International Symposium on Molecular Spectroscopy

Slides:

Advertisements

Similar presentations

68th OSU International Symposium on Molecular Spectroscopy TH08

Advertisements

High sensitivity CRDS of the a 1 ∆ g ←X 3 Σ − g band of oxygen near 1.27 μm: magnetic dipole and electric quadrupole transitions in different bands of.

LINEAR MOLECULE ROTATIONAL TRANSITIONS:  J = 4  J = 3  J = 2  J = 1  J = 0.

D.L. KOKKIN, N.J. REILLY, J.A. JOESTER, M. NAKAJIMA, K. NAUTA, S.H. KABLE and T.W. SCHMIDT Direct Observation of the c State of C 2 School of Chemistry,

Analysis of the 18 O 3 CRDS spectra in the 6000 – 7000 cm -1 spectral range : comparison with 16 O 3. Marie-Renée De Backer-Barilly, Alain Barbe, Vladimir.

The spectral method: time-dependent quantum dynamics of FHF - : Potential Energy Surface, Vibrational Eigenfunctions and Infrared Spectrum. Guillermo Pérez.

Chemistry 6440 / 7440 Vibrational Frequency Calculations.

S&MPO linelist of 16 O 3 in the range 6000 – 7000 cm -1. M.-R. De Backer-Barilly #, Semen N. Mikhailenko*, Yurii Babikov*, Alain Campargue §, Samir Kassi.

A. Barbe, M.R. De Backer-Barilly, Vl.G. Tyuterev, A. Campargue 1, S.Kassi 1 Updated line-list of 16 O 3 in the range 5860 – 7000 cm -1 deduced from CRDS.

THE USE OF CAAARS (Computer Aided Assignment of Asymmetric Rotor Spectra ) IN THE ANALYSIS OF ROTATIONAL SPECTRA. (CAAARS) Ivan R. Medvedev, Manfred Winnewisser,

Rotational and Vibrational Spectra

Vibrational and Rotational Spectroscopy

Vibrational Spectroscopy

Supersonic Jet Spectroscopy on TiO 2 Millimeter-wave Spectroscopy of Titanium Monoxide and Titanium Dioxide 63 rd International Symposium on Molecular.

60th OSU International Symposium on Molecular Spectroscopy TF03 The millimeter-wave rotational spectrum of lactic acid Zbigniew Kisiel, Ewa Białkowska-Jaworska,

Spectroscopy of NCNCS at the Canadian Light Source: the far-infrared spectrum of the ν 7 region from cm -1 (and beyond…) Dennis W. Tokaryk, Stephen.

Fitting the high-resolution spectroscopic data for NCNCS Zbigniew Kisiel, a Brenda P. Winnewisser, b Manfred Winnewisser, b Frank C. De Lucia, b Dennis.

Optical Zeeman Spectroscopy of the (0,0) bands of the B 3  -X 3  and A 3  -X 3  Transitions of Titanium Monoxide, TiO Wilton L. Virgo, Prof. Timothy.

THE PURE ROTATIONAL SPECTRA OF THE TWO LOWEST ENERGY CONFORMERS OF n-BUTYL ETHYL ETHER. B. E. Long, G. S. Grubbs II, and S. A. Cooke RH13.

Electronic spectroscopy of CHBr and CDBr Chong Tao, Calvin Mukarakate, Mihaela Deselnicu and Scott A. Reid Department of Chemistry, Marquette University.

Electronic Spectroscopy of DHPH Revisited: Potential Energy Surfaces along Different Low Frequency Coordinates Leonardo Alvarez-Valtierra and David W.

64 th OSU International Symposium on Molecular Spectroscopy.

Rotational spectra of molecules in small Helium clusters: Probing superfluidity in finite systems F. Paesani and K.B. Whaley Department of Chemistry and.

Spectroscopic signatures of bond- breaking internal rotation in HCP. Mark S Child and Matt P Jacobson Oxford University UK UK EPSRC.

61st OSU International Symposium on Molecular Spectroscopy RI12 Rotational spectrum, electric dipole moment and structure of salicyl aldehyde Zbigniew.

Equilibrium Molecular Structure and Spectroscopic Parameters of Methyl Carbamate J. Demaison, A. G. Császár, V. Szalay, I. Kleiner, H. Møllendal.

Analysis of interactions between excited vibrational states in the FASSST rotational spectrum of S(CN) 2 Zbigniew Kisiel, Orest Dorosh Institute of Physics,

Int. Symp. Molecular Spectroscopy Ohio State Univ., 2005 The Ground State Four Dimensional Morphed Potentials of HBr and HI Dimers Collaborator: J. W.

ENERGY LEVELS OF THE NITRATE RADICAL BELOW 2000 CM -1 Christopher S. Simmons, Takatoshi Ichino and John F. Stanton Molecular Spectroscopy Symposium, June.

Ohio State (Current and recent): Laura Dzugan Jason FordSamantha Horvath Meng Huang Zhou LinMelanie Marlett Bernice Opoku-AgyemanAndrew PetitBethany Wellen.

65th Ohio State University Symposium on Molecular Spectroscopy June 21–25, 2010 Stark spectrum simulation of X 2 Y 4 asymmetric molecules: application.

ROTATIONAL ENERGIES AND SPECTRA: . LINEAR MOLECULE SPECTRA:  Employing the last equation twice  ΔE= E J+1 – E J = hB(J+1)(J=2) – hBJ(J+1)  Or: ΔE.

Effective C 2v Symmetry in the Dimethyl Ether–Acetylene Dimer Sean A. Peebles, Josh J. Newby, Michal M. Serafin, and Rebecca A. Peebles Department of Chemistry,

Towards understanding quantum monodromy in quasi-symmetric molecules: FASSST rotational spectra of CH 3 NCO and CH 3 NCS Zbigniew Kisiel, a Sarah Fortman,

IR Spectroscopy Wave length ~ 100 mm to 1 mm

Developing a Force Field Molecular Mechanics. Experimental One Dimensional PES Quantum mechanics tells us that vibrational energy levels are quantized,

The Analysis of Astrophysical ‘Weeds’ Using 3-D Submillimeter Spectroscopy SARAH M. FORTMAN, JAMES P. MCMILLAN, CHRISTOPHER F. NEESE, and FRANK C. DE LUCIA.

OSU International Symposium on Molecular Spectroscopy June 18 – 22, TF Infrared/Raman -- TF01, Tuesday, June 19, 2012.

Tao Peng and Robert J. Le Roy

1 The r 0 Structural Parameters of Equatorial Bromocyclobutane, Conformational Stability from Temperature Dependent Infrared Spectra of Xenon Solutions,

National Synchrotron Research Facility We conducted 4 Measuring Campaigns: May 2011, 2012, 2013, and 2014 CLS.

1 61 st International Symposium on Molecular Spectroscopy, Talk RD10, 22 June 2006, The Ohio State University, Columbus, OH Approved for Public Release;

Schrödinger Equation – Model Systems: We have carefully considered the development of the Schrödinger equation for important model systems – the one, two.

Dept. of Chemistry University of Arizona A. Janczyk L. M. Ziurys The Millimeter/Submillimeter Spectrum of AlSH (X 1 A) : Further Investigation of the Metal.

Rotational transitions in the and vibrational states of cis-HCOOH 7 9 Oleg I. Baskakov Department of Quantum Radiophysics, Kharkov National University.

Jun 18th rd International Symposium on Molecular Spectroscopy Microwave spectroscopy o ｆ trans-ethyl methyl ether in the torsionally excited state.

Laser spectroscopic study of CaH in the B 2 Σ + and D 2 Σ + state Kyohei Watanabe, Kanako Uchida, Kaori Kobayashi, Fusakazu Matsushima, Yoshiki Moriwaki.

Analysis of the FASSST rotational spectrum of S(CN) 2 Zbigniew Kisiel, Orest Dorosh Institute of Physics, Polish Academy of Sciences Ivan R. Medvedev,

Fourier-transform microwave spectroscopy of the CCCCl radical Takashi Yoshikawa, Yoshihiro Sumiyoshi, and Yasuki Endo Graduate School of Arts and Sciences,

Analysis of Hydrogen Bonding in the OH Stretch Region of Protonated Water Clusters Laura C. Dzugan and Anne B. McCoy June 26, 2015.

Lineshape analysis of CH3F-(ortho-H2)n absorption spectra in 3000 cm-1 region in solid para-H2 Yuki Miyamoto Graduate School of Natural Science and Technology,

Observing Quantum Monodromy

UNIT IV Molecules.

Stéphane Bailleux University of Lille

Hiroyuki Ozeki, Rio Miyahara, Hiroto Ihara, Satoshi Todaka,

The CP-FTMW Spectrum of Bromoperfluoroacetone

SIMULATIONS OF VIBRONIC LEVELS IN DEGENERATE ELECTRONIC STATES IN THE PRESENCE OF JAHN-TELLER COUPLING – EXPANSION OF PES THROUGH THIRD ORDER VADIM L.

3-Dimensional Intermolecular Potential Energy Surface of Ar-SH(2Pi)

Department of Chemistry, University of Wisconsin, Madison

Diatomic molecules

Analysis of the Rotationally Resolved Spectra to the Degenerate (

The Three-dimensional Potential Energy

Stéphane Bailleux Nitrosyl iodide, INO: millimeter-wave spectroscopy guided by ab initio quantum chemical computation.

A. M. Daly, B. J. Drouin, J. C. Pearson, K. Sung, L. R. Brown

Rigid Diatomic molecule

This is the far infra red spectrum of the diatomic molecule CO

I = μr2 μ = m1m2/(m1+m2) I (uÅ2) = / B(cm-1)

The Role of Higher CO-Multipole Moments in Understanding the Dynamics of Photodissociated Carbonmonoxide in Myoglobin Nuria Plattner, Markus Meuwly

Line Strength Measurements in the n2 band of H218O

COMPREHENSIVE ANALYSIS OF INTERSTELLAR

Presentation transcript:

International Symposium on Molecular Spectroscopy 64th Meeting - - June 22 – 26, 2009 WF06 in Dynamics

Chemistry Molecules Physics/ Technology Spectroscopic data Quantum monodromy as a lattice defect of energy-momentum maps Theoretical spectroscopy GSRB Hamiltonian Topology of potential function Mathematics The purpose of computing is insight, not numbers. Richard Hamming 1915 - 1998

Ab initio equilibrium structure of NCNCS CCSD(T)/cc-pV5Z level of theory This work J = 12 – 11 rotational transition observed by H. W. Kroto et al. J. Mol. Spectrosc. 113, 1 (1985)

4 normalization functions as indicated in panel b Re-scaling of the intensities for the NCNCS millimeter wave spectrum by using 4 normalization functions as indicated in panel b Predicted peak intensities for a-type Ka = 0, 1 and 2 rotational transitions Raw Data Normalization functions Normalized spectrum

Expanded screen dump of CAAARS display

1) Frequency(J) / [2(J + 1)] = Beff – Deff 2(J + 1)2 + … 2) GSRB least squares fit to Beff and Deff is currently limited to energy levels in the range from J = Ka to J = 25 MMW GSRB

Reduced Fortrat diagrams of the assigned rotational frequencies for NCNCS in 7 bending states Champagne bottle potential function for quasi-linear two-dimensional bending mode

<r2> Beff Quantum lattice of the effective rotational constants Beff for NCNCS Quantum lattice of expectation values <r2> of the bending coordinate r calculated with the GSRB wave functions Experimental Data are connected by solid lines. Circles are GSRB values Circles are GSRB values connected by dashed lines Beff <r2>

Three dimensional image of the quantum lattice for the end-over-end rotational energy contribution for NCNCS and OCCCS Lattice defect due to Champagne bottle potential function Lattice due to harmonic potential function NCNCS OCCCS

Beff E(vb,Ka) Quantum lattice of the effective rotational constants Beff for NCNCS Two-dimensional energy-momentum lattice for NCNCS representing GSRB bending-rotation term values E(vb,Ka) plotted for J = Ka Experimental Data are connected by solid lines. Circles are GSRB values Beff E(vb,Ka)

with the GSRB wave functions Quantum lattice of expectation values for <r> and <r2> of the bending coordinate r calculated with the GSRB wave functions <r> <r2>

SRB wave functions for NCNCS Expectation values of the permanent electric dipole moment components ma and mb over the CNC SRB wave functions for NCNCS <vb,Ka|ma(r)|vb,Ka> <vb,Ka|mb(r)|vb,Ka>

Conclusions and Insight Re-scaling of the experimental line intensities helps greatly in the assignment of high Ka and vb rotational lines in the NCNCS spectrum GSRB (including centrifugal distortion) analysis of monodromy in NCNCS is illustrated in the quantum lattice of the Beff values and the energy-momentum lattice of the bending-rotation term values. Both maps show clearly the effects of quantum monodromy as a lattice defect which depends on the topology of the bending potential function. The quantum lattice of the expectation values for <r> and <r2> using the GSRB wave functions show that all physical quantities that depend on the bending coordinate r exhibit similar quantum monodromy plots including rotational constants, dipole moments etc.