Localized and extended states in doped polyaniline: The effect of bond-length alternation

Dücker, H.; Struck, Michael; Koslowski, Th.; Niessen, W. von

doi:10.1103/physrevb.46.13078

Cited by 15 publications

(7 citation statements)

References 25 publications

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“…Parts (a-1) and (a-2) refer to the ordered lattice where protonation is randomly distributed in 25% and 100%, respectively, of the imine nitrogens. In parts (b-1) and (b-2) the same concentrations of protonated imine nitrogens are distributed over a completely disordered bipolaronic lattice rings [16][17][18] (we do not consider here any other kind of disorder such as ring torsion or bond length disorder). A distinctive sign of disorder is the fragmentation of the electronic spectrum, a broadening of the density of states and the presence of states in energy regions otherwise forbidden to the electron in the corresponding ordered system.…”

Section: Effect Of Disorder On the Electronic Statesmentioning

confidence: 99%

“…Existing tight-binding (TB) parameterizations of polyanilines are often deduced from Streitweiser [15] with some slight modification [16][17][18], and are used as ingredients of TB Hamiltonians even if the overall band structure generated from them has poor agreement with the band structures obtained from more sophisticated methods; other parameterizations in the literature [19], also introduced in a renormalization approach [20,21], have allowed a better reproduction of the band structures (at least in the energy region around the fundamental gap). Other studies [22,23] have proposed simplified model cells which somehow summarize the content of the true polymer cell; the scope is to use them for the evaluation of the transport properties of the polymeric structure, even if this use has to be taken with caution due to the high sensitivity of the band structures and the densities of states to the parameterization of the original polymeric Hamiltonian.…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Tight-Binding Effective Hamiltonians for the Electronic States of Polyaniline Chains

Vignolo

Farchioni

Grosso

2001

phys. stat. sol. (b)

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By means of strictly one-dimensional effective Hamiltonians, in the tight-binding scheme, we obtain band structures and densities of states of the main forms of polyanilines, which compare favourably with existing theoretical and experimental studies. We first consider the band structures of the three polymeric base forms: leucoemeraldine, emeraldine and pernigraniline; then we study the pernigraniline salt and the emeraldine salt in the polaronic and bipolaronic configurations. The 1D p-electron effective Hamiltonians are obtained exploiting a modified version of the recursion method and successively the application of the renormalization method. The procedure here outlined can be adopted for any polymeric chain; it is so flexible to embody known relevant structural and optical properties of the polymer, moreover it provides a useful tool for successive iterative calculations in the study of the electronic transport properties of the polymer also in the presence of disorder.

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Section: Effect Of Disorder On the Electronic Statesmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Tight-Binding Effective Hamiltonians for the Electronic States of Polyaniline Chains

Vignolo

Farchioni

Grosso

2001

phys. stat. sol. (b)

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“…A great impulse to the solution of the problem has been given by introducing the alternative idea to consider as decisive the role of the disorder due to the random distribution of quinoid and benzoid rings in the chain. [8][9][10][11] In this approach the system has been generally studied in the frame of the Hückel theory, by assigning to the atoms appropriate site energies and hopping interactions according to the type of bonds. To expect electronic transport in a system dominated by disorder may appear surprising; however, this hypothesis is corroborated by the fact that in certain systems with correlated disorder, or in the presence of internal symmetries of the defects, a part of the eigenstates of the spectrum tends to be delocalized, determining an increase of the conductivity of the system; the simplest form of correlated disorder which is worth mentioning for its consequences on the study of conducting polymers, is the random dimer model; [12][13][14][15] it has been deeply studied in the case of binary lattice, but also in more general situations.…”

Section: Introductionmentioning

confidence: 99%

Renormalization approach for transport and electronic properties of conducting polymers

1996

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By means of the renormalization approach, we have developed a map that allows us to investigate transport and electronic properties in polyaniline chains in terms of an effective lattice. This lattice may contain impurities of two kinds: the first has the form of a couple of sites (dimer) with the same or different site energies according to the symmetry of the rings of the polymer it simulates; the other can occur without constraint in the number of sites involved. In the case of more sophisticated descriptions of the polymer, the dimer model can be inadequate and impurities of four sites have to be introduced in the map. We compare the results for the scattering properties of a single impurity with those of a finite sample of the chain, and we show the dependence of the results on the energies assigned to the carbon and nitrogen atoms of the polymer

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“…In fact, it is very tempting to relate all this to the known fact that polyaniline shows a metal-insulator transition, with the concentration of dopant acting as a control parameter (see Ref. 38 and references therein). Another important consequence of this work is that other experimental procedures we have proposed to find out whether delocalization can be measured or not, such as disordered superlattices, 17 are likely to be correct even if 3D effects have not been taken into account.…”

Section: Discussionmentioning

confidence: 99%

Three-dimensional effects on extended states in disordered models of polymers

1995

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We study electronic transport properties of disordered polymers in a quasi-one-dimensional model with fully three-dimensional interaction potentials. We consider such quasi-one-dimensionallattices in the presence of both uncorrelated and short-range correlated impurities. In our procedure, the actual physical potential acting upon the electrons is replaced by a set of nonlocal separable potentials, leading to a Schrodinger equation that is exactly solvable in the momentum representation. By choosing an appropriate potential with the same spectral structure as the physical one, we obtain a discrete set of algebraic equations that can be mapped onto a tight-binding-like equation. We then show that the reflection coefficient of a pair of impurities placed at neighboring sites (dimer defect) vanishes for a particular resonant energy. When there is a finite number of such defects randomly distributed over the whole lattice, we find that the transmission coefficient is almost unity for states close to the resonant energy, and that those states present a very large localization length. Multifractal analysis techniques applied to very long systems demonstrate that these states are truly extended in the thermodynamic limit. These results are obtained with parameters taken from actual physical systems such as polyacetylene, and thus reinforce the possibility of verifying experimentally theoretical predictions about the absence of localization in quasi-one-dimensional disordered systems.

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Localized and extended states in doped polyaniline: The effect of bond-length alternation

Cited by 15 publications

References 25 publications

Tight-Binding Effective Hamiltonians for the Electronic States of Polyaniline Chains

Tight-Binding Effective Hamiltonians for the Electronic States of Polyaniline Chains

Renormalization approach for transport and electronic properties of conducting polymers

Three-dimensional effects on extended states in disordered models of polymers

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