Transport of hot carriers in plasmonic nanostructures

Jermyn, Adam S.; Tagliabue, Giulia; Atwater, Harry A.; Goddard, William A.; Narang, Prineha; Sundararaman, Ravishankar

doi:10.1103/physrevmaterials.3.075201

Cited by 42 publications

(40 citation statements)

References 66 publications

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“…18 ). It indicates that the hot holes with higher energy could only be collected within a shorter distance, agreeing with the reported simulation result due to the shorter mean free path of hotter carriers 9 , 11 . At −0.6 V, the energy barrier is only about 0.1 eV lower than the excitation laser energy (1.96 eV).…”

Section: Resultssupporting

confidence: 91%

“…After generation in the nanoscale localized and strongly enhanced plasmonic electric field, the hot carriers can only travel a few tens of nanometers before they lose their energy by thermalization via the electron–electron scattering and electron–phonon scattering, which has been revealed by the theoretical calculation 9 , 10 . The consequent spatial distribution of the hot carriers may determine the active area on the surface, which is crucial to efficiently capture the hot carriers for achieving highly efficient SP-based catalysts or optoelectronic devices 5 , 9 , 11 . Recently, the spatial distribution of hot carriers has been visualized via ex situ scanning electron microscope or florescence imaging of the reaction or stained products of the hot carriers-induced reaction 11 – 14 .…”

Section: Introductionmentioning

confidence: 99%

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Probing nanoscale spatial distribution of plasmonically excited hot carriers

et al. 2020

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Surface plasmons (SPs) of metals enable the tight focusing and strong absorption of light to realize an efficient utilization of photons at nanoscale. In particular, the SP-generated hot carriers have emerged as a promising way to efficiently drive photochemical and photoelectric processes under moderate conditions. In situ measuring of the transport process and spatial distribution of hot carriers in real space is crucial to efficiently capture the hot carriers. Here, we use electrochemical tip-enhanced Raman spectroscopy (EC-TERS) to in situ monitor an SP-driven decarboxylation and resolve the spatial distribution of hot carriers with a nanometer spatial resolution. The transport distance of about 20 nm for the reactive hot carriers is obtained from the TERS imaging result. The hot carriers with a higher energy have a shorter transport distance. These conclusions can be guides for the design and arrangement of reactants and devices to efficiently make use of plasmonic hot carriers.

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Section: Resultssupporting

confidence: 91%

Section: Introductionmentioning

confidence: 99%

Probing nanoscale spatial distribution of plasmonically excited hot carriers

et al. 2020

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“…33,42,43 Jermyn et al for example, have recently reported the results of models for the energetic and spatial distributions of hot electrons in Au nanorods that are in excellent agreement with HSQ exposures observed in this work. 43 In this work, we coarsely estimate the energy of hot electrons generated in the nanoantennas by calculating resistive losses and assuming that on the timescale of the laser pulse all power dissipated by resistive loss is carried 6 by conduction electrons in Au. Based on these assumptions and approximations, we hypothesize that hot electrons 1.5 eV above the Fermi level of Au may have sufficient energy to initiate the dissociation of water, which subsequently drives hydrolysis and crosslinking of HSQ.…”

supporting

confidence: 86%

“…The recent report by Jermyn et al shows that the distribution of hot carriers is expected to peak at the center of nanorod antennas. 43 These hot electrons may carry sufficient energy to dissociate species on the Au surface via mechanisms such as dissociative electron attachment. 59,60 Dissociation of water due to hot electrons could play an important role in the crosslinking of HSQ, as water dissociation products would support the hydrolysis of silane groups in HSQ.…”

Section: Figures 2a and 2bmentioning

confidence: 99%

Mapping Photoemission and Hot-Electron Emission from Plasmonic Nanoantennas

et al. 2017

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Understanding plasmon-mediated electron emission and energy transfer on the nanometer length scale is critical to controlling light-matter interactions at nanoscale dimensions. In a high-resolution lithographic material, electron emission and energy transfer lead to chemical transformations. In this work, we employ such chemical transformations in two different high-resolution electron-beam lithography resists, poly(methyl methacrylate) (PMMA) and hydrogen silsesquioxane (HSQ), to map local electron emission and energy transfer with nanometer resolution from plasmonic nanoantennas excited by femtosecond laser pulses. We observe exposure of the electron-beam resists (both PMMA and HSQ) in regions on the surface of nanoantennas where the local field is significantly enhanced. Exposure in these regions is consistent with previously reported optical-field-controlled electron emission from plasmonic hotspots as well as earlier work on low-electron-energy scanning probe lithography. For HSQ, in addition to exposure in hotspots, we observe resist exposure at the centers of rod-shaped nanoantennas in addition to exposure in plasmonic hotspots. Optical field enhancement is minimized at the center of nanorods suggesting that exposure in these regions involves a different mechanism to that in plasmonic hotspots. Our simulations suggest that exposure at the center of nanorods results from the emission of hot electrons produced via plasmon decay in the nanorods. Overall, the results presented in this work provide a means to map both optical-field-controlled electron emission and hot-electron transfer from nanoparticles via chemical transformations produced locally in lithographic materials.

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“…The reduced dimensions of the heteronanostructures minimize the probability of undergoing another relaxation/recombination process [68]. While the injection of hot electrons (using n-type semiconductors such as TiO 2 ) is the most accepted plasmon-driven charge transfer mechanism, there exist recent interesting studies claiming the importance of hot holes in other plasmonic-based systems [73,86,92,97,134,135,136,137] such as Au-NiO x , Au-pGaN [73], Au nanorods coated with a CoO nanoshell [138], Au nanostructures [101,139,140], or Ag-BiOCl hybrids [86,137].…”

Section: Discussionmentioning

confidence: 99%

Silver-Copper Oxide Heteronanostructures for the Plasmonic-Enhanced Photocatalytic Oxidation of N-Hexane in the Visible-NIR Range

et al. 2019

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Volatile organic compounds (VOCs) are recognized as hazardous contributors to air pollution, precursors of multiple secondary byproducts, troposphere aerosols, and recognized contributors to respiratory and cancer-related issues in highly populated areas. Moreover, VOCs present in indoor environments represent a challenging issue that need to be addressed due to its increasing presence in nowadays society. Catalytic oxidation by noble metals represents the most effective but costly solution. The use of photocatalytic oxidation has become one of the most explored alternatives given the green and sustainable advantages of using solar light or low-consumption light emitting devices. Herein, we have tried to address the shortcomings of the most studied photocatalytic systems based on titania (TiO2) with limited response in the UV-range or alternatively the high recombination rates detected in other transition metal-based oxide systems. We have developed a silver-copper oxide heteronanostructure able to combine the plasmonic-enhanced properties of Ag nanostructures with the visible-light driven photoresponse of CuO nanoarchitectures. The entangled Ag-CuO heteronanostructure exhibits a broad absorption towards the visible-near infrared (NIR) range and achieves total photo-oxidation of n-hexane under irradiation with different light-emitting diodes (LEDs) specific wavelengths at temperatures below 180 °C and outperforming its thermal catalytic response or its silver-free CuO illuminated counterpart.

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Transport of hot carriers in plasmonic nanostructures

Cited by 42 publications

References 66 publications

Probing nanoscale spatial distribution of plasmonically excited hot carriers

Probing nanoscale spatial distribution of plasmonically excited hot carriers

Mapping Photoemission and Hot-Electron Emission from Plasmonic Nanoantennas

Silver-Copper Oxide Heteronanostructures for the Plasmonic-Enhanced Photocatalytic Oxidation of N-Hexane in the Visible-NIR Range

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