Assignment and vibrational analysis of the 600 nm absorption band in the phenoxyl radical and some of its derivatives

Johnston, Linda J.; Mathivanan, N.; Negri, Fabrizia; Siebrand, Willem; Zerbetto, Francesco

doi:10.1139/v93-206

Cited by 45 publications

(34 citation statements)

References 25 publications

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“…The Equation‐of‐Motion (EOM) approach has been used to investigate a wide range of molecular properties (23–25) and has yielded very accurate excited‐state results for benzene (26, 27). CASSCF has been used in electronic structure calculations for a broad range of molecules (28, 29). The only difficulty associated with CASSCF calculations lies in the judicious choice of the active space.…”

Section: Methodsmentioning

confidence: 99%

Ultraviolet Absorption Spectra of Substituted Phenols: A Computational Study†

Zhang

Peslherbe

Muchall

2006

Photochem Photobiol

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Vertical excitation energies for electronic transitions from the ground state to the first two excited states of phenol, mono- and disubstituted methoxyphenols and methyl-substituted phenols have been characterized with the Time-Dependent Density Functional Theory (TD-DFT), the Complete Active Space Self-Consistent Field method (CASSCF) and the Coupled Cluster with Single and Double Excitations Equation-of-Motion approach (CCSD-EOM) to simulate and interpret experimental ultraviolet absorption spectra. While CASSCF excitation energies for the first two transitions either are grossly overestimated or exhibit a weak correlation with experimental data, both TD-DFT and CCSD-EOM perform very well, reproducing the spectral shifts of both the primary band and secondary band observed upon substitution. The conformational dependence of the calculated excitation energies is generally smaller than the shifts caused by substitution.

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Section: Methodsmentioning

confidence: 99%

Ultraviolet Absorption Spectra of Substituted Phenols: A Computational Study†

Zhang

Peslherbe

Muchall

2006

Photochem Photobiol

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“…Although they are the most fundamental benzene derivative radicals, the thiophenoxy (Araki et al 2014b), phenoxy, and methylphenoxy radicals were not able to explain DIBs. second excited state were calculated by Johnston et al (1993), the energy levels of the ground and excited states in their calculations were inverted compared with those in currently accepted energy level structures. Thus, we recalculated the frequencies of the B A 2 2 second excited state using TD-B3LYP/cc-pVTZ.…”

Section: Discussionmentioning

confidence: 99%

“…The electronically excited states of A B , and E B 2 1 have been characterized with absorption bands in the regions from 1140 nm to 1310 nm (Gunion et al 1992;Radziszewski et al 2001;Cheng et al 2008), 510 nm to 640 nm (Ward 1968;Pullin & Andrews 1982;Kesper et al 1991;Johnston et al 1993;Yu et al 1995;Radziszewski et al 2001;SpangetLarsen et al 2001), 370 nm to 400 nm (Porter & Wright 1955;Pullin & Andrews 1982;Kesper et al 1991;Radziszewski et al 2001;Spanget-Larsen et al 2001;Tonokura et al 2004), 270 nm to 300 nm (Porter & Wright 1955;Ward 1968;Kajii et al 1987;Berho & Lesclaux 1997;Platz et al 1998;Radziszewski et al 2001;Spanget-Larsen et al 2001;Bayrakceken et al 2003), and 220 nm to 250 nm (Kajii et al 1987;Berho & Lesclaux 1997;Platz et al 1998;Radziszewski et al 2001), respectively, where the z-axis isalong the C-O bond and the x-axis is perpendicular to the plane. Only the A B X B transitions show resolved vibrational structures (Johnston et al 1993;Radziszewski et al 2001;Spanget-Larsen et al 2001;Cheng et al 2008 transition. To compare this transition with DIBs, gas-phase, high-resolution observation of the transition is essential.…”

Section: Introductionmentioning

confidence: 99%

Laboratory Optical Spectroscopy of the Phenoxy Radical as a Candidate for Diffuse Interstellar Bands

Araki

Matsushita

Tsukiyama

2015

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The gas-phase optical absorption spectrum of the B A X B 2 2 2 1¬transition of a phenoxy radical (C 6 H 5 O), which is a candidate molecule of diffuse interstellar bands (DIBs), was observed in the discharge of anisole using a cavity ring-down spectrometer. The spectrum comprised four peaks having broad and asymmetric profiles, which were regarded as a vibrational progression of ∼500 cm −1 . The progression was assigned to the 6a mode, and the broad and asymmetric profiles of the peaks accounted for the sequence of the 10b mode. Each component in both the progression and the sequence had a broad structure of 20-30 Å, which can be explained by a convolution of lifetime broadening and a rotational profile. Based on these assignments of the progression and the sequence, the vibronic transitions from v = 0 in the X B excited state were extracted to compare the laboratory bands with DIBs. Although the transitions did not agree with the observed DIBs, the upper limit of the column density for the phenoxy radical in the diffuse clouds toward HD 204827 was evaluated to be 7 × 10 14 cm −2 .

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“…The phenoxy (naphthoxy) radicals characteristically have three absorption bands (Johnston et al, 1993;Steenken and Neta, 2003): an intense band between 300-400 nm (depending on the parent molecule) a weaker and often structured band in the 350-420 nm range (e max E4000 mol À 1 dm 3 cm À 1 ; Roder et al, 1999) and a weak, ill-defined wide band in the 500-700 nm range. Such radicals generally decay in slow second order reactions (as observed here).…”

Section: Reactions Of Ho D Radicalmentioning

confidence: 99%