Role of charge transfer and quinonoid structure in the Raman spectrum of doped poly(p-phenylene)

Cuff, Lilee; Cui, Can; Kertész, Miklós

doi:10.1021/ja00099a051

Cited by 38 publications

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“…These rates are presented as the slopes of the pressure dependence of the Raman frequencies in Table . The frequency increase effect of these BLA mode is correlated to the decrease of the bond length alternation in Figure a, indicating a direction of the structural transformation from aromatic to quinonoid …”

Section: Resultsmentioning

confidence: 80%

High‐Pressure Chemistry and the Mechanochemical Polymerization of [5]‐Cyclo‐p‐phenylene

Qiu

Peña-Álvarez²,

Taravillo³

et al. 2017

Chemistry A European J

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Evidence for the surprising formation of polymeric phases under high pressure for conjugated nanohoop molecules was found. This paper represents one of the unique cases, in which the molecular-level effects of pressure in crystalline organic solids is addressed, and provides a general approach based on vibrational Raman spectroscopy combining experiments and computations. In particular, we studied the structural and supramolecular chemistry of the cyclic conjugated nanohoop molecule [5]cyclo-para-phenylene ([5]CPP) under high pressures up to 10 GPa experimentally and up to 20 GPa computationally. The theoretical modeling for periodic crystals predicts good agreements with the experimentally obtained Raman spectra in the molecular phase. In addition, we have discovered two stable polymeric phases that arise in the simulation. The critical pressures in the simulation are too high, but the formation of polymeric phases at high pressures provides a natural explanation for the observed irreversibility of the Raman spectra upon pressure release between 6 and 7 GPa. The geometric parameters show a deformation toward quinonoid structures at high pressures accompanied by other deformations of the [5]CPP nanohoops. The quinonoidization of the benzene rings is linked to the systematic change of the bond length alternation as a function of the pressure, providing a qualitative interpretation of the observed spectral shifts of the molecular phase.

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Section: Resultsmentioning

confidence: 80%

High‐Pressure Chemistry and the Mechanochemical Polymerization of [5]‐Cyclo‐p‐phenylene

Qiu

Peña-Álvarez²,

Taravillo³

et al. 2017

Chemistry A European J

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“…Angewandte Zuschriften 7154 www.angewandte.de bands resemble that of G + band in armchair SWCNTs. [18] Such a correlation between Raman frequencies and aromatic-quinonoid character is further corroborated by the oxidation of [10]CPP to its radical cation ([10]CPPC + ; Figure 5), which unequivocally provokes ring quinoidization, and shows the main Raman band at 1569 cm À1 . [17] These modes derive from the 8a mode in benzene, which allows us to analyze the benzoquinonoid nature of such molecular structures.…”

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confidence: 68%

Properties of Sizeable [n]Cycloparaphenylenes as Molecular Models of Single‐Wall Carbon Nanotubes Elucidated by Raman Spectroscopy: Structural and Electron‐Transfer Responses under Mechanical Stress

et al. 2014

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“…For example, Ehrendorfer and Karpfen investigated positively charged bipolaronic defects in a series of oligothiophenes [24][25][26][27] and oligophenyls. 28 Kertesz et al 29 presented the structures and vibrational spectra of dications and dianions of terphenyl, and the structures of doubly positive charged closed-shell and open-shell defects in oligothiophenes were analyzed by Tol. 14,15 Common to these investigations on charged defects without counterions is the fact that bipolaronic defects extend over about six monomer units in the case of oligophenyls and by nine to eleven monomer units in the case of oligothiophenes, whereas polaronic defects were found to be less extended, with defect lengths of about three monomer units in oligothiophenes.…”

Section: Introductionmentioning

confidence: 99%

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

Irle

Lischka

1997

The Journal of Chemical Physics

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Articles you may be interested inLow-lying absorption and emission spectra of pyrene, 1,6-dithiapyrene, and tetrathiafulvalene: A comparison between ab initio and time-dependent density functional methods Model ab initio study of charge carrier solvation and large polaron formation on conjugated carbon chains Accurate ab initio density fitting for multiconfigurational self-consistent field methodsThe water exchange process of tetraaquaplatinum(II): Density-functional theory and ab initio computational study Ab initio self-consistent-field ͑SCF͒, two-configuration SCF ͑TCSCF͒, and density functional theory ͑DFT͒ calculations on the charge-transfer complexes of doubly Li/Cl-doped oligothiophenes and oligo͑p-phenyls͒ and on respective charged systems without counterions have been carried out in order to study polaron to bipolaron transitions. Oligomer chains up to octamers and the ring structures cyclo-dodecathiophene and cyclo-dodeca͑p-phenyl͒ have been investigated. Special attention is paid to the open-shell biradical character of two isolated polaronic defects. It is found that the TCSCF and the spin-unrestricted DFT methods can be successfully applied. A bipolaron structure is obtained when the doping atoms are located on neighboring rings and when there is one undoped ring separating the two doped ones. If there are two or more undoped rings in between a two-polaron configuration ͑biradical͒ is found. The bipolaron system is calculated to be more stable than the two-polaron case when counterions are taken into account. The stabilities are reversed if the bare, doubly-charged systems are considered. A theoretical estimate for the barrier height of the polaron to bipolaron transition is given using model reaction coordinates.

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Role of charge transfer and quinonoid structure in the Raman spectrum of doped poly(p-phenylene)

Cited by 38 publications

References 0 publications

High‐Pressure Chemistry and the Mechanochemical Polymerization of [5]‐Cyclo‐p‐phenylene

High‐Pressure Chemistry and the Mechanochemical Polymerization of [5]‐Cyclo‐p‐phenylene

Properties of Sizeable [n]Cycloparaphenylenes as Molecular Models of Single‐Wall Carbon Nanotubes Elucidated by Raman Spectroscopy: Structural and Electron‐Transfer Responses under Mechanical Stress

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

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