Electronic transitions of cobalt carbide, CoC, near 750 nm: A good example of case (bβS) hyperfine coupling

Abstract

The laser induced fluorescence spectrum of jet‐cooled CoC near 750 nm has been measured at high resolution following the reaction of laser‐ablated cobalt atoms with methane. The X²Σ⁺ ground state of CoC is an unusually good example of Hund’s case (b_βS) coupling. Since Co has a nuclear spin I=7/2, each rotational level is split by the Fermi contact interaction into G=3 and G=4 components, where G=I+S; the splitting for N=0 is more than 0.5 cm⁻¹. The X²Σ⁺ state begins to uncouple toward case (b_βJ) with increasing rotation. Transitions to various ²Π excited states occur in the region 13 000–14 500 cm⁻¹; the most prominent of these (for which high resolution spectra have been recorded) lie at 13 079 cm⁻¹ (²Π_3/2) and 13 343 cm⁻¹ (²Π_1/2). The (b_βS) coupling in the ground state produces some unexpected hyperfine intensity patterns, which have been studied in detail. A very low‐lying ²Δ_i state, whose Ω=5/2 and Ω=3/2 components lie at 221 and 1173 cm⁻¹, has been identified. Laser excitation of the ²Π_3/2–²Δ_5/2 transition has been observed by monitoring the strong ²Π_3/2–X²Σ⁺ emission, which has allowed the ²Δ_5/2 state to be characterized at high resolution. A total of 879 rotational‐hyperfine transitions between the various ²Π_1/2, ²Π_3/2, ²Δ_5/2, and ²Σ⁺ states have been assigned and fitted. Matrix elements for a ²Σ⁺ state in case (b_βS) coupling are listed.