HIGH RESOLUTION INFRARED SPECTRA OF TRIACETYLENE*

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Presentation transcript:

HIGH RESOLUTION INFRARED SPECTRA OF TRIACETYLENE* Kirstin D. Doney, Dongfeng Zhao, Harold Linnartz Sackler Laboratory for Astrophysics, Leiden Observatory, University of Leiden, the Netherlands *submitted to JMS Kirstin D. Doney - ISMS - 2015-06-25 1

HST Image of CRL 618.; Trammell et al. 2000 MOTIVATION - Triacetylene (HC6H) is believe to be key intermediate in formation of long chain hydrocarbons and possibly PAHs - Has been detected in space through v11 and v8+v11; but not everywhere where it’s expected - The vibrational information is limited Only 6/13 vibrational modes have been observed in detail Cernicharo et al., ApJL 546 (2001) L123 Cernicharo et al., ApJ 728 (2011) 43 Bernard-Salas et al., ApJL 625 (2006) L29 HST Image of CRL 618.; Trammell et al. 2000 Kirstin D. Doney - ISMS - 2015-06-25 2

Kirstin D. Doney - ISMS - 2015-06-25 MOTIVATION - Triacetylene (HC6H) is believe to be key intermediate in formation of long chain hydrocarbons and possibly PAHs - Has been detected in space through v11 and v8+v11; but not everywhere where it’s expected - The vibrational information is limited Only 6/13 vibrational modes have been observed in detail 3329.0533(1) Bjarnov et al. Spectrochim. Acta part A, 30 (1974) 1255 This work McNaughton & Bruget, JMS 150 (1991) 620 Haas et al., JMS 164 (1994) 445 Matsumura et al. JMS, 131 (1988) 278 Haas et al., JMS 167 (1994) 176 Kirstin D. Doney - ISMS - 2015-06-25 3

EXPERIMENTAL SETUP - SPIRAS - Combined supersonic pulsed planar plasma with cw-CRDS - Thin slit discharge nozzle Near Doppler-free line widths - 0.3% HC2H diluted in Ar with -525 V applied HV pulse - IR light source: idler beam of a continuous wave OPO: ~3100-4100 cm-1 Some advert for what we have done: plus ref. Zhao et al., Chem. Phys. L. 565 (2013) 132 Kirstin D. Doney - ISMS - 2015-06-25 4

OVERVIEW SPECTRUM HC6H HC4H - Trot = 23 K - Freq. uncert. = 0.001 cm-1 - Line widths = 0.003 cm- 1 HC6H HC4H Normalized Intensity / cm-1 Wavenumber (cm-1) Kirstin D. Doney - ISMS - 2015-06-25 5

D. Zhao, K.D. Doney, H. Linnartz, JMS, 296 (2014) 1 OVERVIEW SPECTRUM HC6H HC4H Normalized Intensity / cm-1 D. Zhao, K.D. Doney, H. Linnartz, JMS, 296 (2014) 1 Wavenumber (cm-1) Kirstin D. Doney - ISMS - 2015-06-25 6

OVERVIEW SPECTRUM HC6H HC4H - Trot = 23 K - Freq. uncert. = 0.001 cm-1 - Line widths = 0.003 cm- 1 HC6H HC4H Normalized Intensity / cm-1 Wavenumber (cm-1) Kirstin D. Doney - ISMS - 2015-06-25 7

K.D. Doney, D. Zhao, H. Linnartz, JMS (submitted) OVERVIEW SPECTRUM HC6H HC4H Normalized Intensity / cm-1 K.D. Doney, D. Zhao, H. Linnartz, JMS (submitted) Wavenumber (cm-1) Kirstin D. Doney - ISMS - 2015-06-25 8

C-H ASYMMETRIC FUNDAMENTAL + - ν5 mode (1Σg ) - Based on room-temperature data: Matsumura et al., JMS 158 (1993) 489 # Lines = 124 heavily perturbed at J’ = 21, 49, and 53 weaker perturbations at J’ < 10 and J’ > 100 Figure: experimental spectrum in black, simulated spectrum with PGOPHER in blue (cm-1) Kirstin D. Doney - ISMS - 2015-06-25 9

C-H ASYMMETRIC FUNDAMENTAL + - ν5 mode (1Σg ) - Based on room-temperature data: Matsumura et al., JMS 158 (1993) 489 # Lines = 124 heavily perturbed at J’ = 21, 49, and 53 weaker perturbations at J’ < 10 and J’ > 100 Figure: experimental spectrum in black, simulated spectrum in blue, R(15) – R(27) (cm-1) Kirstin D. Doney - ISMS - 2015-06-25 10

PERTURBER STATE - CORIOLIS INTERACTION - Nature of Perturbation: Heterogeneous (L-uncoupling) Σu (ν5) + Πu (Perturber) Perturber state has an infrared intensity ~10% that of the v5 state - ζ = 6.86(5) x10-4 cm-1 # Lines = 65 to v5 and 14 to the Perturber state Figure: experimental spectrum in black, simulated v5 spectrum in blue, perturber in red + Image of portion with correction Rotational parameters of upper states Kirstin D. Doney - ISMS - 2015-06-25 11

PERTURBER STATE - CORIOLIS INTERACTION - Nature of Perturbation: Heterogeneous (L-uncoupling) Σu (ν5) + Πu (Perturber) Perturber state has an infrared intensity ~10% that of the v5 state ζ = 6.86(5) x10-4 cm-1 # Lines = 65 to v5 and 14 to the Perturber state Figure: experimental spectrum in black, v5 simulated spectrum in blue, R(15) – R(27), and perturber simulated spectrum in red, R(17) – R(25) + Image of portion with correction Rotational parameters of upper states Kirstin D. Doney - ISMS - 2015-06-25 12

w/ Coriolis Interaction THE FIT Matsumura et al., JMS 158 (1993) 489 (cm-1) w/ Coriolis Interaction Key: Perturber State ν5 State R branch lines P branch lines Obs-calc J’ 13 Kirstin D. Doney - ISMS - 2015-06-25

w/ Coriolis Interaction THE FIT Matsumura et al., JMS 158 (1993) 489 (cm-1) w/ Coriolis Interaction Key: Perturber State ν5 State R branch lines P branch lines Obs-calc J’ 14 Kirstin D. Doney - ISMS - 2015-06-25

PERTURBER STATE - FERMI RESONANCE - Nature of Perturbation: Homogeneous Σu (ν5) + Σu (Perturber) Perturber state has an infrared intensity ~10% that of the v5 state - W = 2.18(2) x10-2 cm-1 # Lines = 65 to v5 and 12 to the Perturber state Figure: experimental spectrum in black, simulated v5 spectrum in blue, perturber in red + + Kirstin D. Doney - ISMS - 2015-06-25 15

PERTURBER STATE - FERMI RESONANCE - Nature of Perturbation: Homogeneous Σu (ν5) + Σu (Perturber) Perturber state has an infrared intensity ~10% that of the v5 state - W = 2.18(2) x10-2 cm-1 # Lines = 65 to v5 and 12 to the Perturber state Figure: experimental spectrum in black, v5 simulated spectrum in blue, R(15) – R(27), and perturber simulated spectrum in red, R(16) – R(25) + + Kirstin D. Doney - ISMS - 2015-06-25 16

Kirstin D. Doney - ISMS - 2015-06-25 THE FIT Matsumura et al., JMS 158 (1993) 489 (cm-1) w/ Fermi Resonance Key: Perturber State ν5 State R branch lines P branch lines Obs-calc J’ 17 Kirstin D. Doney - ISMS - 2015-06-25

Kirstin D. Doney - ISMS - 2015-06-25 THE FIT Matsumura et al., JMS 158 (1993) 489 (cm-1) w/ Fermi Resonance Key: Perturber State ν5 State R branch lines P branch lines Obs-calc J’ 18 Kirstin D. Doney - ISMS - 2015-06-25

w/ Coriolis Interaction THE FITS Matsumura et al., JMS 158 (1993) 489 (cm-1) B0 = 0.0441727(27) cm-1 from v8 fundamental - Matsumura et al., JMS 131 (1988) 278; B0 = 0.04417223(15) cm-1 from average of v5; v6; v11; v8+v11 - McNaughton & Bruget, JMS 150 (1991) 620; B0 = 0.04417177(14) cm-1 from v13 fundamental - Haas et al., JMS 164 (1994) 445 w/ Coriolis Interaction w/ Fermi Resonance Key: Perturber State ν5 State R branch lines P branch lines Obs-calc Obs-calc J’ 19 Kirstin D. Doney - ISMS - 2015-06-25

Kirstin D. Doney - ISMS - 2015-06-25 HOT BANDS - Observed: 5 10 ; 5 11 ; 5 13 with band origins at 3328.5829(2) cm-1 (green); 3328.9994(2) cm-1 (red); and 3328.2137(2) cm-1 (blue) - All are Π – Π transitions - Due to internal CCC bending modes, and CCH bending mode - Tvib ~ 105 K Figure: experimental spectrum in black, simulated spectra are in colors 1 1 1 1 1 1 1 1 1 Kirstin D. Doney - ISMS - 2015-06-25 20

Kirstin D. Doney - ISMS - 2015-06-25 HOT BANDS - Observed: 5 10 ; 5 11 ; 5 13 with band origins at 3328.5829(2) cm-1 (green); 3328.9994(2) cm-1 (red); and 3328.2137(2) cm-1 (blue) - All are Π – Π transitions - Due to internal CCC bending modes, and CCH bending mode - Tvib ~ 105 K Figure: experimental spectrum in black, simulated spectra are in colors 1 1 1 1 1 1 1 1 1 Kirstin D. Doney - ISMS - 2015-06-25 21

Kirstin D. Doney - ISMS - 2015-06-25 COMBINATION BAND - Observed 1 8 11 with a band origin at 3310.8104(2) cm-1 - Π – Π transition - Due to two CCC bending modes and the CH symmetric stretch mode Figure: experimental spectrum in black, simulated spectrum in green 1 1 1 Kirstin D. Doney - ISMS - 2015-06-25 22

Kirstin D. Doney - ISMS - 2015-06-25 COMBINATION BAND - Observed 1 8 11 with a band origin at 3310.8104(2) cm-1 - Π – Π transition - Due to two CCC bending modes and the CH symmetric stretch mode Figure: experimental spectrum favoring HC6H in black, experimental spectrum favoring HC4H in red, simulated spectrum in green 1 1 1 Kirstin D. Doney - ISMS - 2015-06-25 23

Kirstin D. Doney - ISMS - 2015-06-25 NEW BAND PARAMETERS (cm-1) a b a c # Lines 34 59 9 68 a. Haas et al., JMS 167 (1994) 176 —> v11 fundamental b. McNaughton & Bruget, JMS 150 (1991) 620 —> 1110 1011 hot band c. Haas et al., JMS 164 (1994) 445 —> v13 fundamental Kirstin D. Doney - ISMS - 2015-06-25 24

Kirstin D. Doney - ISMS - 2015-06-25 SUMMARY - SPIRAS has high detection sensitivity and molecular selectivity - First observation of the perturber state of the ν5 fundamental band More perturbed compared to diacetylene, but unidentified - First observation of 5 10 , 5 11 , and 5 13 hot bands and 1 8 11 combination band Not as vibrationally excited as diacetylene in the discharge plasma 1 1 1 1 1 1 1 1 1 1 1 1 Kirstin D. Doney - ISMS - 2015-06-25 25

Kirstin D. Doney - ISMS - 2015-06-25 ACKNOWLEDGEMENTS Prof. dr. Harold Linnartz Dr. Dongfeng Zhao The Sackler Lab Group Financial Support: NWO Leiden University Fund (LUF) NOVA Kirstin D. Doney - ISMS - 2015-06-25 26

PERTURBER STATE - COMPARISON w/ Coriolis Interaction – P Branch R Branch Image of portion with correction Rotational parameters of upper states w/ Fermi Resonance – P Branch R Branch Kirstin D. Doney - ISMS - 2015-06-25 27

w/ Coriolis Interaction THE FITS Matsumura et al., JMS 158 (1993) 489 w/ Coriolis Interaction w/ Fermi Resonance Key: Perturber State ν5 State R branch lines P branch lines Obs-calc Kirstin D. Doney - ISMS - 2015-06-25 28

w/ Coriolis Interaction THE FITS Matsumura et al., JMS 158 (1993) 489 w/ Coriolis Interaction w/ Fermi Resonance Key: Perturber State ν5 State R branch lines P branch lines Obs-calc Obs-calc Kirstin D. Doney - ISMS - 2015-06-25 29