Electroactivity in Polymeric Materials Lenore Rasmussen Editor Electroactivity in Polymeric Materials 123 LenoreRasmussen Ras Labs,LLC, Intelligent Materials forProsthetics and Automation Plasma Surface ModificationExperiment US Department ofEnergy’s Princeton Plasma PhysicsLaboratory atPrincetonUniversity Room L-127,100Stellarator Road Princeton NJ08543 USA ISBN 978-1-4614-0877-2 e-ISBN978-1-4614-0878-9 DOI 10.1007/978-1-4614-0878-9 SpringerNewYorkHeidelbergDordrechtLondon LibraryofCongressControlNumber:2012932404 (cid:2)SpringerScience+BusinessMediaNewYork2012 Thisworkissubjecttocopyright.AllrightsarereservedbythePublisher,whetherthewholeorpartof the material is concerned, specifically the rights of translation, reprinting, reuse of illustrations, recitation,broadcasting,reproductiononmicrofilmsorinanyotherphysicalway,andtransmissionor informationstorageandretrieval,electronicadaptation,computersoftware,orbysimilarordissimilar methodology now known or hereafter developed. Exempted from this legal reservation are brief excerpts in connection with reviews or scholarly analysis or material supplied specifically for thepurposeofbeingenteredandexecutedonacomputersystem,forexclusiveusebythepurchaserof thework.Duplicationofthispublicationorpartsthereofispermittedonlyundertheprovisionsofthe CopyrightLawofthePublisher’slocation,initscurrentversion,andpermissionforusemustalwaysbe obtained from Springer. Permissions for use may be obtained through RightsLink at the Copyright ClearanceCenter.ViolationsareliabletoprosecutionundertherespectiveCopyrightLaw. The use of general descriptive names, registered names, trademarks, service marks, etc. in this publicationdoesnotimply,evenintheabsenceofaspecificstatement,thatsuchnamesareexempt fromtherelevantprotectivelawsandregulationsandthereforefreeforgeneraluse. While the advice and information in this book are believed to be true and accurate at the date of publication,neithertheauthorsnortheeditorsnorthepublishercanacceptanylegalresponsibilityfor anyerrorsoromissionsthatmaybemade.Thepublishermakesnowarranty,expressorimplied,with respecttothematerialcontainedherein. Printedonacid-freepaper SpringerispartofSpringerScience+BusinessMedia(www.springer.com) Preface Thethoughtsofmakingatheoreticaltextbookstylebookinelectroactivematerials began when I started getting more students in the laboratory. When new students jointheproject,Iinvariablygivethemastackofjournalarticlestowadethrough, so began thinking how helpful it would be to give them a concise book to start with.Thisbookisdesignedasastartingpoint,particularlytogetahandleon‘‘how does electroactive movement happen?’’ The goal of this book was to capture the theory—how electroactivity works— balanced with applications—how can electroactivity be used, drawing inspiration from our manmade mechanical world and the natural worldaround us. This book takes a small step at capturing the fascinating field of electroactive materials and actuators. I’m already putting thoughts together on how to make the second volume even more informative while retaining concision and clarity. The Artificial Muscle Project draws people from a variety of disciplines. Indeed,thefieldofelectroactivityisextremelyinterdisciplinary.Caseinpoint:for my first patent in this area, the examiner from the USPTO called me. Evidently, theyhadseveralmeetingstryingtodecidewhichpatentclassificationcodeitcame under—chemistryorelectricalengineering?Sotheyresolvedthematterbyputting the question to me. We chatted and I agreed that it was on the fence between the two areas, but since my background was stronger in chemistry, the main classi- fication was placed in class 523/113, synthetic resins, subclass composition suit- able for use as tissue or body member replacement, restorative, or implant. Fundamentally, the thorough understanding of electroactivity is important because of the ability of bending, contraction, and expansion to produce smooth, controllable, life-like biomimetic motion. By combining electroactive materials with fuel cells and other technologies, electroactive actuation and its reciprocal action can also provide for extremely energy efficient motion, energy generation, and energy harvesting. Electroactivity offers new ways of thinking about and configuring devises, machines, implants, and surfaces, for futuristic mobility by land, air, and sea. v Acknowledgments The editor would like to thank everyone who contributed to this effort, both for advancing the field of electroactivity as well as those who helped with the prep- arationofthisbook.Theeditorwouldliketothanktheotherco-authors:Prof.Iain Anderson and his group including Todd Gisby and Ben O’Brien; Prof. Mohsen Shahinpoor and his group including Yousef Bahramzadeh; Prof. Qibing Pei and hisgroup includingPaulBrochu; Dr.RoyKornbluh,Ron Pelrine,HarshaPrahad, Annjoe Wong-Foy, Brian McCoy, Susan Kim, Joseph Eckerle, and Tom Low of SRI International; and others who have made so many strides in the field of electroactivity: Dr. Yoseph Bar-Cohen, Profs. Yoshihito Osada and Jian Ping Gong, Prof. Toyoichi Tanaka, Prof. John Madden, Prof. Elizabeth Smela, Prof.FedericoCarpi,Prof.GiovanniPioggia,Prof.DanilodeRossi,Prof.Cynthia Breazeal, Dr. Emilio Calius, Prof. Selahattin Ozcelik, Prof. Alexie Khokhlov, Prof. Donald Leo, Prof. Timothy E. Long, Prof. Roger Moore, Prof. Qiming Zhang,andmany,manyothers.Together,allofuscollectively,aremakingscience fiction a reality. Paramount to the success of this book was the United States Department of Energy’s Princeton Plasma Physics Laboratory at Princeton University. I would like to personally thank Lewis Meixler, Charles Gentile, George Ascoine, Yevg- eny Raitses, Eliot Feibush, Philip Efthimion, Adam Cohen, Stewart Prager, Anthony DeMeo, Kitta McPherson, Patricia Wieser, Jim Taylor, Stephan Jurczynski, Carl Tilson, Sue Hill, Gary D’Amico, William Zimmer, John Trafalski, and many others for their support, encouragement, expertise, and state- of-the-artscientificcapabilities.Iwouldalsoliketothanktheprofessorsandtheir laboratories at Princeton Universitythat have helped so much with this endeavor: Prof.RobertCavaandDr.AnthonyWilliamsforhelpinthesolidstatelaboratory; Prof. Steven L. Bernasek and Dr. Esta Abelev for their help with X-ray photo- electron spectroscopy; and Jane Woodall and Prof. Nan Yao for their help with scanning electron microscopy at the Image and Analysis Center. I would like to thankFrankCozzarelli,Jr.,forhispatentexpertiseandinsights.Aspecialheartfelt thanks goes to Thomas Brown of the Federal Laboratory Consortium. vii viii Acknowledgments I would like to thank all the interns and continuing education teachers who have contributed to the Artificial Muscle Project over the years: Alice Kirk, ErichSchramm,CarlJ.Erickson,DavidSchramm,KelseyPagdon,DanPearlman, Kevin Mulally, Sarah Newbury, Aparna Panja, Victoria Jones, and my two sons, who had no choice but to dragged into the business, Paul and Lars Rasmussen. Your laboratory technique, persistence, inquiring minds, and questions that made me think and re-think, made this project a success. I would also like to thank my youngest son, Carl Rasmussen, for his curiosity in the greater world around us. Many heartfelt thanks to Barbara Jones for her proofing abilities, translation abilities, and wording suggestions. I would like to thank Dean Kathryn E. Uhrich of Rutgers University and Prof. James E. McGrath, Prof. Garth L. Wilkes, and Prof. Eugene M. Gregory of Virginia Tech, for all their help with my education, critical thinking, laboratory technique, and ability to synthetically tailor materials, all of which has served so wellinacademiaandindustry.AspecialthanksgoestoDanandJudiMcGuirefor providing a home away from home while completing my education. Last but certainly not least, I would like to thank the rest of my family for all their love, support and encouragement in this endeavor: my husband Henrik T. Rasmussen for his love and devotion, my mother Winola H. Carman for her continualencouragement,mybrothersandsister-in-lawPaulCarman,Nathanand Sally Carman, my father R. Wayne Carman, and my beautiful family through marriage, Jørgen and Ingrid Rasmussen, Tom and Linda Rasmussen, and Morten and Carolin Rasmussen. Desperation may be the mother of invention, but encouragement is the foundation of creativity. Contents 1 Dielectric Elastomers for Actuators and Artificial Muscles . . . . . . 1 Paul Brochu and Qibing Pei 2 Modeling of IPMC Guide Wire Stirrer in Endovascular Surgery . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 57 Yousef Bahramzadeh and Mohsen Shahinpoor 3 From Boots to Buoys: Promises and Challenges of Dielectric Elastomer Energy Harvesting . . . . . . . . . . . . . . . . . . 67 Roy D. Kornbluh, Ron Pelrine, Harsha Prahlad, Annjoe Wong-Foy, Brian McCoy, Susan Kim, Joseph Eckerle and Tom Low 4 Theory of Ionic Electroactive Polymers Capable of Contraction and Expansion–Contraction Cycles . . . . . . . . . . . . 95 Lenore Rasmussen 5 Touch Sensitive Dielectric Elastomer Artificial Muscles. . . . . . . . . 131 Todd Gisby, Ben O’Brien and Iain A. Anderson Appendices . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 143 Appendix A. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 145 Appendix B. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 151 Index . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 161 ix Chapter 1 Dielectric Elastomers for Actuators and Artificial Muscles Paul Brochu and Qibing Pei Abstract Anumberofelectroactivepolymershavebeenexploredfortheiruseas artificial muscles. Among these, dielectric elastomers appear to provide the best combination of properties for true muscle-like actuation. Dielectric elastomers behaveascompliantcapacitors,expandinginareaandshrinkinginthicknesswhen a voltage is applied. Materials combining very high energy densities, strains and efficiencies have been known for some time. To date, however, the widespread adoption of dielectric elastomers has been hindered by premature breakdown and therequirementforhighvoltagesandbulkysupportframes.Recentadvancesseem poisedtoremovetheserestrictionsandallowfortheproductionofhighlyreliable, high-performance transducers for artificial muscle applications. Keywords Dielectric elastomer (cid:2) Electroactive polymer (cid:2) Bistable electroactive polymers (cid:2) Actuator (cid:2) Transducer (cid:2) Artificial muscle (cid:2) DE (cid:2) EAP (cid:2) BSEP 1.1 Introduction The ability to mimic the muscles in our own human bodies, both for the advancement in our well-being and for our amusement, has been a topic of great interest for some time. Natural muscle has a number of properties that make it difficulttomatchintermsofperformance.Theenergydensityofmuscleisonthe order of 150 J kg-1 and can peak at around 300 J kg-1 [1], while displacements P.Brochu(cid:2)Q.Pei(&) DepartmentofMaterialsScienceandEngineering,TheHenrySamueli SchoolofEngineering,UniversityofCalifornia,420WestwoodPlaza, LosAngeles,CA90095-1595,USA e-mail:[email protected] L.Rasmussen(ed.),ElectroactivityinPolymericMaterials, 1 DOI:10.1007/978-1-4614-0878-9_1, (cid:2)SpringerScience+BusinessMediaNewYork2012 2 P.BrochuandQ.Pei are relatively large with typical strains ranging from 20 to 40% and peaking at 100% [2–4]. By these measures alone, electromagnetic (EM) motors and com- bustion engines should be able to match or exceed the performance of natural muscle [5]. However, as it is made obvious by current leading-edge robots (e.g., Honda’s Asimo) [6], the real world performance of conventional-actuator-based roboticsislimited[2,7].Theshortcomingliesonseveralfronts.Firstisthepower supply: natural muscle relies on chemical energy that is supplied to living organisms through the ingestion offood, while EM motors rely on heavy battery pack and capacitor banks that must be recharged frequently. These large power sources contribute to the overall mass of the robotic device and reduce the effective energy density as well as limit range and mobility. Second is the requirementforgearingsystems:EMmotorsoperatebestathighrotationalspeeds; these must be reduced significantly through the use of gearing systems that can significantly increase mass and reduce energy density. Third is the ability to recoverenergy:tendonandflesh,aswellasmuscleitself,arecapableofabsorbing and storing a large percentage of the impact energy that can be translated back to motion. Additionally, muscles possess other salient properties that allow them to operate as motors, brakes, springs, and struts, permitting better stability control and impact energy absorption [8]. EM motors also generate more noise and heat thannaturalmuscle,which isnotwelcomeforcertain applications,andcannotbe effectively operated in large magnetic fields. Pneumatic systems operate linearly like natural muscle; pneumatic artificial muscles(McKibbenartificialmuscles)inparticularareintrinsicallycompliantand can thus provide the ‘‘give’’ that natural muscle attains. Unfortunately, these systemsrequireaircompressorsthatareneitherlightnorsmall,andtheirresponse speed is limited by the ability to pump air into and out of the actuators. Several ‘‘smart materials’’ have been proposed as artificial muscles. These include shape memory alloys (SMA), magnetostrictive alloys (MSA), and piezo- electrics [2, 9]. SMAs are capable of producing relatively large linear displace- ments and can be actuated relatively quickly using resistive heating. What limits their applicability to artificial muscle applications is the time it takes to cool the alloyandreturntotherestposition.Inordertoobtaingoodoperatingfrequencies, theSMAmustbeactivelycooled,increasingthebulk,complexityandcostofthe system. Magnetostrictive alloys and piezoelectric ceramics both suffer from small strains and high stiffness. These materials are thus not particularly suited to artificial muscle applications. Polymers present an interesting alternative to conventional technologies. They possess inherent compliance, are lightweight, and are generally low cost. Elec- troactivepolymers(EAPs)areanemergingtypeofactuatortechnologywhereina lightweightpolymerrespondstoanelectricfieldbygeneratingmechanicalmotion [1, 10, 11]. Their ability to mimic the properties of natural muscle has garnered them the moniker ‘‘artificial muscle,’’ though the term electroactive polymer artificial muscle (EPAM) is more appropriate and descriptive. Theconceptofelectroactivepolymerscanbedatedbackto1880inapaperby Roentgen[12].Inhisexperiments,heobservedthatafilmofnaturalrubbercould