Electronic Transition Spectra of Thiophenoxy and Phenoxy Radicals in Hollow cathode discharges

Electronic Transition Spectra of Thiophenoxy and Phenoxy Radicals in Hollow cathode discharges Tokyo Univ. Science Mitsunori ARAKI, Hiromichi WAKO, Kei NIWAYAMA and Koichi TSUKIYAMA 2014/06/16 2015/2/20 1

Diffuse Interstellar Bands Electronic Transition A or B Absorption X Optical absorption lines by molecule in diffuse cloud Near infrared ~ optical (line width: 0.5-50Å) First report: 1922 ~600 lines Diffuse Cloud 2015/2/20 2

What are origins of DIBs? Optical Transition Ion and/or radical Large Molecule Not Identified yet Identification of DIBs by Laboratory Spectroscopy 2015/2/20 3

How to identify DIBs? Optical Electronic Transition Space absorption Earth Star Lab Unidentified molecule Molecule DIB Spectrometer Discharge etc Spectra Identification fit 2015/2/20 4

Cavity Ring Down Spectrometer Pulsed dye laser, 10 Hz, ν = 0.1 cm -1 Hollow Cathode Discharge Discharge cell - G Electrodes 2015/2/20 5

Thiophenoxy Radical C 6 H 5 S Rotational Profile Model molecule to discuss Non-Boltzmann Distribution in diffuse cloud Radical: Optical Transition 10% of interstellar molecules -> Sulfide Simple PAH Good candidate of DIB Dose it fit to DIBs? 2015/2/20 6

Reported Laboratory Spectrum Electronic Transition 2 A 2 - X 2 B 1 DIBs LIF Disturbed Origin Shibuya et al., Chemical Physics, 121, 237-244, 1988 2015/2/20 7

Galactic Plane HD204827 having DIBs Celestial North HD204827 Pole HD204827 The 8th Magnitude Star 2015/2/20 8

DIBs and Reported Laboratory Spectrum HD204827 DIBs Wavelength (Å) 2015/2/20 9 Hobbs et al., ApJ, 680, 1256 (2008)

DIBs and Present Laboratory Spectrum by CRD HD204827 DIBs High Temperature Rotational Profile 300K C 6 H 5 SH 1000V Wavelength (Å) 2015/2/20 10 Hobbs et al., ApJ, 680, 1256 (2008)

Analysis of C 6 H 5 S Rotational Profile Rotational Constants Simulation of Non-Boltzmann Distribution in Diffuse Cloud Simulation of Rotational Profile in Diffuse Cloud Comparison with DIBs 2015/2/20 11

Rotational Constants from Rotational Profile 300K (cm -1 ) B3LYP/cc-pVTZ A B C A = = = = 0.1893 0.0546 0.0424 ( ) 0.0073 5 B+ C = 0.0017 1 2 T 19327.7 00 = ( 3) ( ) Wavelength (Å) Pgopher 2015/2/20 12

Non-Boltzmann Distribution in Diffuse Cloud Dark Clouds Diffuse Clouds Collision >> Radiation Less Collision + Radiation T r = 2.73 K T k = 100K Linear Molecule Oka et al., 2013, ApJ, 773, 42O T r = 14.6 K T r = 80 K 2015/2/20 13

Non-Boltzmann Distribution in Diffuse Cloud Dark Clouds Diffuse Clouds Collision >> Radiation Less Collision + Radiation T r = 2.73 K T k = 100K Linear Molecule Oka et al., 2013, ApJ, 773, 42O T r = 14.6 K T r = 80 K C 2v Asymmetric Top Singlet 2015/2/20 14

Rotation of C 2v Asymmetric Top J (K c ) K a Permanent dipole moment 2015/2/20 15

Boltzmann Distribution Collision >> Radiation Dark Clouds J = 3 J = 2 J = 1 High temperature Low temperature J = 0 K a = 0 K a = 1 K a = 2 K a = 3 2015/2/20 16

Rotation of C 2v Asymmetric Top Radiative Cooling a-type J (K c ) Diffuse Clouds K a No Radiative Cooling Permanent dipole moment 2015/2/20 17

Distribution in Diffuse Cloud Collision + Radiation (a-type) Diffuse Clouds J = 3 J = 2 K a = 0 High temperature Low temperature J = 1 J = 0 K a = 0 K a = 1 K a = 2 K a = 3 2015/2/20 18

Rotation of C 2v Asymmetric Top Slow Down J (K c ) Diffuse Clouds K a Hot Axis Continuous Rotation Permanent dipole moment 2015/2/20 19

Analysis of C 6 H 5 S Rotational Profile Rotational Constants Simulation of Non-Boltzmann Distribution in Diffuse Cloud Simulation of Rotational Profile in Diffuse Cloud Pgopher Comparison with DIBs 2015/2/20 20

2.73 K Non-Boltzmann distribution is important in diffuse clouds. HD204827 Rotational Profile in diffuse cloud Collision 40 K Radiation 2.73 K Collision 40 K Wavelength /Å 2015/2/20 21

Distribution in Diffuse Cloud Collision + Radiation (a-type) Diffuse Clouds J = 3 J = 2 K a = ±2 K a = 0 J = 1 J = 0 K a = 0 K a = 1 K a = 2 K a = 3 2015/2/20 22

Distribution in Diffuse Cloud Collision + Radiation (a-type) Diffuse Clouds A( K a = 0) > A( K a = ±2) ~ Collision The profile can depend on this competition. 2015/2/20 23

2.73 K Rotational Profile in diffuse cloud HD204827 Collision 40 K Radiation 2.73 K Narrower limit Wider limit Wavelength /Å 2015/2/20 24

Comparison with DIBs No fit No detection HD204827 Wavelength /Å 2015/2/20 25

Upper Limit of Column Density Simulation of Rotational Profile Band Width of C 6 H 5 S: 2Å Theoretical Calculation (TD B3LYP / cc pvtz) Oscillator Strength: f = 0.003 HD204827, Hobbs et al., ApJ, 680, 1256 (2008) Detection threshold: S/N = 5 Upper limit of column density 2 10 13 cm -2 2015/2/20 26

Summary Electronic Spectrum of Thiophenoxy Radical C 6 H 5 S By Cavity Ring Down Spectroscopy Simulation of Rotational Profile in Diffuse Cloud Upper limit of column density 2 10 13 cm -2 Non-Boltzmann distribution is important in diffuse cloud. 2015/2/20 27

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Einstein Coefficients and Oka Coefficient (1973) J B ρ n(j) B ρ A C C J-1 n(j-1) n ( )( ) ( )( ) J J A B ρ+ C = nj B ρ C + J 1 J 1 1 J 1 + J 1 2015/2/20 29

n Rotational Distribution Linear n ( J) = n( 0) J m= 1 Asym top 2 αb µ J ( ) ( ) 2m 1exp( 2hBm ktr) J = n0 m= K a 4 3 2 m αb µ 2m 1exp 4 3 2 m αb µ 1+ 2m+ 1 exp + 1 αb 3 3 m 3 S 3 2 ms µ 1+ 2m+ 1 exp 1 ( 2hBmkT ) ( 2hBmkT ) ( 2hBm kt ) 2m+ 1 + C exp 1 2m 1 2m 1 + C exp 2m+ 1 r 1 ( hbm kt ) ( hbm kt ) Radiation temp. (dust) T r = 40 K Kinetic (collisional) temp. (H 2 ) T k = 2.73 K Oka s Collisional Coefficient C = 10E-7 Rotational Constant B = 1454 MHz Permanent Dipole Moment µ = 3.1 D 2015/2/20 30 1 1 1 r 2m+ 1 + C exp 1 2m 1 2m 1 + C exp r 1 2m+ 1 ( hbmkt ) k ( hbmkt ) k k k

What parameters are determining the rotational profile? With a hot axis or not. With a permanent dipole moment or not. Radiation temperature T r Kinetic temperature T k C constant Permanent dipole moment Rotational constants Rotational constants difference Lifetime 2015/2/20 31