15min:

HANS-PETER LOOCK, BENOIT SIMARD, Steacie Institute for Molecular Sciences, National Research Council Canada, Ottawa, Ontario, K1A 0R6, Canada; COLAN LINTON, Physics Department, University of New Brunswick, P.O. Box 4400, Fredericton, New Brunswick, E3B 5A3, Canada.

The first spectroscopic identification and characterization of ytterbium monoacetylide (YbCCH) and two of its isotopomers is reported. By combining resonance enhanced two photon ionization (R2PI), laser induced fluorescence (LIF), and photoionization efficiency spectroscopy (PIE) with density functional calculations the X ²⁺ and the A ²_{1/2, 3/2} states of YbCCH and the X ¹⁺ state of YbCCH⁺ have been characterized.

The A ² - X ²⁺ system whose 0-0 band for the A ²_1/2 component lies at around 16848 cm^-1 for YbCCH (A_SO = 1411 cm^-1) has been studied at 0.3 cm^-1 resolution. The excitation spectra, both R2PI and fluorescence, are characterized by progressions and sequences involving the YbCC bending mode, ₅, whose wavenumber has been determined to be 93 cm^-1 and 103 cm^-1 for the X ²⁺ and the A ²_{1/2, 3/2} state, respectively. The dispersed fluorescence spectra show a progression in the ground state YbC stretching mode with a wavenumber of \omega(₃) = 328 cm^-1.

Density functional calculations confirmed the vibrational assignment and yielded a linear geometry for both the X- and A- state of YbCCH as well as for the X ¹⁺ state of the cation.

Photoionization efficiency spectroscopy yielded an adiabatic ionization potential of 47165(10) cm^-1 (5.8477 eV). Rydberg series converging to the v⁺ = 1 and v⁺ = 2 level of YbCCH⁺ were observed and combined with the ion-appearance potentials led to \omega(₅) = 97 cm^-1 for the YbCC bending mode in YbCCH⁺.

A high resolution study of the A ² - X ²⁺ system of YbCCH is currently in progress and results may be available at the time of the meeting.