dc.creator Cosléou, J. en_US dc.creator Paplewski, M. en_US dc.creator Bürger, H. en_US dc.creator Demaison, J. en_US dc.creator Gerke, C. en_US dc.creator Harder, H. en_US dc.date.accessioned 2007-11-20T17:11:34Z dc.date.available 2007-11-20T17:11:34Z dc.date.issued 1995 en_US dc.identifier 1995-TA-01 en_US dc.identifier.uri http://hdl.handle.net/1811/29729 dc.description $^{1}$R. Bocquet, D. Boucher, W. D. Chen, D. Papousek, G. Wlodarczak and J. Demaison, J. Mol. Spectrosc. 163, 291-299 (1994) en_US dc.description Author Institution: Université de Lille 1, 59655 VILLENEUVE D'ASCQ France; Universität-Gesamthochschule, FB 9, D 42037 WUPPERTAL, Germany; "Abteilung Chemische Physik, Universität Kiel", Olshausenstrasse 40-60, D 24098 KIEL Germany en_US dc.description.abstract The infrared spectra of the $\nu_{2}$ and $\nu_{3}$ fondamental bands of $CDF_{3}$ have been recorded with a high resolution $(0.003 cm^{-1})$ FTIR spectrometer (BRUKER IFS 120HR). The K structure was analysed up to J = 50 for both states : 2488 lines of $\nu_{2}$ and 1956 lines of $\nu_{3}$ were assigned. We added also results from a previous analysis of millimeter-wave spectra of the ground, $\nu_{2} = 1$ and $\nu_{3} = 1$ $states^{1}$. Rotational constants and quartic and sextic centrifugal distorsion parameters have been determined accurately. These parameters are much more precise than those reported in previous works. The rotational spectrum of the $\nu_{6} = 1$ state was measured up to 500 GHz and direct $\ell-type$ resonance transitions were observed between 2 and 24 GHz. Two different sets of parameters were used to fit the data because the effective Hamiltonian may be reduced in different ways. The unitary equivalence of both sets of parameters is verified. en_US dc.format.extent 64277 bytes dc.format.mimetype image/jpeg dc.language.iso English en_US dc.publisher Ohio State University en_US dc.title Analysis of the rotation-vibration in the $\nu_{2} = 1, \nu_{3} = 1$ and $\nu_{6} = 1$ states of $CDF_{3}$ en_US dc.type article en_US
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