The <i>e</i>Πg3 state of C2: A pathway to dissociation

Welsh, Blair; Krechkivska, Olha; Nauta, Klaas; Bacskay, George B.; Kable, Scott H.; Schmidt, Timothy W.

doi:10.1063/1.4985882

Cited by 13 publications

(24 citation statements)

References 43 publications

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“…A section of the spectrum of this band is shown in Fig. 2B; the assignments of the spectrum will be briefly discussed further below but essentially follow the assignments made previously (25). A larger portion of the (12 − 0) band is shown and briefly discussed in SI Appendix.…”

Section: Significancementioning

confidence: 67%

“…As opposed to our earlier work, where an electric discharge was used (25)(26)(27)(28)(29)(30)(31), C2 is here produced by photolysis of C2Cl4, roughly 1 mm in front of the orifice of the nozzle producing the molecular beam. This was done to minimize the production of carbon atoms at the molecular beam source (32).…”

Section: Resultsmentioning

confidence: 99%

“…In the course of revising the spectroscopy of the Fox-Herzberg system of C2 (e 3 Πg − a 3 Πu ), we determined that the v = 12 level was likely predissociated (25). Predissociation occurs when a bound level is above the lowest dissociation energy and accesses the continuum by nonadiabatic coupling, in this case to the isosymmetric d 3 Πg state.…”

Section: Comets | Dicarbon | Photodissociationmentioning

confidence: 99%

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Photodissociation of dicarbon: How nature breaks an unusual multiple bond

Borsovszky

Nauta

Jiang

et al. 2021

Proc. Natl. Acad. Sci. U.S.A.

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The dicarbon molecule (C2) is found in flames, comets, stars, and the diffuse interstellar medium. In comets, it is responsible for the green color of the coma, but it is not found in the tail. It has long been held to photodissociate in sunlight with a lifetime precluding observation in the tail, but the mechanism was not known. Here we directly observe photodissociation of C2. From the speed of the recoiling carbon atoms, a bond dissociation energy of 602.804(29) kJ·mol−1 is determined, with an uncertainty comparable to its more experimentally accessible N2 and O2 counterparts. The value is within 0.03 kJ·mol−1 of high-level quantum theory. This work shows that, to break the quadruple bond of C2 using sunlight, the molecule must absorb two photons and undergo two “forbidden” transitions.

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Section: Significancementioning

confidence: 67%

Section: Resultsmentioning

confidence: 99%

Section: Comets | Dicarbon | Photodissociationmentioning

confidence: 99%

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Photodissociation of dicarbon: How nature breaks an unusual multiple bond

Borsovszky

Nauta

Jiang

et al. 2021

Proc. Natl. Acad. Sci. U.S.A.

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“…With these new included data, every observed band has MARVEL-compiled rotationally-resolved data with two exceptions: the Kable-Schmidt (Nakajima et al 2009) e 3 Π g − c 3 Σ + u band around 40 000 cm −1 and the Messerle-Krauss (Messerle & Krauss 1967) C 1 Π g − A 1 Π u band around 30 000 cm −1 . Initial errors in the e state constants prohibited a good fit to the Kable-Schmidt band in 2009; new constants (Welsh et al 2017) obtained from better data in the Fox-Herzberg band allowed a much better fit of the e 3 Π g − c 3 Σ + u (4−3) band in that paper's supplementary information, although a full experimental assigned line list was not produced. In the case of the Messerle-Krauss band, recent unpublished investigations (Nauta & Schmidt 2020) suggests that the observed lines of the Messerle-Krauss band are actually part of the Deslandres-d'Azambuja (C 1 Π g − A 1 Π u ) band and that the true C 1 Π g is much higher in energy, as consistently predicted by ab initio theory.…”

Section: Discussionmentioning

confidence: 99%

“…However, two of these three new spinforbidden bands were inconsistent with the rest of the MARVEL compilation without uncertainties of around 2.4 cm −1 and were thus excluded; in contrast, 67 spin-forbidden transitions between the same two electronic states in 11BoSyKnGe (Bornhauser et al 2011) all validated with smaller uncertainties. 17WeKrNaBa (Welsh et al 2017) Rotationally cool experimental conditions enabled detailed study of low-J ultraviolet rovibronic transitions in the Fox-Herzberg (e 3 Π g − a 3 Π u ) band. No explicit uncertainty was provided in this paper; anestimated source uncertainty of 0.035 cm −1 was used, though this seems to be a slight underestimation based on the uncertainties MARVEL found.…”

Section: New Data Sources Pre-2016mentioning

confidence: 99%

An update to the MARVEL data set and ExoMol line list for 12C2

McKemmish

Syme

Borsovszky

et al. 2020

Monthly Notices of the Royal Astronomical Society

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The spectrum of dicarbon (C2) is important in astrophysics and for spectroscopic studies of plasmas and flames. The C2 spectrum is characterized by many band systems with new ones still being actively identified; astronomical observations involve eight of these bands. Recently, Furtenbacher et al. (2016, Astrophys. J. Suppl., 224, 44) presented a set of 5699 empirical energy levels for 12C2, distributed among 11 electronic states and 98 vibronic bands, derived from 42 experimental studies and obtained using the Marvel (Measured Active Rotational-Vibrational Energy Levels) procedure. Here, we add data from 13 new sources and update data from 5 sources. Many of these data sources characterize high-lying electronic states, including the newly detected 3 3Πg state. Older studies have been included following improvements in the Marvel procedure which allow their uncertainties to be estimated. These older works in particular determine levels in the C 1Πg state, the upper state of the insufficiently characterized Deslandres–d’Azambuja (C 1Πg–A 1Πu) band. The new compilation considers a total of 31 323 transitions and derives 7047 empirical (Marvel) energy levels spanning 20 electronic and 142 vibronic states. These new empirical energy levels are used here to update the 8states C2 ExoMol line list. This updated line list is highly suitable for high-resolution cross-correlation studies in astronomical spectroscopy of, for example, exoplanets, as 99.4% of the transitions with intensities over 10−18 cm molecule−1 at 1000 K have frequencies determined by empirical energy levels.

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