1. Introduction
Conductive polymers (CP) belonging to the so-called “synthetic metal” are polymers with a conjugated carbon chain. They have electrical, electronic, magnetic and optical properties of metals, but retain the plastic properties of conventional polymers, facilitating their processing and further use. Their conductivity, when small amounts of dopants are introduced into the matrix of the original polyconjugated polymers with a typical conductivity of 10−10 to 10−5 Sm·sm−1, significantly increases, reaching the conductivity of semiconductors or even metals from 1 to 10−5 Sm·sm−1.
Doping is performed by chemical or electrochemical oxidation (p-doping) or reduction (n-doping) of the polymer. In this case, the polymer chains acquire, respectively, positive or negative charges, which are compensated by the formation of a polymer matrix of intermolecular complexes in the electrolyte solution with polyions of opposite sign. By adjusting the level of doping, it is possible to change the conductivity of the CP in a wide range.
The main task in the study of CP is to establish the nature and characteristics of charge carriers. As follows from the literature [
1,
2,
3], polarons and/or bipolarons with or without spin can be the charge carriers, ensuring the conductivity of CP. The unambiguous resolution of this task can significantly facilitate the development of new materials with improved properties based on CP for their use in molecular electronics.
Derivatives of polythiophene, including poly 3,4-ethylenedioxythiophene, are the most studied among CP. However, even for this polymer, there are conflicting opinions about the nature of charge carriers and its dependence on the length of the polymer chain.
3. Results and Discussion
For the electroneutral state of the E12 oligomer, the calculated C–C bond lengths between adjacent monomer units are 1.433 Å, which is typical of the benzenoid phase (see
Figure 1).
However, already at a low degree of doping, i.e., for the E12
1+ cation, the lengths of these bonds decrease monotonically from the ends of the chain to its center, reaching a minimum value of 1.417 Å at bond 6 (central), which is typical for the quinoid phase of the systems under study. For the E12
2+ bication, a similar dependence of the bond lengths between monomeric units is also observed. However, these bond lengths are still significantly smaller compared to similar bond lengths in the E12
1+ cation, which determines the increase in the contribution of the quinoid phase. For higher oxidation states (+3 and +4), on the corresponding curves of the dependence of the charge on the bond number between the intermonomer units, two minima appear in the bond regions 2 and 3, as well as 9 and 10, which indicates a further increase in the contribution of the quinoid phase and the formation at the ends of the oligomer chain of two separated polarons. Similar dependences were obtained for charged pyrrole oligomers [
4].
When a positive charge appears in the E12 oligomer, a polaron “hole” level appears in the gap between the energies of the upper occupied molecular orbital (HOMO) and the lower unoccupied molecular orbital (LUMO) of the E121+ cation, which is 0.46 eV away from the top of the valence band (
Figure 2).
Since, during the formation of the E12
1+ cation, an electron is removed from the HOMO level of the E12 oligomer, the level corresponding to the formation of a “hole” will lie above the HOMO level, as occurs when one electron is removed from a doubly occupied molecular orbital. For the neutral oligomer E12, the width of this gap is 2.06 eV (
Figure 3), which shows the dependence of E(LUMO)-E(HOMO) on the number of monomer units. Furthermore, in the text, the HOMO level will be identified by the top of the valence band, and the LUMO level by the bottom of the conduction band.
With a further increase in the degree of doping, two polaron hole levels appear in the E12
2+ bication, spaced from the top of the valence band and the bottom of the conduction band by 0.50 eV. There are three such levels in the E12
3+ cation, two of which lie at a distance of 0.8 eV from the top of the valence band, and one is 0.90 eV away from the bottom of the conduction band. For the E12
4+ cation, there are already four such hole levels that arise during the fourfold ionization of the E12 oligomer, which in pairs give rise to the formation of a polaron band in the energy gap between the HOMO and LUMO levels. The structure of the molecular orbital corresponding to the lowest level, which lies at a distance of 0.85 eV from the HOMO level (
Figure 4), clearly demonstrates the formation of two polarons at the ends of the E12 oligomer. With an appropriate interpretation, confirmation of the fact of the formation of two polarons can be obtained from the corresponding experimental data [
5,
6].
Figure 4 shows that the quinoid phase of the considered molecular orbital of the E12
4+ cation is localized at the ends of the chain in two regions, each of which captures four monomeric units. This indicates that the resulting vacancies, “holes”, are not delocalized over the entire oligomeric chain, which should be expected within the framework of the band theory of solids. Holes are localized in two four-link regions of the oligomeric chain of the E12
4+ cation; so, a bipolaron forms. The appearance of a bipolaron in E12
4+, as well as a polaron in the E12
1+ cation, causes structural deformation of the carbon chain of the oligomer (transition of the benzenoid phase to the quinoid phase). Two positive charges of a bipolaron, each with a charge of +2e, influence each other and behave like a pair. Both polarons and bipolarons, under the action of an electric field, are able to move along the polymer chain, leading to the reorganization of double and single bonds in the conjugated system (see
Figure 5).