Key Role of End-Capping Groups in Optoelectronic Properties of Poly-<i>p</i>-phenylene Cation Radicals

Talipov, Marat R.; Boddeda, Anitha; Timerghazin, Qadir K.; Rathore, Rajendra

doi:10.1021/jp5082752

Cited by 66 publications

(142 citation statements)

References 41 publications

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“…For this purpose, we utilized the B1LYP-40 functional [i.e. B1LYP-40/6-31G(d)+PCM(CH 2 Cl 2 )] 19,20 because our recent careful benchmarking studies on a number of polyaromatic systems 17,20–22 showed that this functional allows an accurate description of the spin/charge (hole) distribution in their cation radicals, and, in turn, the prediction of the corresponding redox/optical properties ( E ox1 , ν D0→D1 ) with high fidelity to experimental data. The excellent performance of the B1LYP-40 functional owes to the fact that 40% contribution of the exact (i.e.…”

Section: Resultsmentioning

confidence: 99%

A search for blues brothers: X-ray crystallographic/spectroscopic characterization of the tetraarylbenzidine cation radical as a product of aging of solid magic blue

et al. 2016

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Magic blue (MB+• SbCl6− salt), i.e. tris-4-bromophenylamminium cation radical, is a routinely employed one-electron oxidant that slowly decomposes in solid state upon storage to form so called ‘blues brothers’, which often complicate the quantitative analyses of the oxidation processes. Herein, we disclose the identity of main ‘blues brother’ as the cation radical and dication of tetrakis-(4-bromophenyl)benzidine (TAB) by a combined DFT and experimental approach, including isolation of TAB+• SbCl6− and its X-ray crystallography characterization. The formation of TAB in aged magic blue samples occurs by a Scholl-type coupling of a pair of MB followed by a loss of molecular bromine. This recognition led us to rational design and synthesis of tris(2-bromo-4-tert-butylphenyl)amine, referred to as ‘blues cousin’, (BC: Eox1 = 0.78 V vs Fc/Fc+, λmax(BC+•) = 805 nm, εmax = 9930 cm−1 M−1), whose oxidative dimerization is significantly hampered by positioning the sterically demanding tert-butyl groups at the para-positions of aryl rings. A ready two-step synthesis of BC from triphenylamine and the high stability of its cation radical (BC+•) promises that BC will serve as a ready replacement for MB and oxidant of choice for mechanistic investigations of one-electron transfer processes in organic, inorganic, and organometallic transformations.

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Section: Resultsmentioning

confidence: 99%

A search for blues brothers: X-ray crystallographic/spectroscopic characterization of the tetraarylbenzidine cation radical as a product of aging of solid magic blue

et al. 2016

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“…The equilibrium concentrations of the species in eqs (8) and (9) can be determined from the equations of chemical equilibria and equations of mass and charge balance (eqs (11)(12)(13)(14)(15)) combined into a cubic equation of one variable (eq. (16)) in terms of oxidant concentration [Ox +• ], which can be solved either analytically or numerically.…”

Section: Resultsmentioning

confidence: 99%

“…[4][5][6][7][8][9][10][11][12] Importantly, such redox titrations allow one to quickly ascertain not only the optical properties of D +• and D 2+ but may also provide the estimates of redox potentials without the need of a complex electrochemical setup. It is noteworthy that characterizations of redox centers in proteins involved in biochemical transformations invariably make use of redox titrations in water-containing ample electrolyte.…”

Section: +mentioning

confidence: 99%

Quantitative generation of cation radicals and dications using aromatic oxidants: effect of added electrolyte on the redox potentials of aromatic electron donors

Talipov

Boddeda

Hossain

et al. 2015

J of Physical Organic Chem

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Redox titrations using robust aromatic oxidants allow for a quantitative analysis of redox and optical properties of organic electron donors in their oxidized states. Unlike spectroelectrochemistry, redox titrations can be performed without added electrolyte in relatively nonpolar solvents, affording quick access to the redox and optical properties of a given electron donor without the need of a complex electrochemical setup. However, the redox potentials obtained by the two methods are not the same. To establish the direction and magnitude of this discrepancy, we have performed a systematic case study using a set of tetraarylethylene donors and a tetrasubstituted hydroquinone ether cation radical () as a stable aromatic oxidant. We show that redox potentials (especially second and higher oxidation potentials) measured by electrochemical methods are systematically lower compared with the redox potentials obtained by redox titrations in the absence of electrolyte, because of the enhanced stabilization of dications and polycations by electrolyte. We have also uncovered that the smaller cation radicals (e.g., a para-hydroquinone or ortho-hydroquinone ether cation radicals) are much more effectively stabilized when compared with the cation radicals in which charge is delocalized over larger area (e.g., tetraarylethylene cation radicals) in the presence of electrolyte because of increased ionic strength of the solution.

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“…Thus, in polymer solutions a distribution of conformers might be present, which may influence the fast dynamical electronic processes that occur in optoelectronic devices such as exciton diffusion or charge migration. [11][12][13][14][15][16][17][18][19][20][21] For this reason it is extremely difficult to gain insight into the relation of electronic processes in conjugated polymers and their microscopic or superstructure in solution and in the solid state. 22 Recently Scholes et al addressed this issue very elegantly by investigating MEH-PPV in its stretched form in CHCl 3 solution in comparison to its coiled nanoparticle form in aqueous solution.…”

Section: Introductionmentioning

confidence: 99%

Energy Transfer Between Squaraine Polymer Sections: From Helix to Zigzag and All the Way Back

et al. 2015

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We provide a joint experimental and theoretical study of squaraine polymers in solution. The absorption spectra show evidence that two different conformations are present in the polymer: a helix and a zigzag structure. This unique situation allows investigating ultrafast energy-transfer processes between different structural segments within a single polymer chain in solution. The understanding of the underlying dynamics is of fundamental importance for the development of novel materials for light-harvesting and optoelectronic applications. Here, we combine femtosecond transient absorption spectroscopy with time-resolved 2D electronic spectroscopy in order to demonstrate that ultrafast energy transfer within the squaraine polymer chains proceeds from initially excited helix segments to zigzag segments or vice versa, depending on the solvent as well as on the excitation wavenumber. These observations contrast other conjugated polymers such as MEH-PPV where much slower intrachain energy transfer was reported. The reason for the very fast energy transfer in squaraine polymers is most likely a close matching of the density of states between donor and acceptor polymer segments because of the very small reorganization energy in these cyanine-like chromophores.

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Key Role of End-Capping Groups in Optoelectronic Properties of Poly-p-phenylene Cation Radicals

Cited by 66 publications

References 41 publications

A search for blues brothers: X-ray crystallographic/spectroscopic characterization of the tetraarylbenzidine cation radical as a product of aging of solid magic blue

A search for blues brothers: X-ray crystallographic/spectroscopic characterization of the tetraarylbenzidine cation radical as a product of aging of solid magic blue

Quantitative generation of cation radicals and dications using aromatic oxidants: effect of added electrolyte on the redox potentials of aromatic electron donors

Energy Transfer Between Squaraine Polymer Sections: From Helix to Zigzag and All the Way Back

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