Combined <i>ab initio</i> and density functional study on polaron to bipolaron transitions in oligophenyls and oligothiophenes

Irle, Stephan; Lischka, Hans

doi:10.1063/1.474701

Cited by 53 publications

(32 citation statements)

References 42 publications

(64 reference statements)

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“…We might actually expect the relative stability of one bipolaron versus two polarons to result from a fine balance depending intimately on the experimental conditions, such as solvent and type of counterions. [64] Experimental Section…”

Section: Resultsmentioning

confidence: 99%

Redox States of Long Oligothiophenes: Two Polarons on a Single Chain

Haare

Havinga

Dongen

et al. 1998

Chemistry A European J

260

308

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A detailed investigation is presented of the redox states of three oligothiophenes (nT) with 6, 9, and 12 thiophene units. While open-shell radical cations (polarons) and closed-shell dications (bipolarons) are usually invoked as the primary redox species in these systems, we have obtained evidence that the dication of the longest oligothiophene (12T) has an electronic structure with two individual polarons. The redox states of 6T, 9T, and 12T have been fully characterized using UV/visible/near-IR and ESR spectroscopy in combination with electrospray mass spectrometry. For 6T and 9T, singleelectron oxidation in dichloromethane produces the corresponding radical cations, which form spinless p dimers at lower temperatures. A second oxidation step forms dications which possess a bipolaronic electronic structure. However, the redox behavior of the longest oligothiophene, 12T, is entirely different. Radical cations of 12T disproportionate into neutral oligomers and dications, except at the lowest oxidation levels. The spectral data for doubly oxidized 12T are incompatible with those expected for a bipolaronic structure but are consistent with the formation of two individual polarons on a single chain; this interpretation is also supported by the results from correlated quantum chemical calculations.

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Section: Resultsmentioning

confidence: 99%

Redox States of Long Oligothiophenes: Two Polarons on a Single Chain

Haare

Havinga

Dongen

et al. 1998

Chemistry A European J

260

308

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“…Since quantum chemical calculations for oligophenyls 44 show that polarons which are separated by a distance of one phenyl ring can already by treated as uncorrelated, we assume that the magnetic resonance enhancement of both nongeminate and geminate recombination works in a similar way. In order to recombine, the polarons must form a correlated pair, with sufficient spin polarization so that at the field for resonance one can sufficiently enhance the recombination of the pairs and, hence, decrease the total polaron population.…”

Section: Magnetic Resonance Experimentsmentioning

confidence: 99%

Interaction of singlet excitons with polarons in wide band-gap organic semiconductors: A quantitative study

et al. 2001

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The steady-state photoinduced absorption ͑PA͒, photoluminescence ͑PL͒, PL-detected magnetic resonance ͑PLDMR͒, and PA-detected magnetic resonance ͑PADMR͒ of poly-and oligo-͑para-phenylenes͒ films is described. In particular, the excitation density ͑laser power͒ N 0 dependence of the PA, PL, and PLDMR signals is analyzed by means of a rate equation model, which describes the dynamics of singlet excitons ͑SE's͒ and polarons in all three experiments quantitatively with the same set of parameters. The model is based on the observations that mobile SE's are quenched by trapped and free polarons and that the spin-1 2 magnetic resonance conditions reduce the total polaron population. Since the sublinear N 0 dependences of the positive ͑PL-enhancing͒ spin-1 2 PLDMR and the polaron PA band are essentially the same, we conclude that PLDMR is due to a reduced quenching of SE's by polarons. The agreement between the model, the current results, and results from other spectroscopic techniques provides strong evidence for this quenching mechanism. This also suggests that it is a very significant process in luminescent -conjugated materials and organic light-emitting devices. Consequently, the quenching mechanism needs to be taken into account, especially at high excitation densities, which is of great importance for the development of electrically pumped polymer laser diode structures.

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“…The gradual manner in which the Fermi energy shifts as a function of intercalation level also provides some evidence of a transition from a polaronic to a bipolaronic state. 13,44,45 Lischka and co-workers 19,20,46,47 have theoretically analyzed the position of intercalated lithium atoms with respect to the molecules within isolated Li-BP complexes. According to their calculations, a single lithium atom interacts through a cation-binding configuration, where the Li counterion is approximately equidistant from the carbon atoms in one of the BP rings and positioned almost directly above the center of that ring.…”

Section: Biphenyl and Bipyridine Derivativesmentioning

confidence: 99%

Electronic structure of Li-intercalated oligopyridines: A comparative study by photoelectron spectroscopy

Doherty

Friedlein

Renouard

et al. 2007

The Journal of Chemical Physics

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The role of nitrogen in the charge transfer and storage capacity of lithium-intercalated heterocyclic oligophenylenes was investigated using photoelectron spectroscopy. The development of new occupied states at low binding energies in the valence band region, as well as core level chemical shifts at both carbon and nitrogen sites, demonstrates partial charge transfer from lithium atoms to the organic component during formation of the intercalated compound. In small compounds, i.e., biphenyl and bipyridine derivatives, the position of the nitrogen heteroatom significantly affects the spacing between gap states in the Li-intercalated film; yet it has minimal effects on the charge storage capacity. In larger, branched systems, the presence of nitrogen in the aromatic system significantly enhances the charge storage capacity while the Li-N bond strength at high intercalation levels is significantly weakened relative to the nitrogen-free derivative. These observations have strong implications towards improved deintercalation processes in organic electrodes in lithium-ion batteries.

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Combined ab initio and density functional study on polaron to bipolaron transitions in oligophenyls and oligothiophenes

Cited by 53 publications

References 42 publications

Redox States of Long Oligothiophenes: Two Polarons on a Single Chain

Redox States of Long Oligothiophenes: Two Polarons on a Single Chain

Interaction of singlet excitons with polarons in wide band-gap organic semiconductors: A quantitative study

Electronic structure of Li-intercalated oligopyridines: A comparative study by photoelectron spectroscopy

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