First-principles electron dynamics control simulation of diamond under femtosecond laser pulse train irradiation

Cong Wang; Lan Jiang; Feng Wang; Xin Li; Yanping Yuan; Hai Xiao; Hai Lung Tsai; Yongfeng Lu

doi:10.1088/0953-8984/24/27/275801

First-principles electron dynamics control simulation of diamond under femtosecond laser pulse train irradiation

Cong Wang^*, Lan Jiang, Feng Wang, Xin Li, Yanping Yuan, Hai Xiao, Hai Lung Tsai, Yongfeng Lu

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

33 Citations (Scopus)

Abstract

A real-time and real-space time-dependent density functional is applied to simulate the nonlinear electronphoton interactions during shaped femtosecond laser pulse train ablation of diamond. Effects of the key pulse train parameters such as the pulse separation, spatial/temporal pulse energy distribution and pulse number per train on the electron excitation and energy absorption are discussed. The calculations show that photonelectron interactions and transient localized electron dynamics can be controlled including photon absorption, electron excitation, electron density, and free electron distribution by the ultrafast laser pulse train.

Original language	English
Article number	275801
Journal	Journal of Physics Condensed Matter
Volume	24
Issue number	27
DOIs	https://doi.org/10.1088/0953-8984/24/27/275801
Publication status	Published - 11 Jul 2012

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abstract = "A real-time and real-space time-dependent density functional is applied to simulate the nonlinear electronphoton interactions during shaped femtosecond laser pulse train ablation of diamond. Effects of the key pulse train parameters such as the pulse separation, spatial/temporal pulse energy distribution and pulse number per train on the electron excitation and energy absorption are discussed. The calculations show that photonelectron interactions and transient localized electron dynamics can be controlled including photon absorption, electron excitation, electron density, and free electron distribution by the ultrafast laser pulse train.",

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AU - Wang, Cong

AU - Jiang, Lan

AU - Wang, Feng

AU - Li, Xin

AU - Yuan, Yanping

AU - Xiao, Hai

AU - Tsai, Hai Lung

AU - Lu, Yongfeng

PY - 2012/7/11

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N2 - A real-time and real-space time-dependent density functional is applied to simulate the nonlinear electronphoton interactions during shaped femtosecond laser pulse train ablation of diamond. Effects of the key pulse train parameters such as the pulse separation, spatial/temporal pulse energy distribution and pulse number per train on the electron excitation and energy absorption are discussed. The calculations show that photonelectron interactions and transient localized electron dynamics can be controlled including photon absorption, electron excitation, electron density, and free electron distribution by the ultrafast laser pulse train.

AB - A real-time and real-space time-dependent density functional is applied to simulate the nonlinear electronphoton interactions during shaped femtosecond laser pulse train ablation of diamond. Effects of the key pulse train parameters such as the pulse separation, spatial/temporal pulse energy distribution and pulse number per train on the electron excitation and energy absorption are discussed. The calculations show that photonelectron interactions and transient localized electron dynamics can be controlled including photon absorption, electron excitation, electron density, and free electron distribution by the ultrafast laser pulse train.

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ER -

First-principles electron dynamics control simulation of diamond under femtosecond laser pulse train irradiation

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