2006
DOI: 10.1021/jp060179l
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Hot Adsorbate-Induced Retardation of the Internal Thermalization of Nonequilibrium Electrons in Adsorbate-Covered Metal Nanoparticles

Abstract: Femtosecond transient absorption spectroscopy has been used to investigate the electron-electron scattering dynamics in sulfate-covered gold nanoparticles of 2.5 and 9.2 nm in diameter. We observe an unexpected retardation of the absolute internal thermalization time compared to bulk gold, which is attributed to a negative feedback by the vibrationally excited sulfate molecules. These hot adsorbates, acting as a transient energy reservoir, result from the back and forth inelastic scattering of metal nonequilib… Show more

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Cited by 27 publications
(39 citation statements)
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“…1, red solid line), a result that is consistent with previous reports (28)(29)(30). Within the theory of UCIS, an increased line width of the LSP absorbance after ligand exchange is expected due to dephasing of the plasmonic electrons as they transiently tunnel in and out of interfacial orbitals with metal and ligand character (17,19,20); however, this interfacial scattering processes is one of several possible contributions to the line width of the LSP (28). Inhomogeneous broadening due to polydispersity in size and shape is probably not a dominant factor in this line width.…”
Section: Resultssupporting
confidence: 88%
See 1 more Smart Citation
“…1, red solid line), a result that is consistent with previous reports (28)(29)(30). Within the theory of UCIS, an increased line width of the LSP absorbance after ligand exchange is expected due to dephasing of the plasmonic electrons as they transiently tunnel in and out of interfacial orbitals with metal and ligand character (17,19,20); however, this interfacial scattering processes is one of several possible contributions to the line width of the LSP (28). Inhomogeneous broadening due to polydispersity in size and shape is probably not a dominant factor in this line width.…”
Section: Resultssupporting
confidence: 88%
“…Recently, Bauer and coworkers have described a phenomenological model in which the interface between the Au NP and an organic adlayer changes the rate at which plasmonic electrons equilibrate to form a thermal distribution by providing pathways for redistribution of the hot electrons' kinetic energy. The authors adopt the name "ultrafast chemical interface scattering (UCIS)" for this mechanism, as it is consistent with chemistryinduced localized surface plasmon (LSP) damping that has long been observed in small NPs in the colloid field (17)(18)(19)(20).…”
mentioning
confidence: 71%
“…41 The FWHM depends on many factors, such as the size of nanoparticles, polydispersity in size and shape and chemical bonding between the nanoparticles and ligand. 41 Although the ligand exchange can diphase the oscillations of the plasmonic electrons by adding an additional decay channel due to the transient in and out tunneling in interfacial orbitals with the NP and ligand, [77][78][79] the size of the NPs plays a dominant role in plasmonic damping (See Figure 3). As demonstrated in the Figure 3 and Figure S3, the FWHM of the smaller samples (Au279 (TBBT), Au329 (SC2Ph) and Au329 (SC6)) at a delay time of 0.5 ps were determined to be ~ 92 nm, which decreases with further increasing the size of the samples and reaches to ~ 53 nm for 13 nm-Au.…”
Section: Ultrafast Transient Absorption Measurementsmentioning
confidence: 99%
“…[152] Moreover, experimental evidence shows that CID by adsorbates is able to retard the thermalization process of hot charge carriers (picosecond regime) by the repeated back and forth transfer of hot electrons between the metal and the adsorbates. [165] Some factors need to be taken into account in order to increase efficiency by CID. [166] In contrast to the indirect transfer mechanism, the direct electron transfer requires not only an orbital overlap, but also strong hybridization between the metallic nanoparticle surface and the adsorbate.…”
Section: Hot Charge Carrier Generation and Transfermentioning
confidence: 99%