Plasmon-driven sub-picosecond breathing of metal nanoparticles

Franco P. Bonafé; Bálint Aradi; Mengxue Guan; Oscar A. Douglas-Gallardo; Chao Lian; Sheng Meng; Thomas Frauenheim; Cristián G. Sánchez

doi:10.1039/c7nr04536k

Plasmon-driven sub-picosecond breathing of metal nanoparticles

Franco P. Bonafé, Bálint Aradi, Mengxue Guan, Oscar A. Douglas-Gallardo, Chao Lian, Sheng Meng, Thomas Frauenheim, Cristián G. Sánchez^*

^*Corresponding author for this work

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

31 Citations (Scopus)

Abstract

We present the first real-time atomistic simulation on the quantum dynamics of icosahedral silver nanoparticles under strong laser pulses, using time dependent density functional theory (TDDFT) molecular dynamics. We identify the emergence of sub-picosecond breathing-like radial oscillations starting immediately after laser pulse excitation, with increasing amplitude as the field intensity increases. The ultrafast dynamic response of nanoparticles to laser excitation points to a new mechanism other than equilibrium electron-phonon scattering previously assumed, which takes a much longer timescale. A sharp weakening of all bonds during laser excitation is observed, thanks to plasmon damping into excited electrons in anti-bonding states. This sudden weakening of bonds leads to a uniform expansion of the nanoparticles and launches coherent breathing oscillations.

Original language	English
Pages (from-to)	12391-12397
Number of pages	7
Journal	Nanoscale
Volume	9
Issue number	34
DOIs	https://doi.org/10.1039/c7nr04536k
Publication status	Published - 14 Sept 2017
Externally published	Yes

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title = "Plasmon-driven sub-picosecond breathing of metal nanoparticles",

abstract = "We present the first real-time atomistic simulation on the quantum dynamics of icosahedral silver nanoparticles under strong laser pulses, using time dependent density functional theory (TDDFT) molecular dynamics. We identify the emergence of sub-picosecond breathing-like radial oscillations starting immediately after laser pulse excitation, with increasing amplitude as the field intensity increases. The ultrafast dynamic response of nanoparticles to laser excitation points to a new mechanism other than equilibrium electron-phonon scattering previously assumed, which takes a much longer timescale. A sharp weakening of all bonds during laser excitation is observed, thanks to plasmon damping into excited electrons in anti-bonding states. This sudden weakening of bonds leads to a uniform expansion of the nanoparticles and launches coherent breathing oscillations.",

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AU - Bonafé, Franco P.

AU - Aradi, Bálint

AU - Guan, Mengxue

AU - Douglas-Gallardo, Oscar A.

AU - Lian, Chao

AU - Meng, Sheng

AU - Frauenheim, Thomas

AU - Sánchez, Cristián G.

PY - 2017/9/14

Y1 - 2017/9/14

N2 - We present the first real-time atomistic simulation on the quantum dynamics of icosahedral silver nanoparticles under strong laser pulses, using time dependent density functional theory (TDDFT) molecular dynamics. We identify the emergence of sub-picosecond breathing-like radial oscillations starting immediately after laser pulse excitation, with increasing amplitude as the field intensity increases. The ultrafast dynamic response of nanoparticles to laser excitation points to a new mechanism other than equilibrium electron-phonon scattering previously assumed, which takes a much longer timescale. A sharp weakening of all bonds during laser excitation is observed, thanks to plasmon damping into excited electrons in anti-bonding states. This sudden weakening of bonds leads to a uniform expansion of the nanoparticles and launches coherent breathing oscillations.

AB - We present the first real-time atomistic simulation on the quantum dynamics of icosahedral silver nanoparticles under strong laser pulses, using time dependent density functional theory (TDDFT) molecular dynamics. We identify the emergence of sub-picosecond breathing-like radial oscillations starting immediately after laser pulse excitation, with increasing amplitude as the field intensity increases. The ultrafast dynamic response of nanoparticles to laser excitation points to a new mechanism other than equilibrium electron-phonon scattering previously assumed, which takes a much longer timescale. A sharp weakening of all bonds during laser excitation is observed, thanks to plasmon damping into excited electrons in anti-bonding states. This sudden weakening of bonds leads to a uniform expansion of the nanoparticles and launches coherent breathing oscillations.

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Plasmon-driven sub-picosecond breathing of metal nanoparticles

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