Conjugated conducting polymers |
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Page 108
An important question is the extent to which solitons or polarons can move from
one chain to another. Given their topological nature, individual solitons cannot
hop to adjacent chains, and joint hopping is a process with very small probability.
An important question is the extent to which solitons or polarons can move from
one chain to another. Given their topological nature, individual solitons cannot
hop to adjacent chains, and joint hopping is a process with very small probability.
Page 146
Since the inter-chain energy increases with separation of the charges in the
bipolaron, the maximum distance between the kink and antikink should be limited
to values below 50 lattice constants. These three-dimensional interactions cause
a ...
Since the inter-chain energy increases with separation of the charges in the
bipolaron, the maximum distance between the kink and antikink should be limited
to values below 50 lattice constants. These three-dimensional interactions cause
a ...
Page 154
Surprisingly, in highly oriented samples the photocurrent is larger if the exciting
light is polarized perpendicularly to the chain direction. This is an indication that
primarily carriers, being excited on different chains, give rise to photoconductivity.
Surprisingly, in highly oriented samples the photocurrent is larger if the exciting
light is polarized perpendicularly to the chain direction. This is an indication that
primarily carriers, being excited on different chains, give rise to photoconductivity.
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Contents
Introduction | 1 |
An Overview of the Theory of Conjugated Polymers | 7 |
References | 114 |
Copyright | |
6 other sections not shown
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Common terms and phrases
A.J. Heeger AsF5 atoms band band gap behaviour bipolarons bond alternation bond lengths calculations CH)x chain charged solitons Chem chemical shift coefficient conducting polymers configuration conjugated polymers correlation Coulomb interactions coupling Cryst decreases defects dependence dimerization discussed dopant dopant concentration doping doping levels e-e interactions effects electron spin electron-electron interactions electron-phonon ENDOR energy excitations exciton experimental finite polyenes frequency function Hamiltonian Hartree-Fock Heeger Hiickel hopping Hubbard model hyperfine interactions inter-chain kink lattice Lett linewidth magnetic Metals molecular neutral solitons nonlinear nuclear observed obtained one-dimensional optical absorption optical gap parameter peak Peierls Peierls-Hubbard model phonon Phys polarons polyacetylene polyenes polypyrrole polythiophene properties proton quantum quasi-particles Raman relaxation resonance Sect shown in Fig Solid State Commun soliton spectra spectrum spin density SSH model structure symmetry Synth temperature theoretical theory trans-(CH)x transition triplet valence bond values Vardeny
Bibliographic information
| Title | Conjugated conducting polymers Volume 102 of Springer series in solid-state sciences Volume 102 of Solid-State Sciences Series Volume 102 of Lecture Notes in Artificial Intelligence |
| Author | Helmut G. Kiess |
| Editors | Helmut G. Kiess, Dionys Baeriswyl |
| Contributors | Helmut G. Kiess, Dionys Baeriswyl |
| Edition | illustrated |
| Publisher | Springer-Verlag, 1992 |
| Original from | the University of Michigan |
| Digitized | 26 Nov 2007 |
| ISBN | 0387535942, 9780387535944 |
| Length | 310 pages |
| Subjects | › › Polymers Polymers - Electric properties Polymers - Optical properties Polymers/ Electric properties Polymers/ Optical properties Science / Chemistry / General Science / Magnetism Science / Physics Science / Solid State Physics Technology & Engineering / Textiles & Polymers |
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