72 research outputs found

    On the solutions of the Schrodinger equation with some molecular potentials: wave function ansatz

    Get PDF
    Making an ansatz to the wave function, the exact solutions of the DD% -dimensional radial Schrodinger equation with some molecular potentials like pseudoharmonic and modified Kratzer potentials are obtained. The restriction on the parameters of the given potential, δ\delta and η\eta are also given, where η\eta depends on a linear combination of the angular momentum quantum number \ell and the spatial dimensions DD and δ\delta is a parameter in the ansatz to the wave function. On inserting D=3, we find that the bound state eigensolutions recover their standard analytical forms in literature.Comment: 14 page

    ON THE MULTIPLICITY OF SOLUTIONS IN FORCE CONSTANTS AND NMR CALCULATIONS.

    No full text
    Author Institution: Czechoslovak Academy of Scienc

    ACETYLENE SPECTRA IN THE 5 MICRON REGION

    No full text
    Author Institution: Department of Physics, The Pennsylvania State UniversityThe ΠuΣg+\Pi_{u}-\Sigma^{+}_{g} bands (2ν4+ν3)1(2\nu_{4}+\nu_{3})^{1} at 1940.002 and 1959.697cm11959.697 cm^{-1} and 3ν513\nu^{1}_{5} at 2169.166cm12169.166 cm^{-1} together with fourteen accompanying “hot” bands of 12C2H2^{12}C_{2}H_{2} were measured using a high-resolution grating spectrometer equipped with an InSb photo-voltaie detector. The “hot” bands are the Σ+Π,ΣΠ\Sigma^{+}-\Pi, \Sigma^{-}-\Pi and ΔΠ\Delta-\Pi transitions of 3ν4+ν41,2ν4+2ν5ν51ν4+3ν5ν413\nu_{4}+\nu^{1}_{4}, 2\nu_{4}+2\nu_{5}-\nu^{1}_{5}\nu_{4}+3\nu_{5}-\nu^{1}_{4} and 4ν5ν514\nu_{5}-\nu^{1}_{5}; in addition, the R-branches of the ν2+ν51ν41\nu_{2}+\nu^{1}_{5}-\nu^{1}_{4} and ν2+ν51ν41ΠΠ\nu_{2}+\nu^{1}_{5}-\nu^{1}_{4}\Pi-\Pi bands were also observed. The information obtained on the strongly interacting upper states involved in the transitions analyzed has made it possible to arrive at a reliable set of spectroscopic constants (anharmonic and rotation-vibration coupling constants) for the bending modes of the acetylene molecule

    ANHARMONCITY OF VALENCE FORCES IN SOME LINEAR TRIATOMIC MOLECULES

    No full text
    ^{*}On leave from Institute of Chemistry, Czechos lovak Academy of Science, Prague, Czechoslovakia. 1^{1}J. Pliva, Collection Czechoslov, Chem. Communs, 23, 777 (1958). 2^{2} E. R. Lippincott and R. Schroeder. J. Chem. Physics 23, 1131 (1955).Author Institution: Division of Pure Chemistry, National Research Council OttawaIt was previously shown1shown^{1} that an empirical valence-force type potential function set up in terms of general valence-force displacement coordinates may be used for an adequate representation of the potential energies of simple polyatomic molecules an

    OBSERVATION OF LARGE VIBRATIONAL l-TYPE RESONANCES IN THE S1 STATE OF BENZENE

    No full text
    Author Institution: Institut f\""{u}r Physikalische Chemie, TU M\""{u}nchen, Lichtenbergstrasse 4; Department of Physics, The Pennsylvania State UniversityImproved experimental methods have recently allowed us to analyze the structure of the fundamental bands in both the IR and UV spectrum of benzene with rotational resolution. Deviations from regular behavior could be well accounted for by anharmonic, Coriolis, and rotational l-type interactions. However, the spectra of multiply degenerate states are still incompletely understood. Large splittings of the various vibrational angular momentum components and the observed relative intensities remain to be explained. With sub-Doppler spectroscopy in a collimated beam, rotationally resolved spectra of the two vibronic bands which were previously assigned to the 601(0±1)(l001)1002(00)6_{0}{^{1}} (\ell_{0}^{\pm 1})(l0_{0}1)10_{0}^{2}(\ell_{0}^{0}) and 601(101)1002(ell0)6_{0}{^{1}} (10_{1})10_{0}^{2}(\\ell_{0}) transitions (Wilson numbering) were measured in the Munich laboratory. Each band could be separately described in terms of effective rotational and Coriolis ζ\zeta-constants. However, the values of these effective band constants would imply unrealistically large deviations from planarity (CνBv/2(C_{\nu}-B^{\prime}_{v}/2 of 5.46×104-5.46 \times 10^{-4} and 6.72×1046.72 \times 10^{-4} respectively for the two bands), and effective ζ\zeta's of -0.0083 and +0.0656+0.0656 instead of the expected values ζ0=0.578\mp \zeta_{0} = \mp 0.578. We have therefore carried out a simultaneous analysis of the two bands with inclusion of a vibrational l-type interaction of the form =C[(v++2)(v)(v+2)(v)]1/2=C[(v+\ell+2)(v-\ell)(v\ell+2)(v-\ell)]^{1/2} in the Hamiltonian. The resulting constants, CvBvC^{\prime}_{v}-B^{\prime}v, of 1.6×105cm11.6 \times 10^{-5} cm^{-1}, and ζeff\zeta_{eff} of -0.5248 and +0.5822, appear very reasonable; the coupling parameter C has the value 1.575cm1.1.575 cm^{-1.} This result, and a similar one for the 60116026_{0}{^{1}} 16_{0}{^{2}} bands, shows the importance of vibrational \ell-type resonances in the multiply degenerate combination states of benzene. The vibrational angular momentum character of such states, which comprise the majority of all vibrational states of benzene at higher excess energies, is therefore not well defined. Important implications for the intramolecular vibrational redistribution and for the nonradiative decay of benzene states are expected to arise

    CORRELATIONS AND ACCURACY OF ESTIMATION OF SPECTROSCOPIC CONSTANTS

    No full text
    Author Institution: Department of Physics, The Pennsylvania State UniversityA comparison and evaluation of the various methods for reducing spectroscopic data to spectroscopic constants or term values is made with the aid of an analysis of a number of ``synthetic” \sum - \sum bands generated from fixed sets of constants with random noise superimposed on the line positions. It is shown that the strong correlations that exist between the upper state constants B^{\prime}, D^{\prime} and the lower state constants BoB_{o}, DoD_{o} can be effectively broken up by using the difference constants ΔB\Delta B = B^{\prime} - BoB_{o} and ΔD\Delta D = D^{\prime} - DoD_{o} along with vov_{o}, for representing the upper states. The lower state constants BoB_{o} and DoD_{o} and their standard errors calculated from the combination differences Δ2\Delta_{2}F^{\prime\prime} (J) are shown to be as good as chose obtained from direct polynomial fits. If data for a number of bands originating in the same lower state are available, a considerable increase in accuracy of estimating the lower state constants can be attained by analyzing the bands simultaneously, e.g., using combination differences, provided the data are free from systematic errors. The dependence of the accuracy of determining the constants BoB_{o}, DoD_{o}, νo\nu_{o}, Δ\DeltaB, and ΔD\Delta D on the extent of the band analyzed was investigated by varying the minimum and maximum J-values. The plots showing this dependence for both the actual errors and standard errors can be used e.g., to assess the band size necessary to attain a desired accuracy for a given constant

    DECONVLVING INFRARED SPECTRA BEYOND THE DOPPLER LIMIT

    No full text
    Author Institution:In high-resolution molecular spectroscopy, the Doppler line width often poses a limitation on the resolution and thereby on the amount of information one can extract form the spectra. to enhance the effective resolution and attain effective line width smaller than the Doppler width, we have applied the deconvolution technique to the infrared spectra of medium size molecules (e.g., C6H6C_{6}H_{6}) measured with a difference frequency laser system, as well as to spectra of light molecules (e.g., CH4CH_{4}) measured on a grating spectrometer. Using a Gaussian line shape function, we were able to enhance the resolution by a factor of 3 to 3.5 obtaining a linewidth of better than 1.5×103cm11.5 \times 10^{-3} cm^{-1} in the deconvolved difference frequency laser spectrum. To test the reliability of the deconvolution routine, a synthetic many-line spectrum was generated and convolved with Gaussians of widths 4.3×103cm1(=154.3 \times 10^{-3} cm^{-1} (= 15 points) and 1.4×103cm1(=51.4 \times 10^{-3} cm^{-1} (=5 points) to match the linewidths of the measured and deconvolved spectra respectively. Deconvolution of the 15-point curve yielded a result almost indistinguishable from the 5-point curve. The effect of random noise and of slight background variations on the deconvolved curve was also studied. We conclude that, with proper care, quite reliable results can obtained by deconvolution of reasonably noise-free spectra
    corecore