1 -RJ16- NON COVALENT INTERACTIONS AND INTERNAL DYNAMICS IN ADDUCTS OF FREONS 69 th Symposium, Urbana-Champaign, June 16-20, 2012 Dipartimento di Chimica.

Slides:

Advertisements

Similar presentations

The Delicate Balance of Hydrogen Bond Forces in D-Threoninol 19 Di Zhang, Vanesa Vaquero Vara, Brian C. Dian and Timothy S. Zwier Zwier Research Group,

Advertisements

Influence of solvation on 1-aminonaphthalene photophysics: ultrafast relaxation in the isolated molecule, molecular clusters and solution by Raúl Montero,

SEMIEXPERIMENTAL EQUILIBRIUM STRUCTURES FOR THE EQUATORIAL CONFORMERS OF N- METHYLPIPERIDONE AND TROPINONE BY THE MIXED ESTIMATION METHOD JEAN DEMAISON,

Cristina PUZZARINI Dip. di Chimica “G. Ciamician”, Università di Bologna QUANTUM-CHEMICAL CALCULATIONS of SPECTROSCOPIC PARAMETERS for ROTATIONAL SPECTROSCOPY:

THE MICROWAVE SPECTRUM, STRUCTURE, AND DOUBLE PROTON EXCHANGE OF FORMIC ACID – NITRIC ACID Becca Mackenzie Chris Dewberry, Ken Leopold Department of Chemistry,

THE CONFORMATIONAL BEHAVIOUR OF GLUCOSAMINE I. PEÑA, L. KOLESNIKOVÁ, C. CABEZAS, C. BERMÚDEZ, M. BERDAKIN, A. SIMAO, J.L. ALONSO Grupo de Espectroscopia.

Susanna Stephens H 2 O  AgF characterised by Rotational Spectroscopy.

Pure Rotational and Ultraviolet-Microwave Double Resonance Spectroscopy of Two Water Complexes of para-methoxyphenylethylamine (pMPEA) Justin L. Neill,

The inversion motion in the Ne – NH 3 van der Waals dimer studied via microwave spectroscopy Laura E. Downie, Julie M. Michaud and Wolfgang Jäger Department.

Nicholas R. Walker, Susanna L. Stephens, David P. Tew and Anthony C. Legon 1 68 th International Symposium on Molecular Spectroscopy, Ohio State University,

Observation of the weakly bound (HCl) 2 H 2 O cluster by chirped-pulse FTMW spectroscopy Zbigniew Kisiel, a Alberto Lesarri, b Justin Neill, c Matt Muckle,

Microwave Spectrum of Hydrogen Bonded Hexafluoroisopropanol  water Complex Abhishek Shahi Prof. E. Arunan Group Department of Inorganic and Physical.

THE ELECTRONIC SPECTRUM OF JET-COOLED H 2 PO, THE PROTOTYPICAL PHOSPHORYL FREE RADICAL Mohammed A. Gharaibeh and Dennis J. Clouthier Department of Chemistry,

Microwave Spectroscopic Investigations of the C—H…  Containing Complexes CH 2 F 2 …Propyne and CH 2 ClF…Propyne Rebecca A. Peebles, Sean A. Peebles, Cori.

Microwave Spectra and Structures of H 2 S-CuCl and H 2 O-CuCl Nicholas R. Walker, Felicity J. Roberts, Susanna L. Stephens, David Wheatley, Anthony C.

Rotational Spectra and Structure of Phenylacetylene-Water Complex and Phenylacetylene-H 2 S (preliminary) Mausumi Goswami, L. Narasimhan, S. T. Manju and.

1 Infrared Spectroscopy of Ammonium Ion MG03: Sub-Doppler Spectroscopy of ND 3 H + Ions in the NH Stretch Mode MG04: Infrared Spectroscopy of Jet-cooled.

Microwave Spectrum and Molecular Structure of the Argon-(E )-1-Chloro-1,2-Difluoroethylene Complex Mark D. Marshall, Helen O. Leung, Hannah Tandon, Joseph.

†) Currently at Department of Chemistry, University of Manitoba A Microwave Study of the HNO 3 -N(CH 3 ) 3 Complex Galen Sedo, † Kenneth R. Leopold Department.

The Pure Rotational Spectrum of Pivaloyl Chloride, (CH 3 ) 3 CCOCl, between 800 and MHz. Garry S. Grubbs II, Christopher T. Dewberry, Kerry C. Etchison,

SILYL FLUORIDE: LAMB-DIP SPECTRA and EQUILIBRIUM STRUCTURE Cristina PUZZARINI and Gabriele CAZZOLI Dipartimento di Chimica “G. Ciamician”, Università di.

1 -RH06- PROTON DONOR/ACCEPTOR PROPENSITIES OF AMMONIA ROTATIONAL STUDIES OF ITS MOLECULAR COMPLEXES WITH ORGANIC MOLECULES 64 th OSU International Symposium.

Grupo de Espectroscopia Molecular, Unidad Asociada CSIC Laboratorios de Espectroscopia y Bioespectroscopia Edificio Quifima. Parque Científico Universidad.

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

Internal Rotation in CF 3 I  NH 3 and CF 3 I  N(CH 3 ) 3 Probed by CP-FTMW Spectroscopy Nicholas R. Walker, Susanna L. Stephens, Anthony C. Legon 66.

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

Grupo de Espectroscopía Molecular, Lab. De Espectroscopia y Bioespectroscopia Edificio Quifima, Unidad Asociada CSIC, Universidad de Valladolid Valladolid,

Conformational Flexibility in Hydrated Sugars: The Glycolaldehyde-Water Complex Juan-Ramon Aviles-Moreno, Jean Demaison and Thérèse R. Huet Laboratoire.

1 The rotational spectrum of 13 CH 3 NH 2 up to 1 THz Roman A. Motiyenko, Laurent Margulès PhLAM, Université Lille 1 Vadim Ilyushin Institute of Radio.

THE MICROWAVE STUDIES OF GUAIACOL (2-METHOXYPHENOL), ITS ISOTOPOLOGUES & VAN DER WAALS COMPLEXES Ranil M. Gurusinghe, Ashley Fox and Michael J. Tubergen,

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,

Accurate Equilibrium Structures of Piperidine and Cyclohexane JEAN DEMAISON, Laboratoire de Physique de Lasers, Atomes et Molécules, Université de Lille.

Structures and Internal Dynamics of H 2 S  ICF 3 and H 2 O  ICF 3 Nicholas R. Walker, Susanna L. Stephens, Anthony C. Legon 1 67 th International Symposium.

Structure Determination of Two Stereoisomers of Sevoflurane Dimer by CP-FTMW Spectroscopy Nathan A. Seifert, Cristobal Perez, Daniel P. Zaleski, Justin.

Determining the Tunneling Path of the Ar-CHF 3 Complex L. Coudert, a W. Caminati, b A. Maris, b P. Ottaviani, b and A. C. Legon c a Laboratoire Interuniversitaire.

Rotational spectroscopy of newly detected atmospheric ozone depleters: CF 3 CH 2 Cl, CF 3 CCl 3, and CFClCCl 3 Zbigniew Kisiel, Ewa Białkowska-Jaworska,

Susanna L. Stephens, John Mullaney, Matt Sprawling Daniel P. Zaleski, Nick R. Walker, Antony C. Legon 69 th International Symposium on Molecular Spectroscopy,

The Ohio State University International Symposium on Molecular Spectroscopy 68th Meeting - - June 17-21, 2013 Microwave Spectrum of Hexafluoroisopropanol,

0 ipc kiel The rotational spectrum of the pyrrole-ammonia complex Heinrich Mäder, Christian Rensing and Friedrich Temps Institut für Physikalische Chemie.

The rotational spectra of helium- pyridine and hydrogen molecule- pyridine clusters Chakree Tanjaroon and Wolfgang Jäger.

Laboratory of Millimetre-wave Spectroscopy of Bologna The ROTATIONAL SPECTRUM of HDO : ACCURATE SPECTROSCOPIC and HYPERFINE PARAMETERS G. Cazzoli*, V.

A. Nishiyama a, K. Nakashima b, A. Matsuba b, and M. Misono b a The University of Electro-Communications b Fukuoka University High Resolution Spectroscopy.

Nicholas R. Walker, David Hird, Anthony C. Legon 1 68 th International Symposium on Molecular Spectroscopy, Ohio State University, Broadband Rotational.

Helen O. Leung, Mark D. Marshall & Joseph P. Messenger Department of Chemistry Amherst College Supported by the National Science Foundation.

 -  and CH-  interactions in the molecular nitrogen- and methane-pyridine complexes Department of Chemistry University of Alberta.

CHIRPED PULSE AND CAVITY FT MICROWAVE SPECTROSCOPY OF THE HCOOH – N(CH 3 ) 3 WEAKLY BOUND COMPLEX Rebecca B. Mackenzie, Christopher T. Dewberry, and Kenneth.

The Rotational Spectrum of the Water–Hydroperoxy Radical (H 2 O–HO 2 ) Complex Kohsuke Suma, Yoshihiro Sumiyoshi, and Yasuki Endo Department of Basic Science,

Rotational Spectra of Adducts of Formaldehyde with Freons Qian Gou, 1 Gang Feng, 1 Luca Evangelisti, 1 Montserrat Vallejo-López, 2 Alberto Lesarri, 2 Walther.

1 L. Spada, Q. Gou, B.M. Giuliano, W. Caminati. 70 th Symposium, Urbana-Champaign, June 22-26, RH06- THE ROTATIONAL SPECTRUM OF PYRIDINE – FORMIC.

Structure of the SEVOFLURANE-BENZENE complex as determined by CP-FTMW spectroscopy Nathan A. Seifert, Daniel P. Zaleski, Justin L. Neill, Brooks H. Pate.

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

IN THE GAS PHASE AND IN SOLUTION

ROTATIONAL SPECTROSCOPY OF THE METHYL GLYCIDATE-WATER COMPLEX

Pure rotational spectrum of the “non-polar” dimer of Formic acid

Department of Chemistry

Mark D. Marshall, Helen O. Leung, Craig J. Nelson & Leonard H. Yoon

1Kanagawa Institute of Technology 3Georgia Southern University

Carlos Cabezas and Yasuki Endo

Daniel Zaleski,a John Mullaney,a Nicholas Walkera and Anthony Legonb

Rotational Spectra of Adducts of Pyridine with Methane and Its Halides

Department of Chemistry

A STUDY OF THE FORMAMIDE-(H2O)3 COMPLEX BY MICROWAVE SPECTROSCOPY

Microwave spectra of 1- and 2-bromobutane

ROTATIONAL SPECTRA OF HYDROGEN BONDED NETWORKS OF AMINO ALCOHOLS

Methylindoles – Microwave Spectroscopy

BROADBAND MICROWAVE SPECTROSCOPY AS A TOOL TO STUDY DISPERSION INTERACTIONS IN CAMPHOR-ALCOHOL SYSTEMS MARIYAM FATIMA, CRISTÓBAL PÉREZ, MELANIE SCHNELL,

Wei Lin, Anan Wu, Zin Lu, Daniel A. Obenchain, Stewart E. Novick

N-METHYL INVERSION IN PSEUDO-PELLETIERINE

and analysis of hyperfine structure from four quadrupolar nuclei

THE MICROWAVE SPECTRUM AND UNEXPECTED STRUCTURE OF THE BIMOLECULAR COMPLEX FORMED BETWEEN ACETYLENE AND (Z)-1-CHLORO-2-FLUOROETHYLENE Nazir D. Khan, Helen.

Presentation transcript:

1 -RJ16- NON COVALENT INTERACTIONS AND INTERNAL DYNAMICS IN ADDUCTS OF FREONS 69 th Symposium, Urbana-Champaign, June 16-20, 2012 Dipartimento di Chimica ”G.Ciamician” - Universita’di Bologna Dep. Química Física y Química Inorganica - Universidad de Valladolid Departamento de Quimica Fisica, Universidad del Pais Vasco, Bilbao. Q. Gou, L. Evangelisti, G. Feng, L. Spada, M. Vallejo, A. Lesarri, E. Cocinero, W. Caminati.

2 1)Oligomers of freons containing hydrogen. Weak hydrogen bonds. After investigating the rotational spectra of several complexes of freons, we can classify them in some categories, and relate the nature of the non bonding interactions to the chemical composition of the involved freons: 2) Adducts of freons containing hydrogen with other small molecules. Weak hydrogen bonds. 3) Adducts of perhalogenated freons with other small molecules. Halogen bonds. 4) Adducts of unsaturated perhalogenated freons with other small molecules n →  * interactions.

(CH 2 F 2 ) n First pure rot. Spectrum of a tetramer of an asymmetric top

Adducts of Freons containing hydrogen with small molecules: Weak hydrogen bonding and dynamics W.Caminati, J.-U.Grabow J.C.López, J.L.Alonso, Angew.Chem.Int.Ed (2005). J. Am. Chem. Soc. 1999, 121, Angew. Chem. Int. Ed., 2006, 45, 2438.

V 2 lower then in CH 2 F 2 -H 2 O The 0 + and 0 component lines of the 4 04 3 03 μ a transition of normal CH 2 F 2 – H 2 CO Relative intensity 1:3 5 Q.Gou, G.Feng, L.Evangelisti, M.Vallejo, A.Lesarri, E.J.Cocinero, W.Caminati, Phys. Chem. Chem. Phys., 15, 6714 (2013) Adducts of Freons containing hydrogen with small molecules: Weak hydrogen bonding and dynamics

6 C-H  Cl preferred to C- H  F Adducts of Freons containing hydrogen with small molecules: Weak hydrogen bonding and dynamics G.Feng, Q.Gou, L.Evangelisti, M.Vallejo, A.Lesarri, E.J.Cocinero, W.Caminati, Phys. Chem. Chem. Phys., (2014), just out

Perhalogenated freons: Halogen bond, much dynamics L.Evangelisti, G.Feng, P.Écija, E.J.Cocinero, F.Castaño, W.Caminati, Angew.Chem.Int.Ed., –7810 (2011) Free rotation of Water → Symmetric top Cl  O halogen bond “Real” Symmetric top Cl  N halogen bond G.Feng, L.Evangelisti, N.Gasparini, W.Caminati, Chem.Eur.J., (2012)

8 Perhalogenated freons: Halogen bond, much dynamics

9 Calculated and experimental rotational constants of CF 3 Cl-CH 3 F calcl.exptl. A/MHz (28) B/MHz (3) C/MHz (3) χ aa /MHz (1) (χ bb -χ cc )/MHz (3) Four isotopologues: CF 3 35 Cl-CH 3 F CF 3 37 Cl-CH 3 F CF 3 35 Cl-CD 3 F CF 3 37 Cl-CD 3 F Perhalogenated freons: Halogen bond, much dynamics

10 A 00 = A r + [W 00 (2) F  a 2 ] CF3 + [W 00 (2) F  a 2 ] CH3 B 00 = B r + [W 00 (2) F  b 2 ] CF3 + [W 00 (2) F  b 2 ] CH3 C 00 = C r + [W 00 (2) F  c 2 ] CF3 + [W 00 (2) F  c 2 ] CH3 V 3 ≈ 7 cal mol -1 Values of F  g 2 of the two internal rotation tops in the four isotopologues of the complex CF 3 35 Cl-CH 3 FCF 3 37 Cl-CH 3 FCF 3 35 Cl-CD 3 FCF 3 37 Cl-CD 3 F CF 3 F  a 2 /MHz F  b 2 /MHz CH 3 F  a 2 /MHz F  b 2 /MHz Assuming there’s no coupling between the two free internal motions: Perhalogenated freons: Halogen bond, much dynamics Q.Gou, L. Spada, E.J. Cocinero, W. Caminati, J. Phys. Chem. Lett., (2014)

Recorded 3 1,2  2 1,1 transition of the observed conformer showing the 35 Cl hyperfine structure. Each line exhibits the doppler doubling. EXP Unsaturated perhalogenated freons with other small molecules n→  * interactions. Q.Gou, G.Feng, L.Evangelisti, W.Caminati, Angew. Chem. Int. Ed., (2013).

ΔE/cm A/MHz B/MHz C/MHz χ aa (Cl)/MHz χ bb -χ cc (Cl)/MHz χ aa (N)/MHz χ bb -χ cc (N)/MHz Unsaturated perhalogenated freons with other small molecules n →  * interactions. This part concerns the investigation during the last few months of C 2 ClF 3 -Ammonia, and involves Q.Gou, L.Spada, Y.Gebose (Antwerpen), S. Melandri & myself.

3 1,3 ←2 1,2 F 1 ′+1/2, F′ ← F 1 ″ +1/2, F″ Unsaturated perhalogenated freons with other small molecules n →  * interactions.

35 Cl- 14 NH 3 37 Cl- 14 NH 3 35 Cl- 15 NH 3 35 Cl- 14 ND 3 A/MHz (2) (2) (6) (4) B/MHz (1) (1) (1) (7 ） C/MHz (1) (2) (7) (5) χ aa (Cl)/MHz (4)-18.71(1)-19.85(4)-14.33(2) χ bb -χ cc (Cl)/MHz (7)-38.63(1)-51.78(3)-51.82(2) χ ab (Cl)/MHz55.91(7)46(1)[55.91]57(1) χ bc (Cl)/MHz12(4)-[12] χ ac (Cl)/MHz10.3(5)6.8(7)[10.3]17.8(6) χ aa (N)/MHz-0.404(4)[-0.404]--0.94(1) χ bb -χ cc (N)/MHz-0.435(7)[-0.435]--1.09(2) χ ab (N)/MHz0.7(1)[0.7]-3.2(8) χ ac (N)/MHz1.8(6)[1.8]- D J /kHz2.518(1)2.416(2)2.547(8)2.654(6) D JK /kHz-6.71(2)-6.27(9)-7.4(2)-9.2(2) D K /kHz16.93(2)[16.93] d 1 /kHz-0.370(1)[-0.370]-0.414(9)-0.589(7) d 2 /kHz-0.115(2)[-0.115] σ/kHz N Unsaturated perhalogenated freons with other small molecules n →  * interactions.

CF 3 Cl C2H4C2H4 C2F4C2F4 CF 2 CFCl Sites of interaction