Alan J. Heeger Papers

Total Page:16

File Type:pdf, Size:1020Kb

Alan J. Heeger Papers http://oac.cdlib.org/findaid/ark:/13030/c8g44nrg No online items Guide to the Alan J. Heeger Papers Preliminary guide by A. Demeter, May 1, 2008; latest revision Aug. 19, 2010. Department of Special Collections Davidson Library University of California, Santa Barbara Santa Barbara, CA 93106 Phone: (805) 893-3062 Fax: (805) 893-5749 Email: [email protected] URL: http://www.library.ucsb.edu/special-collections/ © 2012 The Regents of the University of California. All rights reserved. Guide to the Alan J. Heeger UArch FacP 39 1 Papers Alan J. Heeger Papers, ca. 1952-2003 [bulk dates 1980-2000] Collection number: UArch FacP 39 Department of Special Collections Davidson Library University of California, Santa Barbara Processed by: A. Demeter Date Completed: May 1, 2008 Latest revision: Aug. 19, 2010 Encoded by: A. Demeter © 2012 The Regents of the University of California. All rights reserved. Descriptive Summary Title: Alan J. Heeger Papers Dates: ca. 1952-2003 Bulk Dates: 1980-2000 Collection number: UArch FacP 39 Creator: Heeger, Alan J. Collection Size: 23.4 linear feet (58 document boxes and 1 half-sized document box). Repository: University of California, Santa Barbara. Library. Dept. of Special Collections Santa Barbara, CA 93106 Abstract: The Alan J. Heeger papers contain a large number of drafts, manuscripts, and correspondence relating to journal articles, conference papers, and patent applications, including files on his Nobel Prize-winning work. Also included are some materials from Heeger's college days and his work as an instructor at UCSB. Physical location: Del Sur, University Archives, 29B. Languages: English Access Restrictions None. Publication Rights Copyright has not been assigned to the Department of Special Collections, UCSB. All requests for permission to publish or quote from manuscripts must be submitted in writing to the Head of Special Collections. Permission for publication is given on behalf of the Department of Special Collections as the owner of the physical items and is not intended to include or imply permission of the copyright holder, which also must be obtained. Preferred Citation Alan J. Papers. UArch FacP 39. Department of Special Collections, Davidson Library, University of California, Santa Barbara. Acquisition Information Undetermined. Biography Alan J. Heeger is currently a Professor of Physics and the Director of the Institute for Polymers and Organic Solids at the University of California, Santa Barbara. He was awarded the Nobel Prize for Chemistry in 2000 along with his colleagues Alan MacDiarmid and Hideki Shirakawa for their work in the field of conductive polymers. Heeger was born on January 22, 1936 in Sioux City, Iowa. He received a dual bachelor's degree in Physics and Mathematics from the University of Nebraska in 1957. In 1961, he received his PhD in Physics from the University of California, Berkeley while working for Lockheed Space and Missile Division. He joined the faculty of the University of Pennsylvania the following year, where he remained for twenty years. In 1975, Heeger met Alan MacDiarmid and together they began work in the field Guide to the Alan J. Heeger UArch FacP 39 2 Papers of metallic polymers. On a visit to Japan, MacDiarmid met Hideki Shirakawa, who came to the University of Pennsylvania as a Visiting Scientist. Heeger left the University of Pennsylvania for UC Santa Barbara in 1982 and became part of the new Physics Department. Several years later, he assisted in developing the Macromolecular division of the new Materials Department. In 1986, Heeger and his colleagues encouraged Paul Smith of DuPont Central Research to join him at UC Santa Barbara and in 1990, they founded the UNIAX Corporation to develop commercial products from polymer materials, which was later acquired by DuPont. Heeger's research at UC Santa Barbara covers the fields of conducting and semiconducting polymers, including research in polymer light-emitting diodes, light-emitting electrochemical cells and lasers, photoluminescent and electroluminescent studies, photoconductivity, and spectroscopic studies. Heeger has been married to his wife Ruth for over forty years. His two sons also work in the sciences: David Heeger is a neuroscientist and Peter Heeger is an immunologist. For more biographical information see also the following: Official Nobel Prize website at http://nobelprize.org/nobel_prizes/chemistry/laureates/2000/index.html Institute for Polymers and Organic Solids page for Alan Heeger at http://www.ipos.ucsb.edu/ajh.html Office of Public Information biographical files, UArch 11, in University Archives Scope and Content of Collection The Alan J. Heeger papers contain a large number of drafts, manuscripts, and correspondence relating to journal articles, conference papers, and patent applications, including files on his Nobel Prize-winning work. Also included are some materials from Heeger's college days and his work as an instructor at UCSB. Arrangement The collection is arranged in the following series: Series I, Manuscripts, includes drafts, final copies, figures, and correspondence relating to articles published by Heeger and his colleagues. Not all articles are authored by Heeger. Arranged alphabetically (as received) by article title. Series II, Conferences, includes drafts of papers submitted to conferences by Heeger and his colleagues, correspondence relating to conferences, and copies of conference publications. Arranged chronologically by conference date. Series III, Patent Documentation, includes drafts of and amendments to patent applications by Heeger and his colleagues, as well as correspondence relating to the patents. Arranged chronologically according to date filed with the University of California and/or US Patent Office. Series IV, Overheads, contains overheads from course and conferences presentations, arranged alphabetically by subject title. Series V, Notebooks, contains early class notes and papers from Heeger's college career. Indexing Terms The following terms have been used to index the description of this collection in the library's online public access catalog. Heeger, Alan J. -- Archives. University of California, Santa Barbara. Dept. of Physics. University of California, Santa Barbara -- Faculty. Nobel Prize-winning scientists. Conducting polymers. Related Materials Other UCSB Nobel Laureates in University Archives Faculty Papers: Walter Kohn, Professor Emeritus of Physics and founding director of the Kavli Institute of Theoretical Physics, recipient of the 1998 Nobel Prize for Chemistry. FacP 34. Herbert Kroemer, Professor of Electrical and Computer Engineering and Materials, recipient of the 2000 Nobel Prize for Physics. FacP 42. Related collections in University Archives: Office of Public Information biographical files, UArch 11 Resources in the Main Library: Guide to the Alan J. Heeger UArch FacP 39 3 Papers Nonlinear optical properties of polymers: symposium held December 1-3, 1987, Boston, Massachussetts, U.S.A., eds. Alan J. Heeger, Joseph Orenstein, Donald R. Ulrich. Sciences Engineering Library QD381.9.O66 N66 1988. Articles by Heeger may also be found in databases such as Web of Science, accessible through the library website. Series I: Manuscripts Box 1: 1 "[3 + 2] and [4 + 2] Cycloadditions of C60," M. Prato et al J. Amer. Chem. Soc. 115, 1594, 1992 Box 1: 2 "3-oxo-4-thioxo-1,2,5,6-tetrathiapentalene (OTTP): A Novel Thiocarbon with an Unusual Chalcogen Network in its Solid State Structure," Closs, Srdanov and Wudl, June-Oct. 1989 Box 1: 3 "A 160-Femtosecond Optical Image Processor Based on a Conjugated Polymer," C. Halvorson et al Apr. 1994-Aug. 1995 Box 1: 4 "Absence of Photoinduced Electron Transfer from the excitonic electron-hole bound state in...," N.S. Sariciftci et al Feb-Oct. 1994 Box 1: 5 "Absorption Detected Magnetic Resonance Studies of Photoexications in Conjugated-polymer C60 Composites," by Z. Wei et al n.d. Box 1: 6 "Absorption Spectra and Electronic Properties of Alkali Metal Doped C60," V.I. Sardanov et al n.d. Box 1: 7 "Absorption Spectroscopy of Nonlinear Excitations in Polyaniline," N.S. Sariciftci et al J. Chem. Phys. 98 (4), 2664, Aug. 1992-Feb. 1993 Box 1: 8 "AC Impedance of Frozen Junction Polymer Light-emitting Electrochemical Cells," Y. Li et al June-Nov. 1998 Box 1: 9 "AC Impedance of Polymer Light-emitting Electrochemical Cells and Light-emitting Diodes: A Comparative Study," Y. Li et al May 1995-May 1998 Box 1: 10 "Addition of Azides to C60: Synthesis of Azafulleroids," M. Prato et al J. Amer. Chem. Soc. 115, 1148, Oct. 1991-Sept. 1992 Box 1: 11 "Addition Reactions of C60 Leading to Fullerprolines," by M. Maggini et al 1994 Box 1: 12 "A Facile Formation of Fullerene Adducts from Sultines via a Diels-Alder Reaction," B. Illescas et al 1995 Box 1: 13 "A Heteroaromatic Trimethylenemethane," F. Wudl et al Oct. 1987-1988 Box 1: 14 "Alkali Vapor Phase Doping of Polyacetylene," Moses et al n.d. Box 1: 15 "Amplified Spontaneous Emission from an MEH-PPV film in Cylindrical Geometry," J.Y. Park et al Nov. 1998-Feb. 1999 Box 1: 16 "Amplified Spontaneous Emission from Photopumped Films of a Conjugated Polymer," M.D. McGehee et al Jan-June 1998 Box 2: 1 "An Analytic Model for the Polymer Grid Triode," J. McElvain and A.J. Heeger, Mar-Aug. 1996 Box 2: 2 "A New Preparation of 5-Alkylthio-1,2 Dithiole-3-thiones and A Highly Functionalized 1,3-Dithiole-2-Thione," W.-L. Lu et al Jan. 4, 1989 Box 2: 3 "A New Type of Polyenaminonitrile Analogous to Polyphenyleneurea," Shi and Wudl, July 1990-Feb. 1991 Box 2: 4 "Anharmonicity and Frequency Shift of the Apex Oxygen 0(4) Raman Mode in Y1Ba2Cu3 O7-δ," Mihailovic and Foster, Jan. 19, 1990 Box 2: 5 "An Improved Isolation of Triformylmethane (TFM): Properties & Preparation of Some Derivatives," Keshavarz et al Oct. 1987-Feb. 1988 Box 2: 6 "Anisotropic Conductivity in Polyaniline and Image Processing Applications," M. Costolo and A.J. Heeger, Syn. Met. 114 (1) 85, Feb-Apr. 2000 Box 2: 7 "Anisotropy of the Third Order Nonlinear Optical Susceptibility in a Degenerate Ground State...," Sinclair et al Dec.
Recommended publications
  • Worldwide Electroactive Polymers
    WorldWide ElectroActive Polymers EAP (Artificial Muscles) Newsletter December 2000 WW-EAP Newsletter Vol. 2, No. 2 http://ndeaa.jpl.nasa.gov/nasa-nde/lommas/eap/EAP-web.htm FROM THE EDITOR development of niche applications that take advantage of the unique capabilities of EAPs. The Yoseph Bar-Cohen, JPL [email protected] following are the application categories are currently being considered: (a) Human-Machine Interfaces: The field of EAP is continuing to expand and the Haptic and tactile interfaces, Simulated textures and number of investigators and potential users that body orientation Indicators, Interfacing neuron to are joining this effort is steadily growing. A electronic devices, Active tactile display for the reflection of this growth has been seen in the blind and artificial nose; (b) Planetary Applications; number of abstracts that were submitted to the (c) Controlled Weaving: Garments, clothing and anti upcoming SPIE EAPAD 2001 Conference. While G-Suit; (d) Biologically -Inspired Robotics, Toys and in the first two years about 50 abstracts were Animatronics; (e) Medical Applications: EAP for submitted, for the upcoming conference over 70 biological muscle augmentation or replacement, abstracts were submitted. The topics of research Miniature in-vivo EAP robots for diagnostics and that would be presented are covering a broad microsurgery, Catheter steering mechanism, Tissues range of topics spanning from analytical modeling growth engineering, and active Bandage (f) Liquid to application considerations. and gas flow control and pumping; (g) Noise reduction; (h) Electromechanical polymer sensors In an effort to simplify the terminologies that are and transducers; and (i) Micro-electro-mechanical related to EAP materials, the Editor sought terms systems (MEMS) for grouping these materials.
    [Show full text]
  • Kinetics of Ion Transport in Conducting Polymers
    Kinetics of Ion Transport in Conducting Polymers Dissertation Presented in Partial Fulfillment of the Requirements for the Degree Doctor of Philosophy in the Graduate School of The Ohio State University By Vinithra Venugopal, B.E., M.S. Graduate Program in Mechanical Engineering The Ohio State University 2016 Dissertation Committee: Dr. Vishnu Baba Sundaresan, Advisor Dr. Carlos Castro Dr. Jose Otero Dr. Jonathan Song Dr. Vishwanath Subramaniam c Copyright by Vinithra Venugopal 2016 Abstract Conducting polymers (CPs) exhibit coupling between electrochemical and me- chanical domains, namely, reversible ion exchange with an electrolyte under an ap- plied electrical voltage causes volumetric changes in the polymer matrix. The goal of this dissertation is to develop precise quantification techniques to assess the kinetics of ion transport in CPs. These techniques are based on the mechanics of ion storage in polypyrrole doped with dodecylbenzene sulfonate (PPy(DBS)). In this work, it is postulated that CP response is dictated by the driving force for ion ingress and the accessible ion storage sites in the polymer. Two mechanis- tic models are founded on this premise: (1) A mathematical constitutive model is derived from the first law of thermodynamics to describe the chemomechanically cou- pled, structure dependent, input-output relationship in PPy(DBS). The uniqueness of this model is that mechanical expansion of the polymer is predicted without the incorporation of empirical coefficients. (2) A kinetic model is proposed to describe the current and charge response of PPy(DBS) to a step voltage input. The transfer- function based approach used to validate this model offers advantages over traditional lumped parameter models by quantifying the effect of polymer mass and morphology on the magnitude and rate of ion ingress.
    [Show full text]
  • Electroactive Polymers Joana Costa
    Corso “Materiali intelligenti e biomimetici” Electroactive Polymers Joana Costa 18 – 05 – 18 [email protected] 1 Electroactive Polymers General applications of EAP’s Ionic vs Electronic EAP’s Ionic EPS’s OUTLINE Electronic EAP’s Braille display from the University of Tokyo DEA’s Requirements Examples Case of study: a bioreactor for mechanical stimulation of cells 2 External stimulus Electroactive polymers Property(ies) change 3 Electrical stimulus Electroactive polymers EAP Mechanical response 4 Input voltage, V Electrical stimulus Electroactive EAP polymers Mechanical response Output strain, ε 5 Why use them? Electrical stimulus EAP Mechanical response SOFT ACTUATORS 6 Why use them? Electrical stimulus SENSORS AND ENERGY HARVERSTERS EAP Mechanical response SOFT ACTUATORS 7 Why use them? Electrical stimulus SENSORS AND efficient energy output ENERGY HARVERSTERS high strains high mechanical compliance EAP shock resistance low mass density no acoustic noise ease of processing Mechanical high scalability response low cost SOFT ACTUATORS ARTIFICIAL MUSCLES 8 compliant and light weight drive mechanisms GENERAL APPLICATIONS 1 intrinsically safe robots, anthropomorphic robots and humanoids locomotion systems (https://www.youtube.com/watch?v=7Qxvyw5tUko) bioinspired and biomimetic systems (https://www.youtube.com/watch?v=Y4Q16LBXC9c) robotic hands/arms/legs/wings/fins grippers and manipulators (https://www.youtube.com/watch?v=DzX7BHYTTCE) haptic devices and tactile displays (https://www.youtube.com/watch?v=dWsVDKNOyY4) 9 variable stiffness devices and linkages and active vibration GENERAL dampers APPLICATIONS 2 minimally invasive interventional/diagnostic medical tools controlled drug delivery devices fluidic valves and pumps tuneable optical and acoustic systems (https://www.youtube.com/watch?v=5K5KSDL1gXE) systems to convert mechanical energy into electrical energy for mechanosensing and motion energy harvesting.
    [Show full text]
  • Electroactive Polymers in Space: Design Considerations and Possible Applications
    In Proceedings of the 9th ESA Workshop on Advanced Space Technologies for Robotics and Automation 'ASTRA 2006' ESTEC, Noordwijk, The Netherlands, November 28-30, 2006 Electroactive Polymers in Space: Design Considerations and Possible Applications Maarja Kruusmaa(1), Paolo Fiorini(2) (1)Intelligent Materials and Systems Laboratory Tartu University Institute of Technology Nooruse 1, 50411 Tartu, Estonia Email: [email protected] (2)Department of Computer Science, University of Verona Ca' Vignal 2 - Strada Le Grazie 15, 37134 Verona, Italy Email: [email protected] ABSTRACT This paper gives an overview of the technology of Electroactive Polymer (EAP) materials. We focus specifically on ionic conductive polymer materials (IPMC) as a rapidly maturing technology with first commercial applications available, which have also been considered for space applications for almost a decade. We briefly describe their properties and their working principle. Next, we describe IPMC materials working as sensors and actuators and their potential of use in biomimetic devices. In the following we briefly discuss the challenges of IPMC sensor and actuator control. Finally, we envision some possible applications of these materials to space systems. INTRODUCTION The robotic applications developed and exploited so far use almost exclusively electromechanical actuators. The technology of electromechanical devices is very well established, and has thorough theoretical background, control methods and reliable applications demonstrated during several decades. This technology has obviously reached its maturity and therefore its limits have also become visible. Devices using this technology need rigid links to connect the rotating joints, gears and bearings and they are therefore unavoidably complex, rigid and noisy. At the current state of development it is hard to reduce the size and energy consumption of these devices.
    [Show full text]
  • Worldwide Electroactive Polymers
    WW-EAP Newsletter, Vol. 7, No. 1, June 2005 WorldWide ElectroActive Polymers EAP (Artificial Muscles) Newsletter June 2005 WW-EAP Newsletter Vol. 7, No.1 http://eap.jpl.nasa.gov 1st Wrestling Match between Human and EAP Actuated Robotic Arms was Held on March 7, 2005 in San Diego, CA flight and its advances to the level of today, the FROM THE EDITOR editor is hoping to see a similar success in making Yoseph Bar-Cohen, [email protected] EAP benefit every human being in one way or another. Further information about the competition On March 7, 2005, a major milestone was is available on http://ndeaa.jpl.nasa.gov/nasa- accomplished in the field of EAP – we held the first nde/lommas/eap/EAP-armwrestling.htm Armwrestling Match of EAP Robotic Arm against Human (AMERAH). The competition was hosted by SPIE during the EAP-in-Action Session of the EAPAD Conf., at the Town & Country Resort, San Diego, CA. Three organizations participated in this competition bringing their EAP actuated arms that were driven by different mechanisms. The participating organizations included: Environmental Robots Incorporated (ERI), Albuquerque, NM; EMPA, Swiss Federal Laboratories for Materials Testing and Research, Dubendorf, Switzerland; and students from Virginia Tech. Even though all three arms lost against the student, Panna Felsen, the ERI arm was able to hold for 26-second. This is a major accomplishment for the field and in order to get a prospective of the importance of this milestone one FIGURE 1: Panna Felsen, 17-year old student from may want to remember that the first flight lasted 12- San Diego, CA, wrestling with the EAP driven arm seconds.
    [Show full text]
  • Modelling of an Ionic Electroactive Polymer by the Thermodynamics of Linear Irreversible Processes Mireille Tixier, Joël Pouget
    Modelling of an Ionic Electroactive Polymer by the Thermodynamics of Linear Irreversible Processes Mireille Tixier, Joël Pouget To cite this version: Mireille Tixier, Joël Pouget. Modelling of an Ionic Electroactive Polymer by the Thermodynamics of Linear Irreversible Processes. H. Altenbach, J. Pouget, M. Rousseau, B. Collet, T. Michelitsch. Generalized Models and Non Classical Mechanical Approaches in Complex Materials 1, 1, Springer- Verlag, Chapitre 39, 2018, Generalized Models and Non Classical Mechanical Approaches in Complex Materials. hal-03106340 HAL Id: hal-03106340 https://hal.archives-ouvertes.fr/hal-03106340 Submitted on 11 Jan 2021 HAL is a multi-disciplinary open access L’archive ouverte pluridisciplinaire HAL, est archive for the deposit and dissemination of sci- destinée au dépôt et à la diffusion de documents entific research documents, whether they are pub- scientifiques de niveau recherche, publiés ou non, lished or not. The documents may come from émanant des établissements d’enseignement et de teaching and research institutions in France or recherche français ou étrangers, des laboratoires abroad, or from public or private research centers. publics ou privés. Distributed under a Creative Commons Attribution - NonCommercial - NoDerivatives| 4.0 International License Modelling of an Ionic Electroactive Polymer by the Thermodynamics of Linear Irreversible Processes M. Tixier and J. Pouget Abstract Ionic polymer-metal composites consist in a thin film of electro-active polymers (Nafion for example) sandwiched between two metallic electrodes. They can be used as sensors or actuators. The polymer is saturated with water, which causes a complete dissociation and the release of small cations. The strip undergoes large bending motions when it is submitted to an orthogonal electric field and vice versa.
    [Show full text]
  • Dielectric Elastomers for Energy Harvesting
    Heriot-Watt University Research Gateway Dielectric Elastomers for Energy Harvesting Citation for published version: Thomson, G, Yurchenko, D & Val, DV 2018, Dielectric Elastomers for Energy Harvesting. in R Manyala (ed.), Energy Harvesting. IntechOpen. https://doi.org/10.5772/intechopen.74136 Digital Object Identifier (DOI): 10.5772/intechopen.74136 Link: Link to publication record in Heriot-Watt Research Portal Document Version: Publisher's PDF, also known as Version of record Published In: Energy Harvesting Publisher Rights Statement: © 2018 The Author(s). Licensee InTech. This chapter is distributed under the terms of the Creative Commons Attribution License (http://creativecommons.org/licenses/by/3.0), which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited. General rights Copyright for the publications made accessible via Heriot-Watt Research Portal is retained by the author(s) and / or other copyright owners and it is a condition of accessing these publications that users recognise and abide by the legal requirements associated with these rights. Take down policy Heriot-Watt University has made every reasonable effort to ensure that the content in Heriot-Watt Research Portal complies with UK legislation. If you believe that the public display of this file breaches copyright please contact [email protected] providing details, and we will remove access to the work immediately and investigate your claim. Download date: 26. Sep. 2021 DOI: 10.5772/intechopen.74136 ProvisionalChapter chapter 4 Dielectric Elastomers forfor EnergyEnergy HarvestingHarvesting Gordon Thomson, Daniil YurchenkoYurchenko andand Dimitri V. Val Additional information isis available atat thethe endend ofof thethe chapterchapter http://dx.doi.org/10.5772/intechopen.74136 Abstract Dielectric elastomers are a type of electroactive polymers that can be conveniently used as sensors, actuators or energy harvesters and the latter is the focus of this review.
    [Show full text]
  • Electroactive Polymers
    Electroactive polymers Three main kinds of materials metals, plastics and ceramics. w.wang 198 Preface I am inclined to think that the development of polymerization is, perhaps, the biggest thing chemistry has done, where it has had the biggest effect on everyday life. The world would be a totally different place without artificial fibers, plastics, elastomers etc. Even in the field of electronics, what would you do without insulation? And there you come back to polymers again.--- Lord Todd, president of the Royal Society of London, quoted in Chem. Eng. News 58 (40), 29 (1980), in answer to the question, What do you think has being chemistry’s biggest contribution to science, to society? From clothing to the artificial heart, polymers touch our lives as do no other class of materials, with no end in sight for new uses and improved products. w.wang 199 Polymer Macromolecule Out line of the science of large molecules Polymers Biological materials Plant fiber, starch saccharin etc. Plastics fibers, elastomers Nonbiological materials Rubber, wool, cellulose, silk and leather etc. w.wang 200 Some linear high polymer, their monomers, and their repeat units Polymer Monomer Repeat Unit CH2 CH2 CH2CH2 CH CHCl • Polyethylene CH2 CHCl 2 • Poly(vinyl chloride) CH3 CH3 CH2 C CH2 C CH CH • Polyisobutylene 3 3 CH2 CH CH2 CH • Polystyrene H N(CH2)5C OH N(CH2)5C • Polycaprolactam (6- H H nylon) O O CH CH 2 CH2 CH2 CH2CH CH2 CH2 • Polyisoprene (natural CH3 CH3 rubber) w.wang 201 Polymerization • Step-reaction (Condensation) polymerization • Radical chain
    [Show full text]
  • Electroactive Smart Polymers for Biomedical Applications
    materials Review Electroactive Smart Polymers for Biomedical Applications Humberto Palza 1,2,*, Paula Andrea Zapata 3 and Carolina Angulo-Pineda 1 1 Departamento de Ingeniería Química, Biotecnología y Materiales, Facultad de Ciencias Físicas y Matemáticas, Universidad de Chile, 8370456 Santiago, Chile; [email protected] 2 Millenium Nuclei in Soft Smart Mechanical Metamaterials, Universidad de Chile, 8370456 Santiago, Chile 3 Grupo de Polímeros, Facultad de Química y Biología, Universidad de Santiago de Chile, 8350709 Santiago, Chile; [email protected] * Correspondence: [email protected]; Tel.: +56-229-784-085 Received: 6 December 2018; Accepted: 9 January 2019; Published: 16 January 2019 Abstract: The flexibility in polymer properties has allowed the development of a broad range of materials with electroactivity, such as intrinsically conductive conjugated polymers, percolated conductive composites, and ionic conductive hydrogels. These smart electroactive polymers can be designed to respond rationally under an electric stimulus, triggering outstanding properties suitable for biomedical applications. This review presents a general overview of the potential applications of these electroactive smart polymers in the field of tissue engineering and biomaterials. In particular, details about the ability of these electroactive polymers to: (1) stimulate cells in the context of tissue engineering by providing electrical current; (2) mimic muscles by converting electric energy into mechanical energy through an electromechanical response;
    [Show full text]
  • Low Temperature Electrical Transport Studies of the Conducting Polymer Versicontm
    American Journal of Analytical Chemistry, 2019, 10, 504-512 https://www.scirp.org/journal/ajac ISSN Online: 2156-8278 ISSN Print: 2156-8251 Low Temperature Electrical Transport Studies TM of the Conducting Polymer Versicon Peter K. LeMaire Department of Physics & Engineering Physics, Central Connecticut State University, New Britain, CT, USA How to cite this paper: LeMaire, P.K. Abstract (2019) Low Temperature Electrical Trans- port Studies of the Conducting Polymer Thermal analysis and low temperature D.C. electrical transport measure- VersiconTM. American Journal of Analytical ments of the conducting polymer VersiconTM were carried out between 20 K Chemistry, 10, 504-512. and 300 K. The material was found to be stable up to 498 K (225˚C), with a https://doi.org/10.4236/ajac.2019.1010036 glass transition at 210 K (−63˚C), and a crystalline transition at 436 K Received: September 17, 2019 (163˚C). The electrical resistivity data best fitted the Fluctuation Induced Accepted: October 27, 2019 Tunneling (FIT) model, suggesting that at low temperatures, the electron Published: October 30, 2019 transport is by tunneling through thermally modulated barriers. The high Copyright © 2019 by author(s) and temperature data best fitted the thermally activated hopping model, with an Scientific Research Publishing Inc. activation energy of 0.015 eV, suggesting that the thermally activated hopping This work is licensed under the Creative may be a parallel transport process to fluctuation induced tunneling, becom- Commons Attribution International ing dominant at higher temperatures. From the FIT model the inter-particle License (CC BY 4.0). http://creativecommons.org/licenses/by/4.0/ distance was estimated to be 12 Å.
    [Show full text]
  • Euroeap 2012 Second International Conference on Electromechanically Active Polymer (EAP) Transducers & Artificial Muscles
    EuroEAP 2012 Second International conference on Electromechanically Active Polymer (EAP) transducers & artificial muscles Potsdam, Germany 29-30 May 2012 Technical programme Book of abstracts List of participants Contents Conference venue ............................................................................................... 3 Conference chairman .......................................................................................... 3 Local organization .............................................................................................. 3 Presentation of the EuroEAP conference series .................................................. 4 Conference committees ...................................................................................... 5 Tuesday, 29 May 2012 ....................................................................................... 7 General programme of the day ..................................................................... 7 Session 1.1 ................................................................................................... 8 Session 1.2 ................................................................................................. 11 Session 1.3 ................................................................................................. 23 Wednesday, 30 May 2012 ................................................................................ 35 General programme of the day ................................................................... 35 Session 2.1 ................................................................................................
    [Show full text]
  • Electroactive Polymers for Sensing
    Downloaded from http://rsfs.royalsocietypublishing.org/ on July 5, 2016 Electroactive polymers for sensing Tiesheng Wang1,2, Meisam Farajollahi3, Yeon Sik Choi1, I-Ting Lin1, Jean E. Marshall1, Noel M. Thompson1, Sohini Kar-Narayan1, rsfs.royalsocietypublishing.org John D. W. Madden3 and Stoyan K. Smoukov1 1Department of Materials Science and Metallurgy, University of Cambridge, Cambridge CB3 0FS, UK 2EPSRC Centre for Doctoral Training in Sensor Technologies and Applications, University of Cambridge, Cambridge CB2 3RA, UK Review 3Advanced Materials and Process Engineering Laboratory, University of British Columbia, Vancouver, British Columbia, Canada V6T 1Z4 Cite this article: Wang T, Farajollahi M, Choi TW, 0000-0001-7587-7681; MF, 0000-0001-8605-2589; YSC, 0000-0003-3813-3442; YS, Lin I-T, Marshall JE, Thompson NM, I-TL, 0000-0001-9025-9611; JEM, 0000-0001-7617-4101; NMT, 0000-0002-9310-169X; Kar-Narayan S, Madden JDW, Smoukov SK. SK-N, 0000-0002-8151-1616; JDWM, 0000-0002-0014-4712; SKS, 0000-0003-1738-818X 2016 Electroactive polymers for sensing. Electromechanical coupling in electroactive polymers (EAPs) has been widely Interface Focus 6: 20160026. applied for actuation and is also being increasingly investigated for sensing http://dx.doi.org/10.1098/rsfs.2016.0026 chemical and mechanical stimuli. EAPs are a unique class of materials, with low-moduli high-strain capabilities and the ability to conform to surfaces One contribution of 8 to a theme issue of different shapes. These features make them attractive for applications such as wearable sensors and interfacing with soft tissues. Here, we review ‘Sensors in technology and nature’. the major types of EAPs and their sensing mechanisms.
    [Show full text]