Presentation is loading. Please wait.

Presentation is loading. Please wait.

High-resolution Laser Spectroscopy

Published byGordon Harris Modified over 5 years ago

Similar presentations

Presentation on theme: "High-resolution Laser Spectroscopy"— Presentation transcript:

1 High-resolution Laser Spectroscopy
ISMS, Univ. of Illinois, June 2015 High-resolution Laser Spectroscopy of the S1←S0 Transition of Cl-naphthalenes Shunji Kasahara, Ryo Yamamoto, and Kenichiro Kanzawa Molecular Photoscience Research Center, Kobe University, Japan Naphthalene 2-Cl naphthalene (2-ClN) 1-Cl naphthalene (1-ClN)

2 Rotationally Resolved High-Resolution Laser Spectroscopy
Introduction PAHs (Polycyclic Aromatic Hydrocarbons) benzene naphthalene anthracene H. Katô, M. Baba, and S. Kasahara, Bull. Chem. Soc. Jpn. 80, 456 (2007) M. Baba et. al., J. Chem. Phys. 130, (2009) D. Y. Beak et. al., Bull. Chem. Soc. Jpn. 79(1), 75 (2006), etc. K. Yoshida et. al., J. Chem. Phys. 130, (2009), etc. Rotationally Resolved High-Resolution Laser Spectroscopy Molecular Constants   Molecular Structure Linewidth Energy Shift Excited-State Dynamics Zeeman Effect   

3 Molecular Constants Molecular Structure
Introduction Intramolecular heavy-atom effect ? S0 IC IVR ISC absorption fluorescence phosphorescence S1 S2 T1 2-Chloronaphthalene (2-ClN) 1-Chloronaphthalene (1-ClN) Molecular Constants   Molecular Structure Linewidth Energy Shift Excited-State Dynamics Zeeman Effect   

4 Experimental set up

5 Observed high-resolution spectrum
Marker Etalon cm-1 Doppler-free Saturation Spectrum of I2 cm-1 cm-1 cm-1 Sub-Doppler Fluorescence Excitation Spectrum of 2-ClN

6 2-Cl naphthalene (2-ClN)

7 Low-resolution spectrum (Vibronic bands)
Dispersed Fluorescence Spectrum LIF spectrum (a) (a) (b) (c) (d) (b) (c) (d) Jacobson et al., J. Chem. Phys. 87, 269 (1987).

8 High-resolution fluorescence excitation spectrum of 0-0 band of 2-ClN S1←S0 transition
band origin cm-1 Calculated spectrum (35Cl only, a-type 18 %, b-type 82 %, Tr = 20 K, line width 15 MHz) Observed spectrum

9 Molecular constants of 2-35Cl naphthalene
S0 (ref ) S1 (ref) υ =0 A/ cm-1 (37) (36) (3) (1) B (24) (24) (1) (13) C (19) (20) (1) (2) ∆J 2.25(86) ×10-10  2.29(86)×10-10 1.668(17)×10-10 ∆K 2.356(76)×10-9  2.132(67)×10-8 9.23(27)×10-9 a-type 18% ∆JK 3.34(45)×10-9  3.16(45)×10-9 1.33(30)×10-10 b-type 82% δJ 2.62(41)×10-10  2.80(42)×10-10 3.502(67)×10-11 δK -1.37(44)×10-8 -1.43(44)×10-8  6.7(10)×10-10 origin/cm-1 (2) (1) Std.dev. fitted lines 4583 assigned lines 4725 822 a b (ref) D. F. Plusquellic, et al. J. Chem. Phys, 115, 225 (2001)

10 High-resolution fluorescence excitation spectrum of 0-0 band of 2-ClN S1←S0 transition
band origin cm-1 Calculated spectrum (35Cl only, a-type 18 %, b-type 82 %, Tr = 20 K, line width 15 MHz) Observed spectrum

11 High-resolution fluorescence excitation spectrum of 0-0 band of 2-ClN S1←S0 transition
pPKa (J) rPKa(J) + : + : ∆Kc = +1 - : ∆ Kc= -1

12 Zeeman effect for the 0-0 band of 2-ClN S1←S0 transition (with magnet)
H = 0 T H = 1 T rP0 (28) rP0 (27) rP0 (26) pP5 (8) pP5 (7) pP5 (9) rP0 (29)

13 Zeeman splittings of the 0-0 band of 2-ClN S1←S0 transition
J-L coupling (electronic Coriolis interaction) 0.5 T Ka = 0 (J =Kc) S2 ( cm-1 band) J-L coupling term -2JzLz S1 ZS : Zeeman splitting C : naphthalene : C = cm-1 2-Cl naphthalene : C = cm-1 Lz : Angular momentum along with z-axis μB : Bohr magneton J Kc a(x) b(y) c(z) For the 2-ClN, (i) the order of magnitude of Zeeman Splitting is small.      (ii) the J- and K-dependences are found.  ZS ∝ (Kc)2, ZS ∝ J    These results are almost the same as naphthalene. Foe benzene and naphthalene, Bull. Chem. Soc. Jpn. 80, 456 (2007) ,etc.

14 Low-resolution spectrum (Vibronic bands)
Dispersed Fluorescence Spectrum LIF spectrum (a) (a) (b) (c) (d) (b) 0 – 0 band τ = 31ns → Γ = 5.1 MHz (c) cm-1band τ = 11 ns → Γ = 14 MHz (d) Jacobson et al., J. Chem. Phys. 87, 269 (1987).

15 High-resolution fluorescence excitation spectrum of 000+1042 cm-1 band of 2-ClN S1←S0 transition
band origin: (1) cm Trot = 30 K a-type:b-type = 1:3 Linewidth (FWHM) 50 MHz band origin Calc. Obs.

16 Molecular constants of 2-35Cl naphthalene
S0 (ref ) S1 (ref) υ =0 1042 cm-1 band A/ cm-1 (37) (36) (26) (3) (1) B (24) (24) (85) (1) (13) C (19) (20) (36) (1) (2) ∆J 2.25(86) ×10-10  2.29(86)×10-10 1.668(17)×10-10 ∆K 2.356(76)×10-9  2.132(67)×10-8 9.23(27)×10-9 a-type 18% ∆JK 3.34(45)×10-9  3.16(45)×10-9 1.33(30)×10-10 b-type 82% δJ 2.62(41)×10-10  2.80(42)×10-10 3.502(67)×10-11 δK -1.37(44)×10-8 -1.43(44)×10-8  6.7(10)×10-10 origin/cm-1 (2) (2) (1) Std.dev. fitted lines 4583 1596 assigned lines 4725 1651 822 a b (ref) D. F. Plusquellic, et al. J. Chem. Phys, 115, 225 (2001)

17 High-resolution fluorescence excitation spectrum of 000+1042 cm-1 band of 2-ClN S1←S0 transition
band origin: (1) cm Trot = 30 K a-type:b-type = 1:3 Linewidth (FWHM) 50 MHz band origin Calc. Obs.

18 High-resolution fluorescence excitation spectrum of 000+1042 cm-1 band of 2-ClN S1←S0 transition
Calc. Obs.

19 Energy shifts in the 000+1042 cm-1 band of 2-ClN S1←S0 transition

20 High-resolution spectrum of vibronic band of 2-ClN S1←S0 transition
×1 Excess Energy 476 1042 1396 Lifetime (ns) 31 23 11 8 Natural Line width (MHz) 5.1  6.9  14 20 0 – 0 ×3.5 cm-1 ×3.5 cm-1 ×3.5 cm-1

21 1-Cl naphthalene (2-ClN)

22 High-resolution fluorescence excitation spectrum of 0-0 band of 1-Cl naphthalene (1-ClN) S1←S0 transition S0: A = (30), B = (84), C = (35) [cm-1] S1: A = (31), B = (84), C = (35) [cm-1] band origin (3) cm-1 Trot = 60 K a-type:b-type = 1:2 Linewidth (FWHM) 120 MHz band origin Calc. Obs. Wavenumber / cm-1

23 High-resolution fluorescence excitation spectrum of 0-0 band of 1-Cl naphthalene (1-ClN) S1←S0 transition Calc. Obs.

24 Zeeman effect for the 0-0 band of 1-ClN S1←S0 transition (with magnet)
Zeeman splittings are not found because (1) Zeeman splittings are small. (2) the rotational lines are overlapped even if there are J, K-dependence. What is the background? H = 1.2 T H = 0 T Wavenumber / cm-1

25 Summary We have observed high-resolution fluorescence excitation spectra and their Zeeman effect by crossing a UV laser perpendicular to a molecular beam. 2-ClN 1-ClN Measurement of the 0-0 band ・Rotationally resolved spectra have been observed and assigned. (Typical linewidth was 15 MHz) ・Rotational line has not been resolved. (Typical linewidth was 120 MHz) ・Molecular constants were estimated from simulation and partial assignment of the observed spectrum. Under the external magnetic field up to 1.2 T ・Zeeman effect has been observed. ・Zeeman splittings are small. ・J, K-dependence were found. ・Zeeman effect has not been observed. *There is strong background signal.  Measurement of the vibronic bands ・Rotationally resolved spectra have been observed and assigned. ・Energy shifts were found. ・Not yet.

26 Thank you for your attension !

27 Comparison between 1-ClN and 2-ClN for the 0-0 band of S1←S0 transition (1)
2-ClN 0-0 band: τ = 31 ns *, Γ = 5.1 MHz band origin 31416    31417    31418        31420    31421    31422 1-ClN 0-0 band: τ = 3.4 ns*, Γ = 47 MHz 31571    31572       31574    31575    31576    31577 *Jacobson et al., J. Chem. Phys. 87, 269 (1987). Wavenumber / cm-1

28 Comparison between 1-ClN and 2-ClN for the 0-0 band of S1←S0 transition (2)
2-ClN 0-0 band: τ = 31 ns *, Γ = 5.1 MHz                          1-ClN 0-0 band: τ = 3.4 ns*, Γ = 47 MHz                             *Jacobson et al., J. Chem. Phys. 87, 269 (1987). Wavenumber / cm-1

Download ppt "High-resolution Laser Spectroscopy"

Similar presentations

Masato Hayashi & Yasuhiro Ohshima Department of Photo-molecular Science Institute for Molecular Science (IMS) National Institutes of.

Masato Hayashi & Yasuhiro Ohshima Department of Photo-molecular Science Institute for Molecular Science (IMS) National Institutes of.
Rotationally-resolved infrared spectroscopy of the polycyclic aromatic hydrocarbon pyrene (C 16 H 10 ) using a quantum cascade laser- based cavity ringdown.

Rotationally-resolved infrared spectroscopy of the polycyclic aromatic hydrocarbon pyrene (C 16 H 10 ) using a quantum cascade laser- based cavity ringdown.
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,
Stimulated Raman scattering If high enough powered radiation is incident on the molecule, stimulated Anti-Stokes radiation can be generated. The occurrence.

Stimulated Raman scattering If high enough powered radiation is incident on the molecule, stimulated Anti-Stokes radiation can be generated. The occurrence.
Laser Induced Fluorescence Structural information about the ground and excited states of molecules. Excitation experiments  Excited state information.

Laser Induced Fluorescence Structural information about the ground and excited states of molecules. Excitation experiments  Excited state information.
INTRO TO SPECTROSCOPIC METHODS (Chapter 6 continued ) Quantum-Mechanical Properties Of Light Photoelectric Effect Photoelectric Effect Energy States of.

INTRO TO SPECTROSCOPIC METHODS (Chapter 6 continued ) Quantum-Mechanical Properties Of Light Photoelectric Effect Photoelectric Effect Energy States of.
Methyl Torsional Levels in 9-Methylanthracene

Methyl Torsional Levels in 9-Methylanthracene
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.
MODERATE RESOLUTION JET COOLED CAVITY RINGDOWN SPECTROSCOPY OF THE A STATE OF NO 3 RADICAL Terrance J. Codd, Ming-Wei Chen, Mourad Roudjane and Terry A.

MODERATE RESOLUTION JET COOLED CAVITY RINGDOWN SPECTROSCOPY OF THE A STATE OF NO 3 RADICAL Terrance J. Codd, Ming-Wei Chen, Mourad Roudjane and Terry A.
Anh T. Le and Timothy C. Steimle* The molecular frame electric dipole moment and hyperfine interaction in hafnium fluoride, HfF. Department of Chemistry.

Anh T. Le and Timothy C. Steimle* The molecular frame electric dipole moment and hyperfine interaction in hafnium fluoride, HfF. Department of Chemistry.
Anh T. Le and Timothy C. Steimle The electric dipole moment of Iridium monosilicide, IrSi Department of Chemistry and Biochemistry, Arizona State University,

Anh T. Le and Timothy C. Steimle The electric dipole moment of Iridium monosilicide, IrSi Department of Chemistry and Biochemistry, Arizona State University,
Nathan R. Pillsbury, Timothy S. Zwier, Department of Chemistry, Purdue University, West Lafayette, IN 47907; David F. Plusquellic, NIST, Gaithersburg,

Nathan R. Pillsbury, Timothy S. Zwier, Department of Chemistry, Purdue University, West Lafayette, IN 47907; David F. Plusquellic, NIST, Gaithersburg,
Funded by: NSF Timothy C. Steimle, Fang Wang a Arizona State University, USA & Joe Smallman b, Physics Imperial College, London a Currently at JILA THE.

Funded by: NSF Timothy C. Steimle, Fang Wang a Arizona State University, USA & Joe Smallman b, Physics Imperial College, London a Currently at JILA THE.
Fukuoka Univ. A. Nishiyama, A. Matsuba, M. Misono Doppler-Free Two-Photon Absorption Spectroscopy of Naphthalene Assisted by an Optical Frequency Comb.

Fukuoka Univ. A. Nishiyama, A. Matsuba, M. Misono Doppler-Free Two-Photon Absorption Spectroscopy of Naphthalene Assisted by an Optical Frequency Comb.
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.

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.
Novel Applications of a Shape Sensitive Detector 2: Double Resonance Amanda Shirar Purdue University Molecular Spectroscopy Symposium June 19, 2008.

Novel Applications of a Shape Sensitive Detector 2: Double Resonance Amanda Shirar Purdue University Molecular Spectroscopy Symposium June 19, 2008.
Electronic Spectroscopy of Palladium Dimer (Pd 2 ) 68th OSU International Symposium on Molecular Spectroscopy Yue Qian, Y. W. Ng and A. S-C. Cheung Department.

Electronic Spectroscopy of Palladium Dimer (Pd 2 ) 68th OSU International Symposium on Molecular Spectroscopy Yue Qian, Y. W. Ng and A. S-C. Cheung Department.
Fang Wang & Timothy C. Steimle Dept. Chem. & BioChem., Arizona State University, Tempe, AZ,USA The 65 th International Symposium on Molecular Spectroscopy,

Fang Wang & Timothy C. Steimle Dept. Chem. & BioChem., Arizona State University, Tempe, AZ,USA The 65 th International Symposium on Molecular Spectroscopy,
Electronic Spectroscopy of DHPH Revisited: Potential Energy Surfaces along Different Low Frequency Coordinates Leonardo Alvarez-Valtierra and David W.

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

Similar presentations

Ads by Google