The influence of thermal confinement and temperature-dependent absorption on resonant infrared ablation of frozen aqueous and alcohol targets

The mechanism of matrix-assisted resonant infrared laser ablation of frozen aqueous and methanol solutions of polymer was investigated by performing plume shadowgraphy and ablation yield measurements. A picosecond, tunable free-electron laser was tuned to two wavelengths in the target matrices, one (2940 nm) that was resonant with the -OH stretch in both water and methanol, and the other (3450 nm) that is resonant with the -CH stretch in methanol. The plume images showed gross similarities, differing only in the time required for the shockwave to appear and in the velocity of the shock front. Typically, 15-25 mus after the ablation laser pulse arrives the primary material ejection commences and lasts for hundreds of mus. In all three cases, the ablation plume appears to consist entirely of vapor with no droplets or solid particles. The ablation yield is either linear or quadratic in fluence. This dependence can be understood if we consider thermal diffusion in the targets and the temperature dependence of the absorption coefficient.