International Symposium on Molecular Spectroscopy, June 22-26, 2015 1 First high-resolution analysis of the ν 21 band of propane at 921.4 cm -1 : Evidence.

Slides:

Advertisements

Similar presentations

A fitting program for molecules with two equivalent methyl tops and C 2v point-group symmetry at equilibrium: Application to existing microwave, millimeter,

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.

HIGH-RESOLUTION ANALYSIS OF VARIOUS PROPANE BANDS: MODELING OF TITAN'S INFRARED SPECTRUM J.-M. Flaud.

The Water Molecule: Line Position and Line Intensity Analyses up to the Second Triad L. H. Coudert, a G. Wagner, b M. Birk, b and J.-M. Flaud a a Laboratoire.

High-Lying Rotational Levels of Water obtained by FIR Emission Spectroscopy L. H. Coudert, a M.-A. Martin, b O. Pirali, b D. Balcon, b and M. Vervloet.

9th HITRAN Database & Atmospheric Spectroscopy Applications conferences Formaldehyde broadening coefficients Agnès Perrin Laboratoire Interuniversitaire.

A.Perrin: Ohio-State 62th Molecular Symposium, June 2007 New analysis of the 3 & 4 bands of HNO 3 by high resolution Fourier transform spectroscopy in.

Simulating the spectrum of the water dimer in the far infrared and visible Ross E. A. Kelly, Matt J. Barber, Jonathan Tennyson Department of Physics and.

Agnés Perrin Laboratoire Interuniversitaire des Systémes Atmosphériques (LISA), CNRS, Université Paris XII, Créteil C.Bray,

Submillimeter-wave Spectroscopy of 13 C 1 -Methyl formate [H 13 COOCH 3 ] in the Ground State Atsuko Maeda, Ivan Medvedev, Eric Herbst, Frank C. De Lucia,

Submillimeter-wave Spectroscopy of [HCOOCH 3 ] and [H 13 COOCH 3 ] in the Torsional Excited States Atsuko Maeda, Frank C. De Lucia, and Eric Herbst Department.

First high resolution analysis of the 5 3 band of nitrogen dioxide (NO 2 ) near 1.3 µm Didier Mondelain 1, Agnès Perrin 2, Samir Kassi 1 & Alain Campargue.

Interaction of the hyperfine coupling and the internal rotation in methylformate M. TUDORIE, D. JEGOUSO, G. SEDES, T. R. HUET, Laboratoire de Physique.

Chirality of and gear motion in isopropyl methyl sulfide: Fourier transform microwave study Yoshiyuki Kawashima, Keisuke Sakieda, and Eizi Hirota* Kanagawa.

Molecular Spectroscopy Symposium June 2011 ROTATIONAL SPECTROSCOPY OF HD 18 O John C. Pearson, Shanshan Yu, Harshal Gupta, and Brian J. Drouin,

Millimeter Wave Spectrum of Iso-Propanol A. MAEDA, I. MEDVEDEV, E. HERBST and F. C. DE LUCIA Department of Physics, The Ohio State University.

Millimeter- Wave Spectroscopy of Hydrazoic acid (HN 3 ) Brent K. Amberger, Brian J. Esselman, R. Claude Woods, Robert J. McMahon University of Wisconsin.

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

Praveenkumar Boopalachandran, 1 Jaan Laane 1 and Norman C. Craig 2 1 Department of Chemistry, Texas A&M University, College Station, Texas Department.

69 th International Symposium on Molecular Spectroscopy / Champaign-Urbana, Illinois, USA, June 16–20, 2014 HIGH-RESOLUTION INFRARED SPECTROSCOPY OF CUBANE,

Molecular Spectroscopy Symposium June 2011 TERAHERTZ SPECTROSCOPY OF HIGH K METHANOL TRANSITIONS John C. Pearson, Shanshan Yu, Harshal Gupta,

“Global Fit” of the high resolution infrared data of D 2 S and HDS molecules O. N. Ulenikov, E. S. Bekhtereva Physical Chemistry, ETH-Zurich, CH-8093 Zurich,

High-resolution spectroscopy of nitrous acid (HONO) and its deuterated species (DONO) in the far- and mid-IR spectral regions A. Dehayem-Kamadjeu, J. Orphal,

Xinchuan Huang, 1 David W. Schwenke, 2 Timothy J. Lee 2 1 SETI Institute, Mountain View, CA 94043, USA 2 NASA Ames Research Center, Moffett Field, CA 94035,

Methyl Bromide : Spectroscopic line parameters in the 10-μm region D. Jacquemart 1, N. Lacome 1, F. Kwabia-Tchana 1, I. Kleiner 2 1 Laboratoire de Dynamique,

20 June st International Symposium on Molecular SpectroscopyPetkie – TG03-p1 The Millimeter and Submillimeter-wave Spectrum of the , 6 1.

Synchrotron-Based High Resolution Spectroscopy of N-Bearing PAHs Sébastien Gruet, Olivier Pirali, Manuel Goubet and P. Bréchignac ISMS /06/2014.

68th Ohio State University Symposium on Molecular Spectroscopy June 17–21, 2013 SF 6 THE FORBIDDEN BAND UNVEILED V. BOUDON, Laboratoire Interdisciplinaire.

61th Ohio State University Symposium on Molecular Spectroscopy June 19–23, 2006 GLOBAL FREQUENCY AND INFRARED INTENSITY ANALYSIS OF 12 CH 4 LINES IN THE.

66th OSU International symposium on molecular spectroscopy

GLOBAL FIT ANALYSIS OF THE FOUR LOWEST VIBRATIONAL STATES OF ETHANE: THE 12  9 BAND L. Borvayeh and N. Moazzen-Ahmadi Department of Physics and Astronomy.

Rotationally-Resolved Spectroscopy of the Bending Modes of Deuterated Water Dimer JACOB T. STEWART AND BENJAMIN J. MCCALL DEPARTMENT OF CHEMISTRY, UNIVERSITY.

64th Ohio State University Symposium on Molecular Spectroscopy June 22–26, 2009 THE HIGH RESOLUTION FAR- INFRARED SPECTRUM OF METHANE AT THE SOLEIL SYNCHROTRON.

Atusko Maeda, Ivan Medvedev, Eric Herbst,

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

Fourier transform microwave spectra of CO–dimethyl sulfide and CO–ethylene sulfide Akinori Sato, Yoshiyuki Kawashima and Eizi Hirota * The Graduate University.

High-Resolution Visible Spectroscopy of H 3 + Christopher P. Morong, Christopher F. Neese and Takeshi Oka Department of Chemistry, Department of Astronomy.

A COMPREHENSIVE INTENSITY STUDY OF THE 4 TORSIONAL BAND OF ETHANE J. NOROOZ OLIAEE, N. Moazzen-Ahmadi Institute for Quantum Science and Technology Department.

A new spectroscopic observatory in Créteil to measure atmospheric trace gases in solar occultation geometry C. Viatte, P. Chelin, M. Eremenko, C. Keim,

Molecular Spectroscopy Symposium June 2013 Identification and Assignment of the First Excited Torsional State of CH 2 DOH Within the o 2, e.

70 th International Symposium on Molecular Spectroscopy / Champaign-Urbana, Illinois, USA, June 22–26, 2015 LOW-TEMPERATURE COLLISIONAL BROADENING IN THE.

Chuanxi Duan (段传喜） Central China Normal University Wuhan, China

A. Barbe, M.-R. De Backer-Barilly, Vl.G. Tyuterev Analysis of CW-CRDS spectra of 16 O 3 : 6000 to 6200 cm -1 spectral range Groupe de Spectrométrie Moléculaire.

Molecular Spectroscopy Symposium June 2010 Can the Inversion-Vibration-Rotation Problem in the 4 and 2 2 States of NH 3 be solved to Experimental.

High resolution far-infrared spectra of thiophosgene with a synchrotron source: The 1, 5, 2 4 and bands A.R.W. McKellar National Research Council.

Torsional Splitting in the Rotational Spectrum from 8 to 650 GHz of the Ground State of 1,1-Difluoroacetone L. Margulès, R. A. Motiyenko, Université de.

ROTATION-VIBRATIONAL ANALYSIS OF THE BANDS OF FORMALDEHYDE FALLING IN THE 3900 TO 5300 CM -1 REGION W.J. LAFFERTY Optical Technology Division NIST Gaithersburg,

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

The Cyclic CO 2 Trimer: Observation of two parallel bands and determination of intermolecular out-of-plane torsional frequencies Steacie Institute for.

Laser spectroscopy of a halocarbocation: CH 2 I + Chong Tao, Calvin Mukarakate, and Scott A. Reid Department of Chemistry, Marquette University 61 st International.

THz Spectroscopy of 1d-ethane: Assignment of v 18 ADAM M. DALY, BRIAN J. DROUIN, LINDA BROWN Jet Propulsion Laboratory, California Institute of Technology,

Millimeter-wave Rotational Spectrum of Deuterated Nitric Acid Rebecca A.H. Butler, Camren Coplan, Department of Physics, Pittsburg State University Doug.

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

Analysis of the rotation-torsion spectrum of CH 2 DOH within the e 0, e 1, and o 1 torsional levels L. H. Coudert, a John C. Pearson, b Shanshan Yu, b.

Microwave Spectroscopy of the Excited Vibrational States of Methanol John Pearson, Adam Daly, Jet Propulsion Laboratory, California Institute of Technology,

N. Moazzen-Ahmadi, J. Norooz Oliaee

Rotational spectra of C2D4-H2S, C2D4-D2S, C2D4-HDS and 13CH2CH2-H2S complexes: Molecular symmetry group analysis Mausumi Goswami and E. Arunan Inorganic.

Analysis of bands of the 405 nm electronic transition of C3Ar

MICROWAVE AND FIR SPECTROSCOPY OF DIMETHYLSULFIDE IN THE GROUND, FIRST AND SECOND EXCITED TORSIONAL STATES V. Ilyushin1, I. Armieieva1, O. Dorovskaya1,

Stephen J. Daunt, Robert Grzywacz

THE TORSIONAL FUNDAMENTAL BAND AND ROTATIONAL SPECTRA UP TO 940 GHZ OF THE GROUND, FIRST AND SECOND EXCITED TORSIONAL STATES OF ACETONE V.V. Ilyushin1,

NH3 measurements in the far-IR

First High Resolution IR Spectra of 2,2-D2-Propane The v20 (B1) A-Type Band Near cm-1. Determination of Ground and Upper State Constants Daniel.

Analysis of torsional splitting in the ν8 band of propane near 870

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

FIRST HIGH RESOLUTION IR SPECTRA OF 1-13C-PROPANE

F H F O Semiexperimental structure of the non rigid BF2OH molecule (difluoroboric acid) by combining high resolution infrared spectroscopy and ab initio.

THE ν9 (A1) B-TYPE BAND NEAR cm−1

Holger S. P. Müller, J. C. Pearson, S. Brünken, S. Yu,

Presentation transcript:

International Symposium on Molecular Spectroscopy, June 22-26, First high-resolution analysis of the ν 21 band of propane at cm -1 : Evidence of large amplitude motion tunneling effects A. Perrin, F. Kwabia Tchana, J.-M. Flaud LISA, CNRS, Universités Paris Est Créteil et Paris Diderot, Créteil, France L. Manceron CNRS-MONARIS UMR 8233 and Beamline AILES, Synchrotron Soleil, Saint Aubin, France J. Demaison, N. Vogt Universität Ulm, Section of Chemical Information Systems, Ulm, Germany P. Groner Department of Chemistry, University of Missouri – Kansas City, Kansas City, MO, USA W. Lafferty Optical Technology Dividion, National Institute of Standards and Technology, Gaithersburg, MD, USA

International Symposium on Molecular Spectroscopy, June 22-26, Importance of IR Spectroscopy of propane Gaseous propane, C 3 H 8, isPrevious high-resolution studies present in the atmospheres of Earth (biomass burning) Giant planets Some of their moons (Titan) Principal method to study abundance & distribution: High-resolution IR spectroscopy. a F. Kwabia Tchana, J.-M. Flaud, W.J. Lafferty, L. Manceron, P. Roy. J. Quant. Spectrosc. Rad. Transf. 111 (2010) 1277–1281 b G. Glasser, B. Reissenauer, W. Hüttner, Z. Naturforsch A 44 (1989) 316–24 c J.-M. Flaud, F. Kwabia Tchana, W.J. Lafferty and C.A. Nixon, Mol. Phys. 108 (2010) 699–704 d J.-M. Flaud, W.J. Lafferty, M. Herman, J. Chem. Phys. 114 (2001) SymE v / cm -1 TorsObserved ResonancesRef A1A n.o.a 26 1 B2B b 9292 A1A  (A-Corio)  26 1 c 26 1 B2B B1B d 18 1 B1B local 5151 A1A  (A-Corio)  24 1 d 17 1 B1B  (Anh)  B2B  (A– Corio)  A1A  (C-Corio)   (B-Corio)  24 1

International Symposium on Molecular Spectroscopy, June 22-26, IR Spectrum of propane Bruker IFS 125HR FT spectrometer SOLEIL–LISA cryo-cell AILES Beamline at SOLEILOptical path length:45.14 m HgCdTe (MCT) detector cooled by liquid N 2 Temperature:142 ± 2 K Resolution cm -1 Sample pressure:14.0 ±0.3 Pa

International Symposium on Molecular Spectroscopy, June 22-26, IR Spectrum of propane Two fundamental bands between 820 and 960 cm -1 a-type band at cm -1 ν 21 (in-plane CH 3 rock) b-type band at cm -1 ν 8 (sym CC stretch) Both bands have split rotational transitions due to interactions between overall and internal rotations of the methyl groups ν 21 : Summary of “First high resolution analysis of the ν 21 band of propane CH 3 CH 2 CH 3 at cm −1 : Evidence of large amplitude tunneling effects” A. Perrin et al. (2015) doi: /j.jms doi: /j.jms ν 8 : Preliminary analysis using ERHAM (Effective Rotational Hamiltonian) P. Groner, J. Chem. Phys. 107 (1997) ; J. Mol. Spectrosc. 278 (2012) 52-67

International Symposium on Molecular Spectroscopy, June 22-26, Internal rotation in propane Point group symmetry at equilibrium:C 2v Molecular symmetry group with 2 LAM’s (CH 3 groups):G 36 or [33]C 2v Each energy level in C 2v splits into four components E  E 00  E 01  E 11  E 12 (subscripts refer to σ 1 σ 2 ) C 2v G 36 ShorthandAAEEAEEA (σ 1 σ 2 )(00) (01), (10), (02), (20) (11), (22)(12), (21) A1A1 A1A1 GE1E1 E3E3 A2A2 A3A3 GE2E2 E3E3 B1B1 A4A4 GE2E2 E4E4 B2B2 A2A2 GE1E1 E4E4 K a K c GS nuclear spin weights of rotational energy levels e e / o o e o / o e

International Symposium on Molecular Spectroscopy, June 22-26, Analysis of ν 21 band “Conventional” analysis A. Perrin et al. (2015) doi: /j.jms doi: /j.jms Based on combination differences GS parameters from [1] kept constant 3 band centers identified for AA, EE & AE+EA substates Rotational & centrifugal distortion constants for each substate (  J  & sextic & octic CD constants kept constant at GS value) a Kept at value for EE substate [1]B. J. Drouin, J. C. Pearson, A. Walters, V. Lattanzi, J. Mol. Spectrosc. 240 (2006) 227–237. AAEEAE+EA EVEV (38) (33) (44) A (3600) (1100) (3700) B (2200) (1700) (2400) C (1100) (1200) (1100)    10 6 a12.714(560) a  KJ  10 7 a -4.51(180) a  J  10 7 a (730) a    10 7 a (550) a

Simulation Fig. 1 : Overview of the ν 21 band of propane. The distinctive shape of this typical A-type band is reproduced well. The experimental spectrum is compared to the calculation performed during this study. International Symposium on Molecular Spectroscopy, June 22-26, 20157

Simulation details Portions of R-branch near cm -1 (left) and of P-branch near cm -1 (right) [J, K a, K c ] = assignment in ν 21 state, “d” stand for degenerate K a. Non-degenerate K a : calculated intensities (spin weights ratio) for AA, EE and AE+EA components lead to reasonable agreement between observed and calculated spectra. Degenrate K a : agreement is not good (purple dots for [18,8,d]), triangles for [11,5,d], and diamonds for [11, 6, d].. International Symposium on Molecular Spectroscopy, June 22-26, 20158

Simulation details Portion of R branch near cm -1 (left) and central part of Q branch (right). [J, K a, K c ] = assignment in ν 21 state. Q-branch: The K a stacks with K a > 11 are not well reproduced. International Symposium on Molecular Spectroscopy, June 22-26, 20159

10 Origin of torsional splittings Comparison of torsional splittings E 01/EE – E 00/AA Torsional splitting in ν 21 expected to be comparable to splitting in GS without additional torsional interaction. However, it is about 8 times as large as in the torsional excited states ν 14 and ν 27. Why? E 01 –E 00 (cm -1 ) GS3.69E-05 ν ν ν

International Symposium on Molecular Spectroscopy, June 22-26, Torsional energy levels and splittings for J = 0 Literature analysis of torsional Raman spectra [1], [2] ab initio calculations [3] New fit of Raman data [1], [2] and splittings from rot. spectra in GS, ν 14 & ν 27 [4] ν ν 27, ν 21 FR 2ν ν 27, ν 8 FR 3ν 14 + ν 27 4ν 14 [1]J. R. Durig, P. Groner, and M. G. Griffin, J. Chem. Phys. 66 (1977) ; analysis of torsional Raman spectra, no splittings [2]R. Engeln, J. Reuss, D. Consalvo, J.W.I. Van Bladel, A. Van Der Avoird, V. Pavlov-Verevkin, Chem. Phys. 144 (1990) 81–9; analysis of torsional Raman spectra [3]M. Villa, M.L. Senent, M. Carvajal, Phys. Chem. Chem. Phys. 15 (2013) 10258–10269; ab initio methods, only up to 770 cm-1 [4]B. J. Drouin, J. C. Pearson, A. Walters, V. Lattanzi, J. Mol. Spectrosc. 240 (2006) 227–237.

International Symposium on Molecular Spectroscopy, June 22-26, Origin of larger torsional splittings Comparison of torsional splittings E 01/EE – E 00/AA Fermi resonance ν ν 27  ν 21 could increase such negligible splitting in the observed direction if ν 14 +3ν 27 had lower energy than ν 21 (instead of the predicted higher energy) Other perturbations Resonces have been observed particularly for 01/EE state transitions (though not for 00/AA). Coriolis interaction is allowed for some but not all torsional substates, particularly not for AA. E 01 –E 00 (cm -1 ) GS3.69E-05 ν ν ν ν 14 +3ν

International Symposium on Molecular Spectroscopy, June 22-26, Analysis of ν 8 band with ERHAM Initial assignments by combination difference method (CDM) Much less satisfactory than for ν 21 band (b/c splittings larger than in ν 8 band) Analysis with ERHAM [1] * Modified to allow prediction & fitting of rovibrational spectra * Initial assignments from CDM * Trial calculation of the most intense high-K a P- & R-branch transitions to establish direction of splitting patterns (6 lines): K a -degenerate transitions generate 6 characteristic lines, the strongest 3 with equal intensities (2 01/EE and 1 degenerate 00/AA) Example for & 6 61 – 5 50 at right: 2 predictions with opposite sign of ε 10, bottom: observed spectrum * Assignments with CAAARS [2] using Loomis-Wood diagrams [1] P. Groner, J. Chem. Phys. 107 (1997) ; J. Mol. Spectrosc. 278 (2012) [2] I. R. Medvedev, M. Winnewisser, B. P. Winnewisser,,F. C. De Lucia, E. Herbst., J. Mol. Struct. 742 (

International Symposium on Molecular Spectroscopy, June 22-26, Analysis of ν 8 band with ERHAM Current status 4185 transitions assigned, many blends (not fit as blends yet, incl. K a -degeneracy), max J = 30, max K a = with non-zero weight 00/AA : /EE: /AE: /EA: 73 ρ, β, GS constants from rotational spectroscopy [1] kept fixed sextic CD constants same as in GS 17 variable parameters cm -1 standard deviation Many resonances (level crossings) with unknown dark state [1] B. J. Drouin, J. C. Pearson, A. Walters, V. Lattanzi, J. Mol. Spectrosc. 240 (2006) 227–237 ρ β / deg 8.68 A / MHz (78) B / MHz (34) C / MHz (29) Δ J / kHz (23) Δ JK / kHz (15) Δ K / kHz (43) δ J / kHz (19) δ K / kHz (13) ε 00 / cm (94) ε 1-1 / MHz (82) ε 10 / MHz (11) ε 11 / MHz -76.5(12) ε 20 / MHz -8.98(85) ε 30 / MHz -3.87(64) [A-(B+C)/2] 10 / MHz (15) [(B+C)/2] 10 / MHz (21) [(B-C)/4] 10 / MHz (20)

International Symposium on Molecular Spectroscopy, June 22-26, Comparisons of observed and calculated spectrum Overview Q-branch J 0J – J 1,J-1 (J=9 → J=1)Q-branch J 1,J-1 -J 2,J-2 (J=16 → J=8  ) Circle: level crossing ,11

International Symposium on Molecular Spectroscopy, June 22-26, More comparisons R-branches J+1 1,J+1 -J 0J (J=10 → J=13) and J+1 0,J+1 -J 1J (J=11 → J=13) [last line also 15 1, ,13 ) 23 0, ,22 & 23 1, ,22 (left) (middle) , 18 3, ,15, 23 1, ,21 (right) 11 & 00 components have 2 degenerate transitions, intensities should be double! ,12

International Symposium on Molecular Spectroscopy, June 22-26, Origin of larger torsional splittings Comparison of torsional splittings E 01 -E 00 Fermi resonance ν ν 27  ν 21 could increase such negligible splitting in the observed direction if ν 14 +3ν 27 had lower energy than ν 21 (instead of the predicted higher energy) Similarly, FR 2ν ν 27  ν 8 could increase negligible native splitting in the observed direction if 2ν 14 +2ν 27 had lower energy than ν 8 (instead of the predicted higher energy) E 01 –E 00 (cm -1 ) GS3.69E-05 ν ν ν ν 14 +3ν ν8ν ν 14 +2ν

International Symposium on Molecular Spectroscopy, June 22-26, Discussion & conclusion A start is made!But a lot more needs to be done. a) More assignments necessary to higher J and K a more 11/AE and 12/EE components (more difficult b/c they are weaker) b) More parameters to try, particularly tunneling parameters c) Identify system of level crossings (01/EE and 12/EA components are much more susceptible to Coriolis interactions) d) With enough level crossings, it might be possible to approximate the dark state 2ν 14 +2ν 27 (and get a better torsional potential function). m) Work out some kinks in this modified version of ERHAM. z) Revisit ν 21 and try to characterize the dark state ν 14 +3ν 27.

International Symposium on Molecular Spectroscopy, June 22-26, Thank you