| Record ID | harvard_bibliographic_metadata/ab.bib.14.20150123.full.mrc:143474752:3879 |
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LEADER: 03879nam a22005295a 4500
001 014104343-1
005 20140711195634.0
008 110414s2010 gw | s ||0| 0|eng d
020 $a9783642045387
020 $a9783642045387
020 $a9783642045370
024 7 $a10.1007/978-3-642-04538-7$2doi
035 $a(Springer)9783642045387
040 $aSpringer
050 4 $aQD380-388
072 7 $aPNNP$2bicssc
072 7 $aTEC055000$2bisacsh
082 04 $a541.2254$223
100 1 $aGrasser, Tibor,$eeditor.
245 10 $aOrganic Electronics /$cedited by Tibor Grasser, Gregor Meller, Ling Li.
264 1 $aBerlin, Heidelberg :$bSpringer Berlin Heidelberg,$c2010.
300 $aXIV, 328p.$bonline resource.
336 $atext$btxt$2rdacontent
337 $acomputer$bc$2rdamedia
338 $aonline resource$bcr$2rdacarrier
347 $atext file$bPDF$2rda
490 1 $aAdvances in Polymer Science,$x0065-3195 ;$v223
505 0 $aDescription of Charge Transport in Disordered Organic Materials -- Drift Velocity and Drift Mobility Measurement in Organic Semiconductors Using Pulse Voltage -- Effective Temperature Models for the Electric Field Dependence of Charge Carrier Mobility in Tris(8-hydroxyquinoline) Aluminum -- Bio-Organic Optoelectronic Devices Using DNA -- Comparison of Simulations of Lipid Membranes with Membranes of Block Copolymers -- Low-Cost Submicrometer Organic Field-Effect Transistors -- Organic Field-Effect Transistors for CMOS Devices -- Biomimetic Block Copolymer Membranes -- Steady-State Photoconduction in Amorphous Organic Solids -- Charge Transport in Organic Semiconductor Devices.
520 $aDear Readers, Since the ground-breaking, Nobel-prize crowned work of Heeger, MacDiarmid, and Shirakawa on molecularly doped polymers and polymers with an alternating bonding structure at the end of the 1970s, the academic and industrial research on hydrocarbon-based semiconducting materials and devices has made encouraging progress. The strengths of semiconducting polymers are currently mainly unfolding in cheap and easily assembled thin ?lm transistors, light emitting diodes, and organic solar cells. The use of so-called “plastic chips” ranges from lightweight, portable devices over large-area applications to gadgets demanding a degree of mechanical ?exibility, which would overstress conventionaldevices based on inorganic,perfect crystals. The ?eld of organic electronics has evolved quite dynamically during the last few years; thus consumer electronics based on molecular semiconductors has gained suf?cient market attractiveness to be launched by the major manufacturers in the recent past. Nonetheless, the numerous challenges related to organic device physics and the physics of ordered and disordered molecular solids are still the subjects of a cont- uing lively debate. The future of organic microelectronics will unavoidably lead to new devi- physical insights and hence to novel compounds and device architectures of - hanced complexity. Thus, the early evolution of predictive models and precise, computationally effective simulation tools for computer-aided analysis and design of promising device prototypes will be of crucial importance.
650 20 $aChemistry, Physical and theoretical.
650 20 $aChemistry, Organic.
650 20 $aSolid state physics.
650 10 $aChemistry.
650 0 $aPhysical organic chemistry.
650 0 $aChemistry.
650 0 $aChemistry, Organic.
650 0 $aPolymers.
650 0 $aOptical materials.
650 24 $aPolymer Sciences.
650 24 $aOptical and Electronic Materials.
650 24 $aSpectroscopy and Microscopy.
700 1 $aLi, Ling,$eeditor.
700 1 $aMeller, Gregor,$eeditor.
776 08 $iPrinted edition:$z9783642045370
830 0 $aAdvances in Polymer Science ;$v223.
988 $a20140628
906 $0VEN