prosthetics. Although advances in polymer-based actuators have delivered unprecedented strengths, producing these devices at scale with tunable dimensions remains a challenge. We applied a high-throughput iterative fiber-drawing technique to create strain-programmable artificial muscles with dimensions spanning three orders of magnitude. These fiber-based actuators are thermally and optically controllable, can lift more than 650 times their own weight, and withstand strains of >1000%. Integration of conductive nanowire meshes within these fiber-based muscles offers piezoresistive strain feedback and demonstrates long-term resilience across >105 deformation cycles. The scalable dimensions of these fiber-based actuators and their strength and responsiveness may extend their impact from engineering fields to biomedical applications.

[1]  H. Moon,et al.  Electrically controllable twisted-coiled artificial muscle actuators using surface-modified polyester fibers , 2017 .

[2]  Huisheng Peng,et al.  Hierarchically arranged helical fibre actuators driven by solvents and vapours. , 2015, Nature nanotechnology.

[3]  J. Madden,et al.  Polymer artificial muscles , 2007 .

[4]  Steven G. Johnson,et al.  Structured spheres generated by an in-fibre fluid instability , 2012, Nature.

[5]  K. Kim,et al.  Ionic polymer-metal composites: I. Fundamentals , 2001 .

[6]  H. Choi,et al.  A self-sensing dielectric elastomer actuator , 2008 .

[7]  Huisheng Peng,et al.  Preparation of biomimetic hierarchically helical fiber actuators from carbon nanotubes , 2017, Nature Protocols.

[8]  Howard Kuhn,et al.  Mechanical testing and evaluation , 2000 .

[9]  E. Dill,et al.  Kirchhoff's theory of rods , 1992 .

[10]  A. Yokoyama,et al.  Deformation behavior of thermoplastic elastomer specimens: Observation of the strain behavior in a wide range of tensile speeds , 2018 .

[11]  Moon Jeong Park,et al.  Fast low-voltage electroactive actuators using nanostructured polymer electrolytes , 2013, Nature Communications.

[12]  Na Li,et al.  New twist on artificial muscles , 2016, Proceedings of the National Academy of Sciences.

[13]  Metin Sitti,et al.  High-Performance Multiresponsive Paper Actuators. , 2016, ACS nano.

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

[15]  C. Haines,et al.  Hybrid carbon nanotube yarn artificial muscle inspired by spider dragline silk , 2014, Nature Communications.

[16]  Michael F. Ashby,et al.  Actuator Classification and Selection—The Development of a Database , 2002 .

[17]  Carter S. Haines,et al.  Artificial Muscles from Fishing Line and Sewing Thread , 2014, Science.

[18]  Vijay Kumar,et al.  The grand challenges of Science Robotics , 2018, Science Robotics.

[19]  Carter S. Haines,et al.  Electrically, Chemically, and Photonically Powered Torsional and Tensile Actuation of Hybrid Carbon Nanotube Yarn Muscles , 2012, Science.

[20]  R. Langer,et al.  Biodegradable, Elastic Shape-Memory Polymers for Potential Biomedical Applications , 2002, Science.

[21]  David R. Clarke,et al.  Structural Transition from Helices to Hemihelices , 2014, PloS one.

[22]  Tae Jin Mun,et al.  Bio-inspired, Moisture-Powered Hybrid Carbon Nanotube Yarn Muscles , 2016, Scientific Reports.

[23]  Seyed M. Mirvakili,et al.  Fast Torsional Artificial Muscles from NiTi Twisted Yarns. , 2017, ACS applied materials & interfaces.

[24]  C. Darwin The Movements and Habits of Climbing Plants , 1875, Nature.

[25]  Thomas J. Richner,et al.  Flexible and stretchable nanowire-coated fibers for optoelectronic probing of spinal cord circuits , 2017, Science Advances.

[26]  Mecit Yaman,et al.  Arrays of indefinitely long uniform nanowires and nanotubes. , 2011, Nature materials.

[27]  Lei Wei,et al.  Controlled fragmentation of multimaterial fibres and films via polymer cold-drawing , 2016, Nature.

[28]  A. Concas,et al.  Knitting and weaving artificial muscles , 2017, Science Advances.

[29]  L. F. Pinto,et al.  How to mimic the shapes of plant tendrils on the nano and microscale: spirals and helices of electrospun liquid crystalline cellulose derivatives , 2009 .

[30]  E. Terentjev,et al.  Self-winding of helices in plant tendrils and cellulose liquid crystal fibers , 2010 .

[31]  M. Tabor,et al.  Spontaneous Helix Hand Reversal and Tendril Perversion in Climbing Plants , 1998 .

[32]  Ranran Wang,et al.  A Biomimetic Conductive Tendril for Ultrastretchable and Integratable Electronics, Muscles, and Sensors. , 2018, ACS nano.

[33]  Alain Goriely,et al.  Tendril Perversion in Intrinsically Curved Rods , 2002, J. Nonlinear Sci..

[34]  L. Mahadevan,et al.  How the Cucumber Tendril Coils and Overwinds , 2012, Science.