论文信息 - Dynamics of ultrashort pulse-laser ablation: equation-of-state considerations

Dynamics of ultrashort pulse-laser ablation: equation-of-state considerations

Ultrafast time resolved microscopy of femtosecond laser irradiated surfaces reveals a universal feature of the ablating surface on nanosecond time scale. All investigated materials show rings in the ablation zone, which were identified as an interference pattern (Newton fringes). Optically sharp surfaces occur during expansion of the heated material as a result of anomalous hydrodynamic expansion effects. Experimentally, the rings are observed within a certain fluence range which strongly depends on material parameters. The lower limit of this fluence range is the ablation threshold. We predict a fluence ratio between the upper and the lower fluence limit approximately equal to the ratio of critical temperature to boiling temperature at normal pressure. This estimate is experimentally confirmed on different materials (Si, graphite, Au, Al).

Vassili Temnov | Klaus Sokolowski-Tinten | Dietrich von der Linde | Sergei I. Anisimov | Baerbel Rethfeld

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