PHASE CHANGE AND ABLATION STUDY OF METALS BY FEMTOSECOND LASER IRRADIATION USING HYBRID TTM/MD SIMULATIONS

Weirong Yuan (10726149)

30 April 2021

<div>The interactions of femtosecond lasers with gold targets were investigated with a numerical method combining molecular dynamics (MD) and the two-temperature model (TTM). Previous works using MD-TTM method did not consider all the thermodynamic parameters and the interatomic potential dependent of the electron temperature simultaneously. Therefore, we developed a LAMMPS function to achieve this. To accurately capture the physics behind the interactions, we also included the electron blast force from free electron pressure and the modified Fourier law with steep electron temperature gradient in our model. For bulk materials, a stress non-reflecting and heat conducting boundary is added between the atomistic and the continuum parts. The modified boundary force in our study greatly reduces the reflectivity of the atomistic-continuum boundary compared with its original form. Our model is the first to consider all these factors simultaneously and manage to predict four femtosecond laser ablation phenomena observed in the experiments. </div><div><br></div><div>In this dissertation, the thermodynamic parameters in the two-temperature model were extensively explored. We considered three different approaches to calculate these parameters: namely interpolation, <i>ab initio</i> calculation, and analytical expression. We found that simple interpolation between solid state and plasma state could lead to high level of inaccuracy, especially for electron thermal conductivity. Therefore, <i>ab initio</i> calculation and analytical expression were used for the calculation of the thermodynamic parameters in more advanced studies. The effects of electron thermal conductivity and electron-phonon coupling factor on electron and lattice temperatures were analyzed.</div><div><br></div><div>Our studies considered electron temperature dependent (ETD) and electron temperature independent (ETI) interatomic potentials. The ETI interatomic potential is easier to implement and therefore it is used in our phase change study to investigate the effects of target thickness on melting. Homogeneous melting occurred for thin films, while melting can be observed through the movement of the solid-liquid interface in thick or bulk materials. However, the ETI potential overestimated the bond strength at high temperatures. Therefore, ablation process was studied with the ETD potential. Three ablation mechanisms were found in our simulations at different laser fluences. Short nonthermal ablation was only observed at the ablation threshold. With increasing laser fluence, spallation was then seen. In high laser fluence regime, phase explosion occurred on the surface and coexisted with spallation.</div><div><br></div><div>Lastly, we researched on the effects of the delay time between two femtosecond laser pulses. Various delay times did not have much influence on melting depth. In low laser fluence regime, with increasing delay time, the target went through nonthermal ablation, to spallation and to no ablation. In high laser fluence regime, longer delay time encouraged phase explosion while suppressed spallation.</div>

Mechanical Engineering

Applied Physics

Computational Physics

Condensed Matter Physics

Plasma Physics

Metals and Alloy Materials

Atomic and Molecular Physics

Thermodynamics and Statistical Physics

Lasers and Quantum Electronics

Femtosecond laser

Metal

Ablation

Molecular dynamics

Two-temperature model

Phase change

Spectroscopie EUV résolue temporellement à l'échelle femtoseconde par imagerie de vecteur vitesse et génération d'harmoniques d'ordres élevés

Handschin, Charles

01 July 2013

Cette thèse fait l'étude expérimentale de dynamiques de relaxations ultrarapides au sein d'atomes et de molécules (Ar, NO2, C2H2). Les méthodes expérimentales qui sont utilisées sont basées sur l'interaction d'un rayonnement laser avec le système atomique ou moléculaire étudié et font intervenir le processus de génération d'harmoniques d'ordres élevés, ainsi que la spectrométrie d'imagerie de vecteur vitesse. Au cours de cette thèse, deux approchesexpérimentales de type pompe-sonde ont été mises en œuvre. Une première approche exploitela sensibilité du processus de génération d'harmoniques à la structure électronique dumilieu pour la sonder. Cette méthode a été utilisée sur la molécule de dioxyde d'azote pourobserver sa relaxation électronique à travers l'intersection conique des états X2A1-A2B2suite à une excitation autour de 400 nm. Une seconde approche utilise le rayonnementharmonique comme source de photons dans le domaine de l'extrême ultraviolet (EUV)pour exciter ou sonder les espèces d'intérêt. Cette approche a été couplée avec l'utilisationd'un spectromètre d'imagerie de vecteur vitesse (VMIS), qui a été développé durant lathèse. Des expériences menées sur un système modèle comme l'argon ont permis de validerle dispositif expérimental, qui a ensuite été mis en application pour étudier la photodissociationde la molécule d'acétylène, après excitation autour de 9,3 eV du complexe deRydberg 3d-4s. Les deux méthodes mises en œuvre permettent toutes-deux de réaliserdes études dynamiques résolues en temps à l'échelle femtoseconde. / Ultrafast atomic and molecular dynamics (Ar, NO2, C2H2) have been experimentally studied during this PhD. The employed techniques use the laser interaction with the atomic or molecular system produced in gas phase. High harmonic generation (HHG) pump-probe studies allow resolving dynamics on a femtosecond scale. Two applications of high harmonic generation have been implemented here. In the first one, the harmonic generation process is the probe of a vibronic relaxation induced by a pump pulse. This application is currently labeled high harmonic spectroscopy. The sensibility of the high harmonic process to the geometry of the atomic or molecular orbitals is exploited to obtain information about the electronic structure of the generating medium. This method have been used to reveal the electronic relaxation of the nitrogen dioxide molecule (NO2) through the X2A1-A2B2 conical intersection.A second way consists to use the harmonic radiation like a source of XUV photons. The produced XUV radiation permits thus to reach electronically excited energy levels of atoms or molecules, pumping only with a one photon transition. XUV photons can also be used like a probe to ionize products of a molecular reaction. Velocity map imaging spectrometer (VMIS) have been designed and built to complete this fs-VUV source. Above threshold ionization (ATI) experiments and pump-probe XUV-400 nm studies have been performed on reference system like Argon to characterize the built experimental setup. The last excitation scheme has been also applied to study the photodissociation of the Acetylene excited in the 3d-4s Rydberg complex.

Spectroscopie harmonique/VUV-fs

Physique atomique et moléculaire

Dynamique femtoseconde moléculaire

Relaxation électronique

Expériences type pompe-sonde

Imagerie de vecteur vitesse

Photodissociation

Intersection conique

Lentille électrostatique

Dioxyde d'azote

Acétylène

High harmonic generation

Harmonic spectroscopy

Atomic and molecular physics

Femtosecond molecular dynamics

Electronic relaxation

Pump-probe experiments

Velocity map imaging

Mass/photoelectron spectrometry

Photodissociation

Conical intersection

Electrostatic lense

Nitrogen dioxide

Acetylene