A Spectroscopic Survey of Electronic Transitions of C6H, 13C6H, and C6D

Abstract

Electronic spectra of C6H are measured in the 18\,950-21\,100 cm-1 domain using cavity ring-down spectroscopy of a supersonically expanding hydrocarbon plasma. In total, 19 (sub)bands of C6H are presented, all probing the vibrational manifold of the B2 electronically excited state. The assignments are guided by electronic spectra available from matrix isolation work, isotopic substitution experiments (yielding also spectra for 13C6H and C6D), predictions from ab initio calculations as well as rotational fitting and vibrational contour simulations using the available ground state parameters as obtained from microwave experiments. Besides the 000 origin band, three non-degenerate stretching vibrations along the linear backbone of the C6H molecule are assigned: the 6 mode associated with the C-C bond vibration and the 4 and 3 modes associated with C triple bonds. For the two lowest 11 and 10 bending modes, a Renner-Teller analysis is performed identifying the μ2(11) and both μ2(10) and 2(10) components. In addition, two higher lying bending modes are observed, which are tentatively assigned as μ2(9) and μ2(8) levels. In the excitation region below the first non-degenerate vibration (6), some 2-2 transitions are observed that are assigned as even combination modes of low-lying bending vibrations. The same holds for a 2-2 transition found above the 6 level. From these spectroscopic data and the vibronic analysis a comprehensive energy level diagram for the B2 state of C6H is derived and presented.