Presentation is loading. Please wait.

Presentation is loading. Please wait.

K. Iwakuni, H. Sera, M. Abe, and H. Sasada Department of Physics, faculty of Science and Technology, Keio University, Japan 1 70 th. International Symposium.

Published byMilo Collins Modified over 9 years ago

Similar presentations

Presentation on theme: "K. Iwakuni, H. Sera, M. Abe, and H. Sasada Department of Physics, faculty of Science and Technology, Keio University, Japan 1 70 th. International Symposium."— Presentation transcript:

1 K. Iwakuni, H. Sera, M. Abe, and H. Sasada Department of Physics, faculty of Science and Technology, Keio University, Japan 1 70 th. International Symposium on Molecular Spectroscopy June 23, 2015 The University of Illinois TF02

2 Outline 1. Comb-referenced DFG spectrometer 2. Observed spectra and analysis 3. Assignment and determination of molecular constants 2

3 ν f rep ECLD Nd:YAG laser 1.06 μm 1.55 μm PPLN 3.4 μm ECAC InSb detector Comb-referenced DFG spectrometer OFC TAI synthesizer Rb clock Pump Signal Idler

4 The method of absolute frequency measurement of the DFG light 4 ν signal pump f beat2 f beat1 ν n1 = f ceo + n 1 f rep ν n2 = f ceo + n 2 f rep f rep = 67 MHz ・・・ 0 Hz f ceo ν idler Absolute frequency Narrow linewidth (250 kHz → 25 kHz) Repeatability sweep High resolution High accuracy High sensitivity ν DFG = (n 1 ‐ n 2 ) f rep + ( f beat1 – f beat2 ) Rb clock

5 1.55 μm Comb-referenced +Wavelength-modulation DFG spectrometer ν f rep ECLD Nd:YAG laser 1.06 μm PPLN 3.4 μm ECAC InSb detector synthesizer absolute frequency signal lock in amp. modulation 3 kHz demodulation 3 kHz 21.4 MHz Rb clock

6 Sub-Doppler resolution spectrum of H 35 Cl R(0) the fundamental vibration band v = 1, J’ = 1 v = 0, J ”= 0 F’ = 1/2 F’ = 5/2 F’ = 3/2 F” = 3/2 R(0) measurement conditions ● sweep step; 0.01 Hz/step (13.1 kHz/step in the mid-infrared frequency) ● averaged over 20 frequency sweeps ● sweep time; 20 ms/step ● pressure; a few mTorr ● measurement time; 20 min. ● linewidth (HWHM); 230 kHz measurement conditions ● sweep step; 0.01 Hz/step (13.1 kHz/step in the mid-infrared frequency) ● averaged over 20 frequency sweeps ● sweep time; 20 ms/step ● pressure; a few mTorr ● measurement time; 20 min. ● linewidth (HWHM); 230 kHz F’ = 3/2 F’ = 5/2 F’ = 1/2 * * * *cross-over resonance Spin of Cl nuclear

7 * *cross-over resonance * ×2 * * * * * ☆ ΔF = +1, ☆ ΔF = 0 ☆ ☆ ☆ ☆ ☆ ☆ ☆ ☆ ☆ ☆ ☆☆ ☆ Observed spectra of H 35 Cl * * * ×2 R(1) R(2) ☆ ☆ ☆ ☆ ☆ ☆ ☆ ☆ ☆ ☆ ☆ * ×2 * * * * R(3) R(4)

8 Hamiltonian 8 Vibration energy Rotation energy Electric quadrupole hyperfine interaction Magnetic hyperfine interaction v: vibrational quantum number J: rotational quantum number Bv: rotational constant Dv: centrifugal distortion Hv, Lv: high order centrifugal distortion I: nuclear spin quantum number F: total angular momentum vibrational term value quadrupole coupling constant magnetic coupling constant

9 Hamiltonian 9 Vibration energy Rotation energy Electric quadrupole hyperfine interaction Magnetic hyperfine interaction vibrational term value quadrupole coupling constant magnetic coupling constant 0 Relative Freq. (reference) f1f1 f2f2

10 10 Determined molecular constants Analysis: Least-squares method DATA: H 35 Cl; 42 hyperfine-resolved transitions of R(0) to R(4) H 37 Cl; 35 hyperfine-resolved transitions of R(0) to R(3) The ground state constants are fixed at the values determined by Cazzoli*. L 1 is fixed at zero. The weight is taken 1 for all hyperfine-resolved transitions and 0 for unresolved lines. * G. Cazzoli, et. al, JMS 266, 161 (2004) v = 0 (sub-milli- meter data) v = 1

11 11 H 35 Cl: R(0) transition : Upper level : Lower level The difference of the comb mode number is determined from HITRAN2008. The uncertainly is typically 10 kHz for the lines with S/N higher than 4. The pressure shift is less than the measurement uncertainty. All ΔF = ±1, 0 transitions are observed.,,

12 : Upper level : Lower level H 35 Cl: R(1) transition All ΔF = +1, 0 transitions are observed. Any ΔF = – 1 transitions are not observed, but the frequencies can be experimentally determined. : weight 0 *,,

13 H 35 Cl: R(2) transition All ΔF = +1, 0 transitions are observed. Any ΔF = – 1 transitions are not observed, but the frequencies can be experimentally determined. : weight 0 * : Upper level : Lower level,,

14 H 35 Cl: R(3) transition All ΔF = +1, 0 transitions are observed. Any ΔF = – 1 transitions are not observed, but the frequencies can be experimentally determined. : weight 0 * : Upper level : Lower level,,

15 15 H 35 Cl: R(4) transition All ΔF = +1 transitions are observed. The frequencies of ΔF = 0 transitions are determined from that of the cross-over resonances. The frequencies of ΔF = – 1 transitions can be calculated. : weight 0 * : Upper level : Lower level,,

16 16 Determined molecular constants * G. Cazzoli, et. al, JMS 266, 161 (2004) *. The standard deviation: 10.1 kHz

17 Summary Transition frequencies of ΔF = ±1, 0 of R(0)-R(4) for H 35 Cl and R(0)- R(3) for H 37 Cl are determined with a typical uncertainty of 10 kHz using the comb-referenced DFG spectrometer. Six molecular constants are determined with a standard deviation of 10.1 kHz. The absolute frequency measurements and the assignment of absorption lines are consistent, and the model Hamiltonian is accurate enough to reproduce the measured transition frequencies. 17 Acknowledgments This research is financially supported by Grand-in-Aid for Scientific Research (A), the Photon Frontier Network Program of the Ministry of Education, Culture, Sports, Science and Technology, and JST, ERATO, MINOSHIMA Intelligent Optical Synthesizer Project Japan. Kana Iwakuni et. al, JMS 306 (2014) 19-25, Hyperfine-resolved transition frequency list of fundamental vibration bands of H 35 Cl and H 37 Cl

Download ppt "K. Iwakuni, H. Sera, M. Abe, and H. Sasada Department of Physics, faculty of Science and Technology, Keio University, Japan 1 70 th. International Symposium."

Similar presentations

High-resolution spectroscopy with a femtosecond laser frequency comb Vladislav Gerginov 1, Scott Diddams 2, Albrecht Bartels 2, Carol E. Tanner 1 and Leo.

High-resolution spectroscopy with a femtosecond laser frequency comb Vladislav Gerginov 1, Scott Diddams 2, Albrecht Bartels 2, Carol E. Tanner 1 and Leo.
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.
1 THz vibration-rotation-tunneling (VRT) spectroscopy of the water (D 2 O) 3 trimer : --- the 2.94THz torsional band L. K. Takahashi, W. Lin, E. Lee, F.

1 THz vibration-rotation-tunneling (VRT) spectroscopy of the water (D 2 O) 3 trimer : --- the 2.94THz torsional band L. K. Takahashi, W. Lin, E. Lee, F.
Sub-Doppler Resolution Spectroscopy of the fundamental band of HCl with an Optical Frequency Comb ○ K. Iwakuni, M. Abe, and H. Sasada Department of Physics,

Sub-Doppler Resolution Spectroscopy of the fundamental band of HCl with an Optical Frequency Comb ○ K. Iwakuni, M. Abe, and H. Sasada Department of Physics,
Results The optical frequencies of the D 1 and D 2 components were measured using a single FLFC component. Typical spectra are shown in the Figure below.

Results The optical frequencies of the D 1 and D 2 components were measured using a single FLFC component. Typical spectra are shown in the Figure below.
PRECISION CAVITY ENHANCED VELOCITY MODULATION SPECTROSCOPY Andrew A. Mills, Brian M. Siller, Benjamin J. McCall University of Illinois, Department of Chemistry.

PRECISION CAVITY ENHANCED VELOCITY MODULATION SPECTROSCOPY Andrew A. Mills, Brian M. Siller, Benjamin J. McCall University of Illinois, Department of Chemistry.
Dual-Comb Spectroscopy of C2H2, CH4 and H2O over 1.0 – 1.7 μm

Dual-Comb Spectroscopy of C2H2, CH4 and H2O over 1.0 – 1.7 μm
MID-IR SATURATION SPECTROSCOPY OF HeH + MOLECULAR ION HSUAN-CHEN CHEN,CHUNG-YUN HSIAO Institute of Photonics Technologies, National Tsing Hua University,

MID-IR SATURATION SPECTROSCOPY OF HeH + MOLECULAR ION HSUAN-CHEN CHEN,CHUNG-YUN HSIAO Institute of Photonics Technologies, National Tsing Hua University,
Supersonic Jet Spectroscopy on TiO 2 Millimeter-wave Spectroscopy of Titanium Monoxide and Titanium Dioxide 63 rd International Symposium on Molecular.

Supersonic Jet Spectroscopy on TiO 2 Millimeter-wave Spectroscopy of Titanium Monoxide and Titanium Dioxide 63 rd International Symposium on Molecular.
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.
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.

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.
Infrared Diode Laser Spectroscopy of the ν 3 Fundamental Band of the PO 2 Free Radical.

Infrared Diode Laser Spectroscopy of the ν 3 Fundamental Band of the PO 2 Free Radical.
Spectroscopy with comb-referenced diode lasers

Spectroscopy with comb-referenced diode lasers
Laser-microwave double resonance method in superfluid helium for the measurement of nuclear moments Takeshi Furukawa Department of Physics, Graduate School.

Laser-microwave double resonance method in superfluid helium for the measurement of nuclear moments Takeshi Furukawa Department of Physics, Graduate School.
TB06 TB06 PRECISION FREQUENCY MEASUREMENT OF N 2 O TRANSITIONS NEAR 4.5  m AND ABOVE 150  m WEI-JO TING, CHUN-HUNG CHANG, SHIH-EN CHEN, HSUAN CHEN CHEN,

TB06 TB06 PRECISION FREQUENCY MEASUREMENT OF N 2 O TRANSITIONS NEAR 4.5  m AND ABOVE 150  m WEI-JO TING, CHUN-HUNG CHANG, SHIH-EN CHEN, HSUAN CHEN CHEN,
High Precision Mid-Infrared Spectroscopy of 12 C 16 O 2 : Progress Report Speaker: Wei-Jo Ting Department of Physics National Tsing Hua University 2010.06.25.

High Precision Mid-Infrared Spectroscopy of 12 C 16 O 2 : Progress Report Speaker: Wei-Jo Ting Department of Physics National Tsing Hua University
Tunable Mid-IR Frequency Comb for Molecular Spectroscopy

Tunable Mid-IR Frequency Comb for Molecular Spectroscopy
Sub-Doppler Spectroscopy of Molecular Ions in the Mid-IR James N. Hodges, Kyle N. Crabtree, & Benjamin J. McCall WI06 – June 20, 2012 University of Illinois.

Sub-Doppler Spectroscopy of Molecular Ions in the Mid-IR James N. Hodges, Kyle N. Crabtree, & Benjamin J. McCall WI06 – June 20, 2012 University of Illinois.
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.
Zeinab. T. Dehghani, A. Mizoguchi, H. Kanamori Department of Physics, Tokyo Institute of Technology Millimeter-Wave Spectroscopy of S 2 Cl 2 : A Candidate.

Zeinab. T. Dehghani, A. Mizoguchi, H. Kanamori Department of Physics, Tokyo Institute of Technology Millimeter-Wave Spectroscopy of S 2 Cl 2 : A Candidate.

Similar presentations

Ads by Google