Electron-phonon coupling dynamics in very small (between 2 and 8 nm diameter) Au nanoparticles

Hodak, José H.; Henglein, A.; Hartland, Gregory V.

doi:10.1063/1.481167

Cited by 207 publications

(275 citation statements)

References 39 publications

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“…This effect has been observed earlier and can be rationalized by the fact that the electronic heat capacity is also dependent on the initial electronic temperature rise [16,17]. Fig.…”

Section: Resultsmentioning

confidence: 78%

Role of adsorbates on dynamics of hot-electron (type I and II) thermalization within gold nanoparticles

Bauer

Abid

2005

Comptes Rendus. Chimie

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Early stages of hot-electron thermalization in small gold nanoparticles wrapped in an adsorbates shell have been investigated by femtosecond transient absorption spectroscopy. Type-I hot electrons thermalize in 800 fs (to form type-II hot electron) either by scattering with cold conduction band electrons or by chemical interface scattering with adsorbates shell. Type-II hot electrons redistribute the excess energy toward the lattice via electron-phonon coupling in 1.8-3.6 ps depending on pump fluence. The electron-phonon coupling process (type II hot electron) is retarded because of the incomplete internal thermalization of type-I hot electron at early times due to the presence of adsorbates. RésuméLes premiers événements relatifs à la thermalisation des électrons chauds dans des nanoparticules d'or enrobées dans une coquille d'adsorbats ont été étudiés par spectroscopie femtoseconde d'absorption transitoire. Les électrons chauds de type I se thermalisent en 1 ps (pour former les électrons chauds de type II), soit par diffusion avec les électrons froids de conduction, soit par diffusion interfaciale chimique dans la coquille d'adsorbats. Les électrons chauds de type II redistribuent l'énergie en excès en 1,6 à 3,6 ps en fonction de la puissance de pompe. Le processus de couplage électrons-phonon est retardé dans ce système en raison de la dépopulation incomplète des électrons de type I induite par la présence d'adsorbats durant les premiers temps. Pour citer cet article : C. Bauer et al., C. R. Chimie 9 (2006).

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“…This effect has been observed earlier and can be rationalized by the fact that the electronic heat capacity is also dependent on the initial electronic temperature rise [16,17]. Fig.…”

Section: Resultsmentioning

confidence: 78%

Role of adsorbates on dynamics of hot-electron (type I and II) thermalization within gold nanoparticles

Bauer

Abid

2005

Comptes Rendus. Chimie

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“…However, for the electron-phonon relaxation dynamics this is not observed experimentally. Using a theory developed by Belotskii et al (107), Hartland and coworkers (108) showed that the coupling constant between the electrons with acoustic and capillary modes of the surface phonons is determined by the ratio of the number of valence electrons in the atom to the atomic mass of the metal. Because of the small number of the valence electrons in gold (only one electron) combined with a large atomic mass, the contribution of electron-surface scattering to the overall electron-phonon scattering cross section is very small.…”

Section: Ultrafast Dynamics: Electron-phonon and Phonon-phonon Relaxamentioning

confidence: 99%

Optical Properties and Ultrafast Dynamics of Metallic Nanocrystals

Link¹,

El‐Sayed

2003

Annu. Rev. Phys. Chem.

1,518

1,499

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Noble metal particles have long fascinated scientists because of their intense color, which led to their application in stained glass windows as early as the Middle Ages. The recent resurrection of colloidal and cluster chemistry has brought about the strive for new materials that allow a bottoms-up approach of building improved and new devices with nanoparticles or artificial atoms. In this review, we discuss some of the properties of individual and some assembled metallic nanoparticles with a focus on their interaction with cw and pulsed laser light of different energies. The potential application of the plasmon resonance as sensors is discussed.

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“…24) On the other hand, the energy transfer in the nanoparticle also occurs thorough electron-surface interactions, which couple an acoustic surface mode and a capillary surface mode with electrons. 25,28,29) The acoustic and capillary mode coupling constants, g A and g C respectively, are given by 25) …”

Section: Resultsmentioning

confidence: 99%

“…The relaxation behavior in the nanoparticle can be expressed by the two-temperature model, which describes the energy exchange between the electrons and phonons in nanoparticles by the coupled equations. [22][23][24] In the limit of low pump power, where the change in lattice temperature can be neglected, time evolution of the electron temperature is given by 25,26) γ…”

Section: Resultsmentioning

confidence: 99%

Copper Nanoparticle Composites in Insulators by Negative Ion Implantation for Optical Application

et al. 2002

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Steady-state and laser-induced transient surface plasmon bands of copper nanoparticle composites, fabricated by ion implantation, were studied by optical measurements. Negative ion implantation has been applied to generate the Cu nanoparticles with a narrow distribution in amorphous SiO 2 , MgO2.4(Al 2 O 3 ) and LiNbO 3 with various refractive indices. The Cu nanoparticles were embedded within a depth of 100 nm by implantation of 60 keV Cu − . The surface plasmon band in steady-state absorption spectra resulted from formation of nanoparticles in the various substrates and shifted to red with increasing refractive index of the matrix. Transient absorption was measured with the technique of pump-probe femtosecond spectroscopy. The transient bleaching band also shifted in parallel with the steady-state plasmon resonance. The bleaching recovered in several picoseconds due to energy transfer from the excited electron system to the phonon system via the electron-phonon interaction. The electron-phonon coupling constant, g, of Cu nanoparticles in amorphous SiO 2 was obtained to be a value of 2.4×10 16 W/m 3 K.

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Electron-phonon coupling dynamics in very small (between 2 and 8 nm diameter) Au nanoparticles

Cited by 207 publications

References 39 publications

Role of adsorbates on dynamics of hot-electron (type I and II) thermalization within gold nanoparticles

Role of adsorbates on dynamics of hot-electron (type I and II) thermalization within gold nanoparticles

Optical Properties and Ultrafast Dynamics of Metallic Nanocrystals

Copper Nanoparticle Composites in Insulators by Negative Ion Implantation for Optical Application

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