The vacuum UV photoabsorption spectrum of methyl chloride (CH3Cl) and its perdeuterated isotopomer CD3Cl I. A Rydberg series analysis

Locht, Robert; Leyh, Bernard; Jochims, H.‐W.; Baumgärtel, H.

doi:10.1016/s0301-0104(01)00464-5

Cited by 31 publications

(37 citation statements)

References 28 publications

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“…Figure 2 shows the absolute photoabsorption cross section, the photoion-pair quantum efficiency and the absolute photoion-pair cross section of CH 3 Cl. The overall appearance of the photoabsorption spectrum is similar to those reported in previous studies using photon [9,[14][15][16][17][18] and high-energy electron impact [19] methods. However, the absolute values are at least a factor of 2 larger than those obtained in the most recent photoabsorption study [15,16], although in excellent agreement with the results of Lee and Suto [9] and Olney et al [19].…”

Section: Chloromethanesupporting

confidence: 85%

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Ion-pair formation mechanisms in chloromethane, bromomethane and dichlorodifluoromethane

Shaw

Holland

Walker

2006

J. Phys. B: At. Mol. Opt. Phys.

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The first absolute photoion-pair cross sections have been derived from measurements of the absolute photoabsorption cross section and the photoionpair quantum efficiency. The results for CH 3 Cl, CH 3 Br and CF 2 Cl 2 show that direct transitions into ion-pair states play a significant role. In each molecule, the structure in the photoion-pair spectrum is different to that in the photoabsorption spectrum and often does not resemble the strong bands, due to Rydberg transitions, prominent in the latter spectra. At photon energies associated with excitations into Rydberg states, and consequently with peaks in absorption, the photoion-pair quantum efficiency usually exhibits a local minimum. This indicates that the Rydberg state decays preferentially by predissociation into a state yielding neutral fragments rather than by predissociation into a state evolving into ion pairs.

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Section: Chloromethanesupporting

confidence: 85%

“…Only the principal features are labelled in figure 2(a). The accompanying vibrational excitations, which are responsible for the weaker structure, have been discussed by Locht et al [17,18].…”

Section: Chloromethanementioning

confidence: 92%

Ion-pair formation mechanisms in chloromethane, bromomethane and dichlorodifluoromethane

Shaw

Holland

Walker

2006

J. Phys. B: At. Mol. Opt. Phys.

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“…Similar calculation have been published in the literatures. [27][28][29] From Fig. 1 and Table I, it is clear that almost all bond lengths and bond angles are changed upon ionization, and the main changes are in the bond angles of H-C-Cl.…”

Section: Fig 1 the Minimum Energy Geometrical Structures For Ch 3 Cl(xmentioning

confidence: 98%

“…The neutral CH 3 Cl has C 3v geometrical structure, and its molecular orbitals can be represented as 27,28 (Core) (5a 1 ) 2 (6a 1 ) 2 (1e) 4…”

Section: B Calculation For Pes and Vibronic Parametersmentioning

confidence: 99%

“…27 The resolution of the spectra was similar to that of Karlsson et al 19 The vibrational structures of the Rydberg states of CH 3 Cl have been also studied using vacuum ultraviolet (VUV) absorption method. 28,29 Because the vibrational structure of the ionic core for the high Rydberg molecule approaches the cation, this kind of researches should be helpful to understand the electronic structure of CH 3 Cl + . The IR absorption spectra of CH 3 Cl + isolated on the solid neon have been measured, which recorded four vibrational bands.…”

Section: Introductionmentioning

confidence: 99%

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The Jahn-Teller effect in ${\rm CH}_{\rm 3} {\rm Cl}^{\rm + } ( {{\rm \tilde X}{}^{\rm 2}{\rm E}} )$ CH 3 Cl +(X̃E2): A combined high-resolution experimental measurement and ab initio theoretical study

Shao

Zhang

et al. 2012

The Journal of Chemical Physics

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The energy levels of CH(3)Cl(+)X̃(2)E showing strong spin-vibronic coupling effect (Jahn-Teller effect) have been measured up to 3500 cm(-1) above the ground vibrational state using one-photon zero-kinetic energy photoelectron and mass-analyzed threshold ionization spectroscopic method. Theoretical calculations have been also performed to calculate the spin-vibronic energy levels using a diabatic model and ab initio adiabatic potential energy surfaces (PESs). In the theoretical calculations the diabatic potential energy surfaces are expanded by the Taylor expansions up to the fourth-order including the multimode vibronic interactions. The calculated spin-orbit energy splitting (224.6 cm(-1)) for the ground vibrational state is in good agreement with the experimental data (219 ± 3 cm(-1)), which indicates that the Jahn-Teller and the spin-orbit coupling have been properly described in the theoretical model near the zero-point energy level. Based on the assignments predicted by the theoretical calculations, the experimentally measured energy levels were fitted to those from the diabatic model by optimizing the main spectroscopic parameters. The PESs from the ab initio calculations at the level of CASPT2/vq(t)z were thus compared with those calculated from the experimentally determined spectroscopic parameters. The theoretical diagonal elements in the diabatic potential matrix are in good agreement with those determined using the experimental data, however, the theoretical off-diagonal elements appreciably deviate from those determined using the experimental data for geometric points far away from the conical intersections. It is also concluded that the JT effect in CH(3)Cl(+) mainly arises from the linear coupling and the mode coupling between the CH(3) deform (υ(5)) and CH(3) rock (υ(6)) vibrations. The mode couplings between the symmetric C-Cl stretching vibration υ(3) with υ(5) and υ(6) are also important to understand the spin-vibronic structure of the molecule.

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Photodissociation and formation of an ion‐pair in CH₂FCl (HCFC‐31)

Silva,

Rodrigues,

Ventura

et al. 2023

J Comput Chem

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Although CH2FCl (HCFC‐31) recently became of great atmospheric importance, studies concerning its excited states are almost nonexistent. Several excited singlet states were studied (valence nσ* and Rydberg n3s, n3p, σ3s, and σ3p) through highly correlated multireference configuration interaction with singles and doubles, including extensivity correction. Comparison with the states of CH3Cl indicates a strong influence of the F atom. Potential energy curves suggest formation of an electrostatically bound complex that relaxes to a hydrogen‐bonded contact ion‐pair (HBCIP) which can decay yielding CH2F + Cl or to the ground state minimum of CH2FCl. The HBCIP has a dipole moment of 9.57 D, a CI wavefunction described as 0.65ionic + 0.20biradical and it is strongly bonded by 4.72 eV. Its H bond has characteristics of moderate and strong H bonds. The simulated absorption spectrum confirms the nσ* assignment for the first and suggests the n3s + n3pσ assignment for the second band.

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The vacuum UV photoabsorption spectrum of methyl chloride (CH3Cl) and its perdeuterated isotopomer CD3Cl I. A Rydberg series analysis

Cited by 31 publications

References 28 publications

Ion-pair formation mechanisms in chloromethane, bromomethane and dichlorodifluoromethane

Ion-pair formation mechanisms in chloromethane, bromomethane and dichlorodifluoromethane

The Jahn-Teller effect in ${\rm CH}_{\rm 3} {\rm Cl}^{\rm + } ( {{\rm \tilde X}{}^{\rm 2}{\rm E}} )$ CH 3 Cl +(X̃E2): A combined high-resolution experimental measurement and ab initio theoretical study

Photodissociation and formation of an ion‐pair in CH₂FCl (HCFC‐31)

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The vacuum UV photoabsorption spectrum of methyl chloride (CH3Cl) and its perdeuterated isotopomer CD3Cl I. A Rydberg series analysis

Cited by 31 publications

References 28 publications

Ion-pair formation mechanisms in chloromethane, bromomethane and dichlorodifluoromethane

Ion-pair formation mechanisms in chloromethane, bromomethane and dichlorodifluoromethane

The Jahn-Teller effect in ${\rm CH}_{\rm 3} {\rm Cl}^{\rm + } ( {{\rm \tilde X}{}^{\rm 2}{\rm E}} )$ CH 3 Cl +(X̃E2): A combined high-resolution experimental measurement and ab initio theoretical study

Photodissociation and formation of an ion‐pair in CH2FCl (HCFC‐31)

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Photodissociation and formation of an ion‐pair in CH₂FCl (HCFC‐31)