Time-of-Flight Mass Spectroscopy of Carbon Clusters and Hydrocarbons Produced by Laser Ablation of Graphite under H₂ and He Buffer Gas

—Formation and Stability of C₁₀ and C_2nH₂ (n =2–5)—

Abstract

The products from laser ablated graphite under the flow of H₂ and He buffer gases were analyzed by time-of-flight (TOF) mass spectroscopy in combination with one-photon ionization of an energy of 10.5 eV/photon. By changing the time interval between the ablation laser pulse and the photoionization laser pulse it was found that the neutral clusters ablated from the graphite have three distinctly different velocities for one and the same value of m/z, which was detected as three separate bunches of TOF mass peaks. The effect of changing the time interval was examined extensively. As a result, it was found that the first component that appeared earlier in the ionization region consisted of various bared carbon clusters C_n with n≥6 and hydrocarbons C_nH_m with n≥4 and m=1 through 4 while the second and third components that arrived later were C₁₀ and C_2nH₂ (n=2 through 5) only. This persistence of C₁₀ and C_2nH₂ at longer delay times was attributed to the robustness of these clusters against collisions occurring in ablated plumes. It was inferred that the robustness is due to the chemical inertness of a monocyclic form for C₁₀ and of a linear polyynic form, H(-C≡C)_n-H, for C_2nH₂. In the He buffer gas heated to 600 K the yield of the third (slowest) component of C₁₀ enhanced drastically, which indicates that thermal collisions in plumes favor the production of this monocycle, which further suggests that the monocycle may play a crucial role in the formation of C₆₀, known as a favored product in hot plumes of ablated graphite.