Experimental investigation of the rotational- and vibrational-state dependence of the HF–Rg interactions

Duijn, E.J. van; Nokhai, R. N.; Hermans, L. J. F.

doi:10.1063/1.472490

Cited by 18 publications

(5 citation statements)

References 53 publications

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“…Spectroscopy of HF and its clusters has been extensively investigated in both experimental − and theoretical works. − This is because HF molecules provide a prototype for hydrogen-bonded systems. In particular, HF dimers as one of the simplest systems have attracted the greatest interest. − ,− Hydrogen bond interconversion of dimers causes the tunneling splitting in their spectra and has been considered as one of the primary processes of cluster dynamics .…”

Section: Introductionmentioning

confidence: 99%

“…HF monomers, polymers, and clusters with other species in condensed phases have been also studied in many works. − Infrared absorption spectra of the monomer and polymers, and HF-N 2 , HF-H 2 , HF-O 2 , etc., in solid Ar and solid Ne were reported previously. − The matrix isolation technique has been a useful method for spectroscopy of unstable molecules including radicals and clusters. , However, strong interactions with rare gas matrices make it difficult to perform a high resolution spectroscopy and detailed studies of subtle interactions and dynamics in solids.…”

Section: Introductionmentioning

confidence: 99%

“…Quantum matrices such as solid p H 2 − and helium nanodroplets − , are proven to be excellent environments for the high-resolution spectroscopy of cold molecules. In general, molecules embedded in these quantum matrices exhibit quantized rotational states and extremely long lifetimes of vibration–rotation excited states, which makes the line widths of the rovibrational transitions of molecules narrow in these quantum matrices.…”

Section: Introductionmentioning

confidence: 99%

“…In general, molecules embedded in these quantum matrices exhibit quantized rotational states and extremely long lifetimes of vibration–rotation excited states, which makes the line widths of the rovibrational transitions of molecules narrow in these quantum matrices. Furthermore, the small cage effect of solid p H 2 allows us to use it as a reaction field and study chemical reactions at low temperature, including tunneling-reactions. − He nanodroplet studies in combination with the pendular spectroscopy performed by R. E. Miller et al − revealed the structure and dynamics of HF monomers, polymers, and clusters with other species in the superfluid helium environment. Their time scale to trace the dynamics was limited in the millisecond range.…”

Section: Introductionmentioning

confidence: 99%

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Spectroscopy of HF and HF-Containing Clusters in Solid Parahydrogen

et al. 2011

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We report measurements of FT-IR absorption spectroscopy of HF, DF, and their clusters in solid parahydrogen (pH(2)). The observed spectra contain many absorption lines which were assigned to HF monomers, HF polymers, and clusters with other species, such as N(2), O(2), orthohydrogen (oH(2)), etc. The rotational constants of HF and DF monomers were determined from the cooperative transitions of the vibration of solid pH(2) and the rotation of HF and DF. Small reduction of the rotational constants indicates that HF and DF are nearly free rotors in solid pH(2). Time dependence of the spectra suggests that HF and DF monomers migrate in solid pH(2) and form larger polymers, probably via tunneling reactions through high energy barriers on inserting another monomer to the polymers. The line width of HF monomers in solid pH(2) was found to be 4 cm(-1), which is larger than that of other hydrogen halides in solid pH(2). This broad line width is explained by rapid rotational relaxation due to the accidental coincidence between the rotational energy of HF and the phonon energy with maximum density of states of solid pH(2) and the rotational-translational coupling in a trapping site.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Spectroscopy of HF and HF-Containing Clusters in Solid Parahydrogen

et al. 2011

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“…When averaging over the initial M i , some care should be taken in view of the anisotropy ("alignment") induced by laser excitation. Since its effect on the experimental results has been shown to be small [10], [13], we will ignore this and assume an isotropic distribution. Because of the orthonormality of the tensor T 1σ , the double summations reduce to single ones.…”

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confidence: 99%

Rotational quenching of dipole-dipole interaction

1997

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Experiments based upon light-induced drift have yielded direct information on the rotational-state dependence of intermolecular interactions. Data were obtained for the change in collision rate ν upon rovibrational (J, v) excitation of HF in Ar, H2, HCl, CH4 and CH3F. It is found that J and v have independent influences on ν. For the dipole-dipole cases, ν decreases by up to 40% as JHF increases from 0 to 6. This is attributed to the increased averaging-out of the dipolar potential. A theoretical treatment based upon the first Born approximation yields good agreement with the HF-HCl data.

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Nearside−Farside Analysis of Differential Cross Sections: Ar + HF Rotationally Inelastic Scattering

2001

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We report accurate coupled-channel quantum calculations of state-to-state and degeneracy-averaged differential cross sections for the rotationally inelastic collision Ar + HF(V i ) 0, j i ) 0, m i ) 0) f Ar + HF(V f ) 0, j f , m f ), where V i , j i , m i and V f , j f , m f are initial and final vibrational, rotational, and helicity quantum numbers, respectively. The calculations have been performed at eight collision energies and assume that HF is a rigid rotator. Structure in the differential cross sections is analyzed using the unrestricted version of nearsidefarside (NF) theory. The NF theory decomposes the partial wave series (PWS) for the helicity scattering amplitude into two subamplitudes, one N, the other F. This is the first application of NF theory to an atomheteronuclear molecule inelastic collision. It is demonstrated that the NF technique provides a clear physical interpretation of the angular scattering, except sometimes for scattering angles, θ, close to 0°and 180°. It is also shown that a resummation of the PWS can improve the usefulness of the NF technique, when the N and F cross sections possess small oscillations. The resummation procedure exploits recurrence properties of reduced rotation matrix elements to extract a factor (R + βcos θ) -1 from the PWS, where R and β are constants. Criteria for choosing R and β so as to obtain a physically meaningful NF decomposition are discussed.

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Experimental investigation of the rotational- and vibrational-state dependence of the HF–Rg interactions

Cited by 18 publications

References 53 publications

Spectroscopy of HF and HF-Containing Clusters in Solid Parahydrogen

Spectroscopy of HF and HF-Containing Clusters in Solid Parahydrogen

Rotational quenching of dipole-dipole interaction

Nearside−Farside Analysis of Differential Cross Sections: Ar + HF Rotationally Inelastic Scattering

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