| Record ID | marc_columbia/Columbia-extract-20221130-030.mrc:120247230:8011 |
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LEADER: 08011cam a2200769 i 4500
001 14752452
005 20220403000858.0
006 m o d
007 cr cnu|||unuuu
008 190329s2019 flua ob 001 0 eng d
035 $a(OCoLC)on1090812973
035 $a(NNC)14752452
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020 $a9780429190520$q(electronic bk.)
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020 $a9780429539121$q(electronic bk. ;$qMobipocket)
020 $a0429539126$q(electronic bk. ;$qMobipocket)
020 $a9781315159294$q(electronic bk. ;$qPDF)
020 $a1315159295$q(electronic bk. ;$qPDF)
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035 $a(OCoLC)1090812973
050 4 $aQD382.C66
072 7 $aTEC$x009000$2bisacsh
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049 $aZCUA
245 00 $aConjugated polymers :$bproperties, processing, and applications /$cedited by John R. Reynolds, Barry C. Thompson, Terje A. Skotheim,
250 $aFourth edition.
264 1 $aBoca Raton, FL :$bCRC Press,$c[2019]
300 $a1 online resource :$billustrations
336 $atext$btxt$2rdacontent
337 $acomputer$bc$2rdamedia
338 $aonline resource$bcr$2rdacarrier
490 1 $aHandbook of conducting polymers
504 $aIncludes bibliographical references and index.
588 0 $aOnline resource; title from PDF title page (EBSCO, viewed April 01, 2019).
520 $aThis book covers properties, processing, and applications of conducting polymers. It discusses properties and characterization, including photophysics and transport. It then moves to processing and morphology of conducting polymers, covering such topics as printing, thermal processing, morphology evolution, conducting polymer composites, thin films
545 0 $aTerje A. Skotheim is the founder of Lightsense and has a successful record in developing new technologies and launching new products in fields as diverse as advanced lithium-sulfur batteries, MEMS devices, photovoltaic cells, and biosensors, through several startups. His research interests have spanned across several disciplines in materials science, including conducting polymers, semiconductors, ion conductors and diamond-like carbon. He has held research positions and co-founded companies in Europe and the US, and was head of the conducting polymer group at DOE's Brookhaven National Laboratory before launching his career as an entrepreneur. He received his B.S. in physics from the Massachusetts Institute Technology and his Ph. D. in physics from the University of California at Berkeley. John R. Reynolds, a native Californian, obtained his B.S. in Chemistry at San Jose State University (1979) followed by his M.S. (1982) and Ph. D. (1984) in Polymer Science and Engineering at the University of Massachusetts. He became interested in the field of conducting and electroactive polymers through a position with the IBM Research Laboratories in the late 1970s. After developing his own research effort at The University of Texas at Arlington (1984-1991), he moved to the University of Florida where he was a Professor of Chemistry and Associate Director of the Center for Macromolecular Science and Engineering until Spring 2012, when his group moved to Georgia Tech where he is a Professor of Chemistry and Biochemistry, and Materials Science and Engineering. He serves as Director of the Georgia Tech Polymer Network (GTPN) and is a member of the Center for Organic Photonics and Electronics (COPE) management team. Barry C. Thompson was born in Milwaukee, Wisconsin in 1977 and moved to Gallipolis, Ohio at a young age, where he attended elementary and high school. Barry then attended the University of Rio Grande in Rio Grande, Ohio, where he m
505 0 $aCover; Half Title; Title Page; Copyright Page; Table of Contents; Editors; Contributors; 1: Conjugated Polymer- Based OFET Devices; Mark Nikolka and Henning Sirringhaus; 1.1 Introduction; 1.2 State of OFET Technology/Applications/ Commercialization Efforts; 1.3 Recent Developments in Polymer OFET Materials -- From Crystalline Polythiophenes to Donor-Acceptor Polymers; 1.4 Charge Transport in Polymer OFETs; 1.5 Role of Disorder; 1.6 Charge Carrier Mobility and Artefacts; 1.7 Stability of OFETs; 1.8 Outlook; References
505 8 $a2: Electrical Doping of Organic Semiconductors with Molecular Oxidants and ReductantsStephen Barlow, Seth R. Marder, Xin Lin, Fengyu Zhang, and Antoine Kahn; 2.1 Introduction; 2.2 Basics of Doping in Organic Materials; 2.2.1 Comparison to Doping of Inorganic Materials; 2.2.2 Effects of Doping; 2.2.2.1 Enhancement of Conductivity; 2.2.2.2 Lowering of Injection Barriers; 2.3 Criteria for Dopant Choice; 2.4 Survey of Dopants; 2.4.1 p-Dopants; 2.4.1.1 Inorganic p-Dopants; 2.4.1.2 Organic and Metal-Organic p-Dopants; 2.4.2 n-Dopants; 2.4.2.1 One-Electron Reductants; 2.4.2.2 Air-Stable n-Dopants
505 8 $a2.5 Device Examples2.5.1 OLEDs; 2.5.2 OFETs; 2.5.3 OPVs; 2.6 Summary; Acknowledgments; References; 3: Electric Transport Properties in PEDOT Thin Films; Nara Kim, Ioannis Petsagkourakis, Shangzhi Chen, Magnus Berggren, Xavier Crispin, Magnus P. Jonsson, and Igor Zozoulenko; 3.1 Introduction; 3.2 Chemistry of PEDOT; 3.2.1 Chemical vs. Electrochemical Polymerization of PEDOT:X; 3.2.2 Chemical Water Dispersion: PEDOT:PSS; 3.2.3 PEDOT:Biopolymer Dispersion Polymerization; 3.2.4 Tuning the Oxidation/Doping Level Chemically vs. Electrochemically
505 8 $a3.3 Electronic Structure of PEDOT: From a Single Chain to a Thin Film3.3.1 Nature of Charge Carriers and Electronic Structure of PEDOT Chains; 3.3.2 Density of States of PEDOT: From a Single Chain to a Thin Film; 3.3.3 Band Gap and Optical Transitions in PEDOT; 3.4 Morphology of PEDOT; 3.4.1 Brief Review of Experimental Data for PEDOT:X and PEDOT:PSS (GIWAXS, TEM, AFM); 3.4.2 Morphology of PEDOT: A Theoretical Perspective; 3.4.2.1 Molecular Dynamics Simulation of the Morphology; 3.4.2.2 Effect of Counter-Ions at High Oxidation Levels; 3.4.2.3 Effect of Substrates; 3.5 Electrical Conductivity
505 8 $a3.5.1 Basic Thermodynamics of Thermoelectrical Processes3.5.2 Temperature Dependence; 3.5.3 Secondary Doping; 3.5.4 Acid-Base Effect; 3.6 Optical Conductivity; 3.6.1 Basic Definitions and Relations; 3.6.2 Methodologies for Measuring the Dielectric Function; 3.6.2.1 Optical Parameters from Transmittance and Reflectance Measurements; 3.6.2.2 Terahertz Time-Domain Spectroscopy (THz-TDS); 3.6.2.3 Variable Angle Spectroscopic Ellipsometry (VASE); 3.6.3 Optical Conductivity and Permittivity of PEDOT; 3.6.3.1 Anisotropy, Interfacial Layers, and Substrate Effects
650 0 $aConducting polymers.
650 0 $aOrganic conductors.
650 6 $aPolymères conducteurs.
650 6 $aConducteurs organiques.
650 7 $aTECHNOLOGY & ENGINEERING$xEngineering (General)$2bisacsh
650 7 $aTECHNOLOGY & ENGINEERING$xReference.$2bisacsh
650 7 $aTECHNOLOGY$xEngineering$xChemical & Biochemical.$2bisacsh
650 7 $aTECHNOLOGY$xMaterial Science.$2bisacsh
650 7 $aTECHNOLOGY$xTextiles & Polymers.$2bisacsh
650 7 $aConducting polymers.$2fast$0(OCoLC)fst00874590
650 7 $aOrganic conductors.$2fast$0(OCoLC)fst01047677
655 4 $aElectronic books.
700 1 $aReynolds, John R.,$d1956-$eeditor.
700 1 $aThompson, Barry C.,$eeditor.
700 1 $aSkotheim, Terje A.,$d1949-$eeditor.
830 0 $aHandbook of conducting polymers.
856 40 $uhttp://www.columbia.edu/cgi-bin/cul/resolve?clio14752452$zTaylor & Francis eBooks
852 8 $blweb$hEBOOKS