Nonequilibrium Interface Dynamics:
Fundamental Physical Issues in Nonequilibrium Interface Dynamics

CSIC Building (#406), Seminar Room 4122.
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Laser Ablation and Deposition of Metals: Large-Scale Molecular Dynamics Simulations

Dr. George H. Gilmer

Lawrence Livermore National Laboratory

Abstract:   We have simulated short-pulse ablation of metals using continuum and molecular dynamics models, and performed experiments to examine ablated surface structures. The interaction of the light with the electrons and the subsequent equilibration of the electrons with the ions during the first picosecond are modeled using a one-dimensional continuum model. The molecular dynamics model then takes the output from the continuum, and follows the process for about 200 picoseconds, where the sudden heating of the metal atoms leads to a variety of morphologies. Our purpose is to investigate the mechanisms leading to the rough surfaces observed in the experiments, and to the ejection of micron-sized particles. A rich diversity of phenomena is observed as a function of the pulse energy density, including: (i) a low energy regime with a minute ablation flux corresponding to evaporation of atoms from the hot metal surface; (ii) an intermediate regime where void nucleation and growth, or spall, causes the ejection of a stable liquid layer and particles, and (iii) high pulse energies where liquid droplets are ejected with a wide range of sizes. Experimental observations of interference fringes during short-pulse ablation are in excellent agreement with our simulations that show the ejection of a liquid layer. We discuss some implications of the experiments and simulations for the laser machining of fine-scale surface features on metal objects. Pulsed laser deposition of thin films is discussed, using Monte Carlo models of thin film growth to help understand the effects of the ejected material on thin film structures. The simulations of the dynamics of short-pulse ablation are illustrated by mpeg movies.