Your search keyword '"Genieys, T"' showing total 7 results

1. Unravelling ultrashort laser excitation of nickel at 800 nm wavelength

Author

Genieys, T, Petrakakis, M, Tsibidis, G, Sentis, M, and Utéza, O

Subjects

Physics - Optics

Abstract

The optical response of nickel is studied in a wide range of laser fluence, below and above the ablation threshold, by selfreflectivity measurements of ultrashort 800nm single laser pulses. At the ablation threshold, the reflectivity remains unchanged with respect to its unperturbed value irrespective of the pulse duration, from 15 to 100 fs, consistently with the steadiness of the laser-induced ablation threshold fluence Fth for all pulse durations tested. Until the ablation threshold ($F\le F_{th}$) and whatever the pulse duration, the disturbances caused to the initial structure of the electron gas distribution by the laser energy deposition are limited, having no significant impact on the transient optical response of nickel and on its ablation threshold. At higher laser fluences ($F> F_{th}$), the reflectivity becomes rapidly dominated by the contribution to the optical response of the fast-thermalized free electrons (4s-band) with energy largely above the Fermi energy level. In these conditions, the reflectivity decreases for all pulse durations enhancing laser energy coupling and larger optical absorption at the surface of nickel. The optical response of nickel under ultrashort (15-100 fs) irradiation is thus fully elucidated on a wide range of fluence (0.3 $F_{th}$ - 30 $F_{th}$) and for pulse duration down to few-optical-cycle pulse duration. As a key parameter for benchmarking laser-matter interaction in poorly known conditions yet, the evolution of the effective electron collision rate is determined as a function of fluence and pulse duration in very good consistency with experiments.

Published

2021

2. Investigation of ultrashort laser excitation of aluminum and tungsten by reflectivity measurements

Author

Genieys, T., Sentis, M., and Utéza, O.

Subjects

Physics - Optics, Condensed Matter - Materials Science

Abstract

We determine the laser-induced ablation threshold fluence in air of aluminum and tungsten excited by single near-infrared laser pulses with duration ranging from 15 fs to 100 fs. The ablation threshold fluence is shown constant for both metals, extending the corresponding scaling metrics to few-optical-cycle laser pulses. Meanwhile, the reflectivity is measured providing access to the deposited energy in the studied materials on a wide range of pulse durations and incident fluences below and above the ablation threshold. A simulation approach, based on the two-temperature model and the Drude-Lorentz model, is developed to describe the evolution of the transient thermodynamic and optical characteristics of the solids (lattice and electronic temperatures, reflectivity) following laser excitation. The confrontation between experimental results and simulations highlights the importance of considering a detailed description and evolution of the density of states in transition metals like tungsten.

Published

2020

3. Electron collision rate in ultrashort laser-metal interaction inferred from reflectivity measurements

Author

Genieys, T, Sentis, M, Utéza, O, Laboratoire Lasers, Plasmas et Procédés photoniques (LP3), Centre National de la Recherche Scientifique (CNRS)-Aix Marseille Université (AMU), and Aix Marseille Université (AMU)-Centre National de la Recherche Scientifique (CNRS)

Subjects

[PHYS.PHYS.PHYS-OPTICS]Physics [physics]/Physics [physics]/Optics [physics.optics], laser-induced ablation threshold, effective electron collision rate, reflectivity, metals, Ultrashort laser, optical laser coupling

Abstract

International audience; We study optical laser coupling of four metals (aluminum, copper, nickel and tungsten) upon single ultrashort 30-fs laser irradiation. Using dedicated experimental methodology, we carefully monitor the evolution of the material reflectivity integrated over the femtosecond pulse duration. We further apply the Drude-Lorentz formalism to infer the evolution of the effective electron collision rate eff as a function of applied fluence. The knowledge of this parameter is of paramount importance in any lasermatter interaction situation because of its immediate impact on laser energy coupling in material and on its subsequent macroscopic transformation.

Published

2021

4. Unravelling ultrashort laser excitation of nickel at 800 nm wavelength

Author

Genieys, T, primary, Petrakakis, M N, additional, Tsibidis, G D, additional, Sentis, M, additional, and Utéza, O, additional

Published

2021

5. Investigation of ultrashort laser excitation of aluminum and tungsten by reflectivity measurements

Author

Genieys, T., primary, Sentis, M., additional, and Utéza, O., additional

Published

2020

6. Electron Collision Rate in Ultrashort Laser - Metal Interaction Inferred from Reflectivity Measurements.

Author

Genieys, T., Sentis, M., and Utéza, O.

Subjects

ULTRASHORT laser pulses, COLLISIONS (Nuclear physics), LASERS, FEMTOSECOND pulses, METALS, LASER ablation

Abstract

We study optical laser coupling of four metals (aluminum, copper, nickel and tungsten) upon single ultrashort 30-fs laser irradiation. Using dedicated experimental methodology, we carefully monitor the evolution of the material reflectivity integrated over the femtosecond pulse duration. We further apply the Drude-Lorentz formalism to infer the evolution of the effective electron collision rate νeff as a function of applied fluence. The knowledge of this parameter is of paramount importance in any laser - matter interaction situation because of its immediate impact on laser energy coupling in material and on its subsequent macroscopic transformation. [ABSTRACT FROM AUTHOR]

Published

2021

7. Experimental and Theoretical Study of Ultrashort Laser Excitation of Nickel

Author

Genieys, T., primary, Petrakakis, M. N., additional, Tsibidis, G., additional, Sentis, M., additional, and Uteza, O., additional

Published

2019