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The Rotational Spectrum and Conformational Structures of Methyl Valerate LAM NGUYEN Laboratoire Interuniversitaire des Systèmes Atmosphériques (LISA)

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Presentation on theme: "The Rotational Spectrum and Conformational Structures of Methyl Valerate LAM NGUYEN Laboratoire Interuniversitaire des Systèmes Atmosphériques (LISA)"— Presentation transcript:

1 The Rotational Spectrum and Conformational Structures of Methyl Valerate
LAM NGUYEN Laboratoire Interuniversitaire des Systèmes Atmosphériques (LISA) Université Paris Est Créteil WOLFGANG STAHL Institute of Physical Chemistry, RWTH Aachen University

2 Methyl valerate Methyl pentanoate
Chemistry : Linear aliphatic ester (methyl alkanoate) Natur : Fruit ester (odorants of fruits, flowers, wines...) Spectroscopy : Conformations, internal dynamics

3 Conformational analysis
Methoxy methyl group Butyl methyl group Methyl internal rotations  no new conformations

4 Conformational analysis
Methoxy methyl group Butyl methyl group Methyl internal rotations  no new conformations trans or cis esters cis esters much higher in energy  not observable under our experimental conditions  discard only trans esters are considered.

5 Conformational analysis
Methoxy methyl group Butyl methyl group Methyl internal rotations  no new conformations trans or cis esters cis esters much higher in energy  not observable under our experimental conditions  discard only trans esters are considered. Different conformations

6 Conformational analysis
MP2/ G(d,p), 11 stable conformers Conformers VIII-XI : more than 4.5 kJ·mol−1 higher in energy than the most stable conformer I  not observable  discard Except conformer V, all other conformers possess C1 symmetry.

7 Conformer I Most stable conformation of methyl valerate
No linear alkyl chain A = MHz, B = MHz, C = MHz  near prolate top a = 1.43 D, b = 0.39 D, c = 0.92 D  a-, b-, and c-type transitions

8 Conformer I Two methyl internal rotors Barrier heights :
Methoxy methyl group Butyl methyl group Two methyl internal rotors Barrier heights : Methoxy methyl group : about 420 cm1 (Methyl acetate : 422 cm 1, Methyl propionate : 429 cm1)  A-E splittings up to a few tens of MHz Butyl methyl group :  1000 cm1  no observable splittings

9 Molecular beam FT microwave spectroscopy, 2 – 26.5 GHz
Measurements Molecular beam FT microwave spectroscopy, 2 – 26.5 GHz High resolution Broadband scan Experimental accuracy: 2 kHz Doppler effect A – E splittings Broader lines (unresolved splittings from the alkyl methyl rotor)  4 kHz Series of automatically recorded spectra in the high resolution mode 250 kHz step width, 50 decays per step Frequency range : 9  13.5 GHz

10 Rigid-Rotor (A Species) Assignments
Expt. Calc.

11 Rigid-Rotor (A Species) Assignments
6 ← 5 7 ← 6 Expt. Calc. R-branch a-type J = 6 ← 5 and J = 7 ← 6 transitions shifted by  0.5 GHz

12 Rigid-Rotor (A Species) Assignments
Expt. Calc. Q-branch b-type transitions shifted by up to 2.0 GHz

13 Internal Rotation (E Species) Assignments
Expt. Methoxy methyl group Calc. Barrier to internal rotation : estimated to be 420 cm1 Polar-coordinates of the internal rotor axis : taken from the geometry optimized at the MP2/ G(d,p) level

14 Molecular Parameters PAR. Unit XIAM A MHz 5063.17500(71) B
(19) C (19) J kHz (64) JK −6.7550(49) K 68.77(14) J − (32) K 2.611(82) V3,1 cm–1 417.66(68) F0 GHz 157.98(22) (i1,a) 37.793(93) (i1,b) 52.293(93) (i1,c) (46) NA/NE 85/83 3.3 MP2 XIAMMP2 4407.0 656.2 (13 %) 932.3 34.6 (4 %) 897.4 51.0 (6 %)

15 Within the experimental accuracy
Molecular Parameters PAR. Unit XIAM A MHz (71) B (19) C (19) J kHz (64) JK −6.7550(49) K 68.77(14) J − (32) K 2.611(82) V3,1 cm–1 417.66(68) F0 GHz 157.98(22) (i1,a) 37.793(93) (i1,b) 52.293(93) (i1,c) (46) NA/NE 85/83 3.3 MP2 XIAMMP2 4407.0 656.2 (13 %) 932.3 34.6 (4 %) 897.4 51.0 (6 %) Within the experimental accuracy

16 Molecular Parameters PAR. Unit XIAM A MHz 5063.17500(71) B
(19) C (19) J kHz (64) JK −6.7550(49) K 68.77(14) J − (32) K 2.611(82) V3,1 cm–1 417.66(68) F0 GHz 157.98(22) (i1,a) 37.793(93) (i1,b) 52.293(93) (i1,c) (46) NA/NE 85/83 3.3 MP2 XIAMMP2 4407.0 656.2 (13 %) 932.3 34.6 (4 %) 897.4 51.0 (6 %)

17 Molecular Parameters PAR. Unit XIAM A MHz 5063.17500(71) B
(19) C (19) J kHz (64) JK −6.7550(49) K 68.77(14) J − (32) K 2.611(82) V3,1 cm–1 417.66(68) F0 GHz 157.98(22) (i1,a) 37.793(93) (i1,b) 52.293(93) (i1,c) (46) NA/NE 85/83 3.3 MP2 XIAMMP2 4407.0 656.2 (13 %) 932.3 34.6 (4 %) 897.4 51.0 (6 %)

18 Molecular Parameters PAR. Unit XIAM A MHz 5063.17500(71) B
(19) C (19) J kHz (64) JK −6.7550(49) K 68.77(14) J − (32) K 2.611(82) V3,1 cm–1 417.66(68) F0 GHz 157.98(22) (i1,a) 37.793(93) (i1,b) 52.293(93) (i1,c) (46) NA/NE 85/83 3.3 MP2 XIAMMP2 4407.0 656.2 (13 %) 932.3 34.6 (4 %) 897.4 51.0 (6 %)

19 Molecular Parameters PAR. Unit XIAM A MHz 5063.17500(71) B
(19) C (19) J kHz (64) JK −6.7550(49) K 68.77(14) J − (32) K 2.611(82) V3,1 cm–1 417.66(68) F0 GHz 157.98(22) (i1,a) 37.793(93) (i1,b) 52.293(93) (i1,c) (46) NA/NE 85/83 3.3 MP2 XIAMMP2 4407.0 656.2 (13 %) 932.3 34.6 (4 %) 897.4 51.0 (6 %)

20 Basis set variation Conformer I was definitively assigned !
a-type 6 ← 5 MP2/ G(d,p) level fails ! Which level works ?

21 Basis set variation Conformer I was definitively assigned !
a-type 6 ← 5 MP2/ G(d,p) level fails ! Which level works ? MP2/cc-pVDZ

22 Barrier heights in methyl alkanoates
PAR. Unit XIAM A MHz (71) B (19) C (19) J kHz (64) JK −6.7550(49) K 68.77(14) J − (32) K 2.611(82) V3,1 cm–1 417.66(68) F0 GHz 157.98(22) (i1,a) 37.793(93) (i1,b) 52.293(93) (i1,c) (46) NA/NE 85/83 3.3 coupling 422.0 cm1 Methyl acetate 429.3 cm1 Methyl propionate 425.1 cm1 Similar structures Methyl butyrate 417.7 cm1 Methyl valerate

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