Presentation is loading. Please wait.

Presentation is loading. Please wait.

Observation of the forbidden transitions between the A 1  u and b 3  g - states of C 2 Graduate School of Natural Science and Technology Okayama Univ.

Published byMarybeth Haynes Modified over 8 years ago

Similar presentations

Presentation on theme: "Observation of the forbidden transitions between the A 1  u and b 3  g - states of C 2 Graduate School of Natural Science and Technology Okayama Univ."— Presentation transcript:

1 Observation of the forbidden transitions between the A 1  u and b 3  g - states of C 2 Graduate School of Natural Science and Technology Okayama Univ. Wang Chen, Jian Tang, Kentarou Kawaguchi

2 Introduction B 1g+B 1g+ B 1  g a 3u a 3u d 3  g c 3  u + b 3  g - X 1  g + A 1  u Phillips Ballik-Ramsay 15g15g Kokkin et al. (2006) Bornhauser et al. (2011) 29258.592(5) cm -1 C 2 : many singlet, triplet and even quintet states at lower energy Many transition systems were observed, perturbations exist very often Swan interaction Bernath

3 Deperturbation for the spin-orbit interaction spin-orbit interaction between b 3  g - and X 1  g + states :  X 1  g + |H SO |b 3  g -  = A bX  v X |v b   The first deperturbation analysis: E. A. Ballik and D. A. Ramsay, ApJ. 137, 84-101 (1963) E ( a 3  u ) – E ( X 1  g + ) = 716.24  5 cm -1  Further analysis with high resolution FTIR spectrum C. Amiot, J. Chauville and J. P. Maillard, JMS 75, 19-40 (1979) E ( a 3  u ) – E ( X 1  g + ) = 718.318(1) cm -1  Our new analysis: 68 th OSU Symposium (Columbus 2013) E (a 3  u ) – E( X 1  g + ) = 720.002(4) cm -1

4 Two definitions of Hamiltonians for 3  Merer & Brown JMS. 74, 488 (1979) R.N.Zare et.al., JMS. 46, 37 (1973) F1:F1: F2:F2: F3:F3:  Amiot et al.(1979) T e = 718.3 cm -1 (Zare)716.7 cm -1 (M&B)  Our value T e = 721.6 cm -1 (Zare) 720.0 cm -1 (M&B) The change was due to the different ways for deperturbation

5 Global analysis by Amiot et al.(1979)  Analysis for the unperturbed lines of b 3  g - - a 3  u Determine the effective molecular constants for various vibrational states Derive the Dunham coefficients for vibrational dependency  Deperturbation for the perturbed lines Obtain the energy difference E(a 3  u ) – E(X 1  g + ) spin-orbit interaction constant A bX

6 Problem in the previous deperturbation Roux et al., JMS 109, 334 (1985) cm -1 ‘perturbed’ ‘unperturbed’ 5.05 5.62 6.03 5.86  Analysis for the “unperturbed” lines includes small interaction: incomplete deperturbation  Ununified A bx values for different ‘v’ 5.7(4) cm -1 Ave.

7 Our new deperturbation analysis Global analysis simultaneously for the Phillips system and the Ballik-Ramsay system Molecular constants with vibrational expansion are used The overlap integrals  v’|v  in  X 1  g + |H SO |b 3  g -  = A bX  v X |v b  are calculated with Le Roy’s program (2005) New values for our new deperturbation:  E ( a 3  u –X 1  g + ) = 720.002(4) cm -1 A bX = 6.30(1) cm -1 E. Kagi & K. Kawaguchi, JMStruct. 795, 179 (2006) A deperturbation analysis by this method has been successful before for MgO For totally: 3950 lines (v max = 7, J max = 60) Standard deviation  = 0.004 cm -1

8 Determined molecular constants for C 2 A bX 6.298(12) cm -1 720.0015(42)

9 Perturbation at crossing rotational levels Roux et al., JMS 109, 334 (1985) b3g-b3g- X1g+X1g+ v = 3 v = 5 v = 4 v = 6 v = 3 v = 2 v = 1 v = 0 J=14 J=38 J=28 J=52 J=40 J=52 J=62 J< 0 Our result J = 2 !

10 J = 0 0 = J 2 4 6 8 2 4 6 2 4 6 8 X 1  g  v=6 b 3  g  v=3 F1F1 F3F3  E=0.08 cm -1 0.52 cm -1 Interaction at the crossing levels 0.55 cm -1 0.03 cm -1 H SO = 0.89 cm -1

11 Intensity for forbidden transitions b 3  g - v=3 J=2(F 1 ) X 1  g + v=6 J=2 A bX a 3  u v=4 Forbidden I Forbidden :I Allowed = b 2 : a 2 = 0.83 A 1  u v=4 Forbidden Allowed Ballik-Ramsay band Allowed Phillips band

12 Observed FTIR emission spectrum P.N.Ghosh, M.N.Deo and K.Kawaguchi, ApJ, 525, 539 (1999) CH 4 ( 80 mTorr )/He ( 6 Torr )Resolution : 0.02 cm - 1 C2C2 CH 4 v=(0-0) (1-2) (2-3) (3-4) Ballik-Ramsay Bernath

13 Forbidden transition Observed forbidden transitions

14 b 3  g - v=3 F 1 J=2 X 1  g + v=6 A bX Forbidden of Q 12 (2) Q 12 (2)Forbidden Q(2) F 2 Prediction:O-C=-0.0254 cm -1 By fitting:O-C=-0.0108 cm -1 Forbidden X 1  g + – a 3  u v=6 – 4 Q(2) F 2 Allowed b 3  g + – a 3  u v=3 – 4 Q 12 (2) Forbidden transition a 3  u v=4 J=2 F2F2

15 Forbidden of Q 1 (2) b 3  g - v=3 F 1 F1F1 J=2 Q 1 (2) Forbidden Q(2)F 1 X 1  g + v=6 A bX a 3  u v=4 J=2 Q 12 (2) Prediction:O-C=-0.0158 cm -1 By fitting:O-C=-0.0018 cm -1 Allowed b 3  g + – a 3  u v=3 – 4 Q 1 (2) Forbidden X 1  g + – a 3  u v=6 – 4 Q(2)F 1 Forbidden transition F2F2 Forbidden Q(2) F 2

16 Forbidden of R 3 (13) Prediction:O-C=-0.0243 cm -1 By fitting:O-C=-0.0061 cm -1 b 3  g - v=3 F 3 a 3  u v=4 F 3 J=14 J=13 R 3 (13) Forbidden R(13) F 3 X 1  g + v=6 A bX Forbidden X 1  g + – a 3  u v=6 – 4 Q(2)F 1 Forbidden transition Allowed b 3  g + – a 3  u v=3 – 4 R 3 (13)

17 Observed forbidden transitions X 1  g + (v=6) - a 3  u (v=4) J v (O-C)  2-2(F 2 ) 3569.9558 (-0.0108)  2-2(F 1 ) 3591.7409 (-0.0018)  14-13(F 3 ) 3597.8123 (-0.0061)

18 Conclusion  Our deperturbation analysis led to  E ( a 3  u – X 1  g + ) = 720.002(4) cm -1 which is 3.3 cm -1 larger than the previous value 716.69 cm -1.  Energy crossing at J = 2 of X 1  g + (v=6) and b 3  g ( v=3 ) is found newly with strong interaction and led to the forbidden transitions observed.  Three forbidden transitions for v=6-4 of X 1  g + - a 3  u showed in our spectrum in the predicted frequencies and intensities, which verified our deperturbation analysis.

19 Intensity for forbidden transitions b 3  g - v=3 F 1 J=2 X 1  g + v=6 A bX a3ua3u Forbidden b 3  g - v=3 F 3 a3ua3u J=14 Forbidden X 1  g + v=6 A bX I Forbidden :I Allowed = 0.83I Forbidden :I Allowed = 0.06

20 Our deperturbation analysis Global analysis simultaneously for the Phillips system and the Ballik-Ramsay system Molecular constants with vibrational expansion are used

21 Previous global analysis for unperturbed lines Amiot et al., JMS 75, 19 (1979)

Download ppt "Observation of the forbidden transitions between the A 1  u and b 3  g - states of C 2 Graduate School of Natural Science and Technology Okayama Univ."

Similar presentations

R.S. RAM, K. TERESZCHUK, I. GORDON 1, K.A. WALKER 2 and P. F. BERNATH Department of Chemistry, University of York, Heslington, York YO10 5DD, UK. 1 Harvard-Smithsonian.

R.S. RAM, K. TERESZCHUK, I. GORDON 1, K.A. WALKER 2 and P. F. BERNATH Department of Chemistry, University of York, Heslington, York YO10 5DD, UK. 1 Harvard-Smithsonian.
A Deperturbation Method to Aid in the Interpretation of Infrared Isotopic Spectra G. Garcia and C. M. L. Rittby Texas Christian University Fort Worth,

A Deperturbation Method to Aid in the Interpretation of Infrared Isotopic Spectra G. Garcia and C. M. L. Rittby Texas Christian University Fort Worth,
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 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.
Intracavity Laser Absorption Spectroscopy of PtS in the Near Infrared James J. O'Brien University of Missouri – St. Louis and Leah C. O'Brien and Kimberly.

Intracavity Laser Absorption Spectroscopy of PtS in the Near Infrared James J. O'Brien University of Missouri – St. Louis and Leah C. O'Brien and Kimberly.
Analysis of an 18 O and D enhanced lab water spectrum using variational calculations of HD 18 O and D 2 18 O spectra Michael J Down - University College.

Analysis of an 18 O and D enhanced lab water spectrum using variational calculations of HD 18 O and D 2 18 O spectra Michael J Down - University College.
1 OBSERVATION OF TWO  =0 + EXCITED ELECTRONIC STATES IN JET-COOLED LaH Suresh Yarlagadda Ph.D Student Homi Bhabha National Institute Bhabha Atomic Research.

1 OBSERVATION OF TWO  =0 + EXCITED ELECTRONIC STATES IN JET-COOLED LaH Suresh Yarlagadda Ph.D Student Homi Bhabha National Institute Bhabha Atomic Research.
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,

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

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

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.
IR EMISSION SPECTROSCOPY OF AMMONIA: LINELISTS AND ASSIGNMENTS. R. Hargreaves, P. F. Bernath Department of Chemistry, University of York, UK N. F. Zobov,

IR EMISSION SPECTROSCOPY OF AMMONIA: LINELISTS AND ASSIGNMENTS. R. Hargreaves, P. F. Bernath Department of Chemistry, University of York, UK N. F. Zobov,
Terrance J. Codd*, John Stanton†, and Terry A. Miller* * The Laser Spectroscopy Facility, Department of Chemistry and Biochemistry The Ohio State University,

Terrance J. Codd*, John Stanton†, and Terry A. Miller* * The Laser Spectroscopy Facility, Department of Chemistry and Biochemistry The Ohio State University,
Rovibronic Analysis of the State of the NO 3 Radical Henry Tran, Terrance J. Codd, Dmitry Melnik, Mourad Roudjane, and Terry A. Miller Laser Spectroscopy.

Rovibronic Analysis of the State of the NO 3 Radical Henry Tran, Terrance J. Codd, Dmitry Melnik, Mourad Roudjane, and Terry A. Miller Laser Spectroscopy.
Global analysis of broadband rotation and vibration-rotation spectra of sulfur dicyanide Zbigniew Kisiel, a Manfred Winnewisser, b Brenda P. Winnewisser,

Global analysis of broadband rotation and vibration-rotation spectra of sulfur dicyanide Zbigniew Kisiel, a Manfred Winnewisser, b Brenda P. Winnewisser,
Einstein A coefficients for vibrational-rotational transitions of NO

Einstein A coefficients for vibrational-rotational transitions of NO
FTIR Spectroscopy of the n4 bands of 14NO3 and 15NO3

FTIR Spectroscopy of the n4 bands of 14NO3 and 15NO3
65th OSU International Symposium on Molecular Spectroscopy RH14.

65th OSU International Symposium on Molecular Spectroscopy RH14.
Invisible electronic states and their dynamics revealed by perturbations Anthony J. Merer Institute of Atomic and Molecular Sciences, Taipei, Taiwan University.

Invisible electronic states and their dynamics revealed by perturbations Anthony J. Merer Institute of Atomic and Molecular Sciences, Taipei, Taiwan University.
Brookhaven Science Associates U.S. Department of Energy Hot band transitions in CH 2 Kaori Kobayashi *, Trevor Sears, Greg Hall Department of Chemistry.

Brookhaven Science Associates U.S. Department of Energy Hot band transitions in CH 2 Kaori Kobayashi *, Trevor Sears, Greg Hall Department of Chemistry.
The Electronic Spectra of Coordination Compounds.

The Electronic Spectra of Coordination Compounds.

Similar presentations

Ads by Google