The benzene ground state potential surface. I. Fundamental frequencies for the planar vibrations

Thakur, Surya N.; Goodman, Lionel; Ozkabak, Ali G.

doi:10.1063/1.450717

Cited by 94 publications

(30 citation statements)

References 35 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Calculations were carried out not only on the three fundamental frequencies ν 18 , ν 19 , ν 20 but also on higher E 1 u CH stretch overtone energies CH(v), at v ≤ 6, as functions of the values of the relevant harmonic force constants in benzene C 6 H 6 . The calculated vibrational energies are compared to existing experimentally measured data 13–21. The determined values of the force constants, by adjustment of the calculated to the experimentally measured vibrational energies, are displayed in Table V, together with the previously empirically determined values by Goodman et al 13 for comparison.…”

Section: Calculations Of Vibrational Frequencies and Determination Ofmentioning

confidence: 96%

“…In our recent work 12, we studied the vibrational level structure inherent to the A 1 g block of benzene vibrations (ν 1 , ν 2 in Wilson's notation). From comparison of the ν 1 , ν 2 fundamental frequencies for four D 6 h benzene isotopomers ( C 6 H 6 , C 6 D 6 , 13 C 6 H 6 , and 13 C 6 D 6 ), calculated as functions of the relevant force constants parameters, to experimentally measured values 13–16, we have been able to determine highly accurate values for the force constants F 1,1 , F 2,2 , and F 1,2 . It must be pointed out that these calculations reproduced almost perfectly the ν 1 , ν 2 fundamental frequencies for all four benzene isotopomers 9.…”

Section: Calculations Of Vibrational Frequencies and Determination Ofmentioning

confidence: 98%

See 1 more Smart Citation

Complex symmeterized analysis of benzene vibrations

Rashev¹

2002

Int J of Quantum Chemistry

View full text Add to dashboard Cite

ABSTRACT:The aim of this work is to introduce specific complex coordinates and wave functions (Hamiltonian eigenfunctions) for the description of vibrational motion in benzene. When suitably chosen, these complex functions are shown to possess interesting transformation behavior under the symmetry operations of the molecular symmetrical top point group D 6 . This behavior is analyzed and classified as "complex symmetry types" (CSTs). CSTs can be defined for all symmetrical top point groups. The description in terms of complex symmeterized coordinates and wave functions allows for the construction of a separable symmeterized vibrational basis set for benzene. New results from calculations on vibrational energies and redeterminations of harmonic force constants in benzene, obtained using the CST description, are presented.

show abstract

Section: Calculations Of Vibrational Frequencies and Determination Ofmentioning

confidence: 96%

Section: Calculations Of Vibrational Frequencies and Determination Ofmentioning

confidence: 98%

Complex symmeterized analysis of benzene vibrations

Rashev¹

2002

Int J of Quantum Chemistry

View full text Add to dashboard Cite

show abstract

“…Figure 1 shows the definition of the axis system used for monosubstituted benzene derivatives following the Mulliken convention [31,35]. This convention is most commonly used for electronic spectra of benzene derivatives, but differs from the one often used in infrared spectroscopy [29,36] and also the one used in [32]. In the two conventions the species B 1 and B 2 need to be interchanged.…”

Section: Methodsmentioning

confidence: 99%

Sub-Doppler supersonic jet spectra of the coupled 6a¹₀and 6b¹₀vibronic bands of the S₁(¹B_2u) ← S₀(¹A_1g) transition in monodeuterobenzene and their rovibrational analysis

et al. 1994

View full text Add to dashboard Cite

We report the rotationally resolved spectra of C6HsD obtained in a supersonic seeded jet by Doppler free UV laser spectroscop~ with an effective resolution of about ff0045 cm -1. The coupled 6a~ and 6b0 vibronic transitions are analysed in terms of their spectroscopic constants (~0 = 38 634.2429 cm -~ for 1 1 1 6a0 and u0 =38637.1792cm-for 6b0) and the Coriolis coupling constant (~ = 0"095 85cm -1, obtained by constraining the C rotational constants to be equal for 6a 1 and 6b 1. Simulations of the spectra result in rotational temperatures of about 2 K. The polarizations of the two transitions could be determined unambiguously as well as the approximate ratio of the transition moments.

show abstract

“…deuterated, C6HnD6-n) benzene molecules, which have predictably perturbed normal modes and frequencies, has also been exhaustively performed. 4,13 This has added greatly to the spectroscopic data base useful in refining force constants. High-resolution techniques have been used to measure the 3 detailed rotational structure of some vibrational bands: IR absorption14-16 and Raman17-19 studies have given accurate values of moments of inertia and vibration-rotation interaction constants.…”

mentioning

confidence: 99%

Infrared–ultraviolet double resonance studies of benzene molecules in a supersonic beam

Page¹,

Shen²,

Lee³

1988

The Journal of Chemical Physics

204

114

View full text Add to dashboard Cite

We have used IR excitation to selectively create populations in admixtures of the zeroth-order states comprising the ∼3000 cm−1 ‘‘C–H stretching Fermi triad’’ of benzene. UV spectra of the 260 nm Ã(1B2u)←X̃(1A1g) transition in the IR-excited molecules show several new bands, which we have assigned. Final states in the UV transitions are some vibrational levels which have not been detected before, allowing us to find several excited-state vibrational frequencies. We have determined ν′3 =1327±3 cm−1, ν19 =1405±3 cm−1, and ν′20 =3084±5 cm−1. Also, vibrational structure which was unresolved in IR spectra of the ‘‘Fermi triad’’ was resolved in the UV double resonance spectra, confirming that the C–H stretching admixture is really a tetrad. The 3048, 3079, and 3101 cm−1 states had formerly been given the labels ν″20, ν″8+ν″19, and ν″1+ν″6+ν″19, respectively. Actually, the middle level most nearly resembles ν″1+ν″6+ν″19, and the 3101 cm−1 level is strongly mixed with ν″3+ν″6+ν″15. As predicted by molecular orbital theory, excited-state C–H bending and stretching frequencies are not very different from those in the ground state. Furthermore, we suggest that the four C–H stretching frequencies increase uniformly by ∼20 cm−1 in the excited state; reexamination of the Atkinson and Parmenter 260 nm Ã←X̃ spectrum leads us to reassign ν2 from 3130 to ∼3093 cm−1, which is 19 cm−1 above ν″2. There is a Fermi resonance between the ν6+ν′20 level and another level ∼13 cm−1 lower in energy; the strength of the perturbation is ∼18 cm−1. Possibilities for the perturbing vibrational state are ν6+ν′8+ν14 and ν′6+ν13.

show abstract

The benzene ground state potential surface. I. Fundamental frequencies for the planar vibrations

Cited by 94 publications

References 35 publications

Complex symmeterized analysis of benzene vibrations

Complex symmeterized analysis of benzene vibrations

Sub-Doppler supersonic jet spectra of the coupled 6a¹₀and 6b¹₀vibronic bands of the S₁(¹B_2u) ← S₀(¹A_1g) transition in monodeuterobenzene and their rovibrational analysis

Infrared–ultraviolet double resonance studies of benzene molecules in a supersonic beam

Contact Info

Product

Resources

About

The benzene ground state potential surface. I. Fundamental frequencies for the planar vibrations

Cited by 94 publications

References 35 publications

Complex symmeterized analysis of benzene vibrations

Complex symmeterized analysis of benzene vibrations

Sub-Doppler supersonic jet spectra of the coupled 6a10and 6b10vibronic bands of the S1(1B2u) ← S0(1A1g) transition in monodeuterobenzene and their rovibrational analysis

Infrared–ultraviolet double resonance studies of benzene molecules in a supersonic beam

Contact Info

Product

Resources

About

Sub-Doppler supersonic jet spectra of the coupled 6a¹₀and 6b¹₀vibronic bands of the S₁(¹B_2u) ← S₀(¹A_1g) transition in monodeuterobenzene and their rovibrational analysis