Recent Progress and Prospects in Plasmon-Mediated Chemical Reaction

Zhan, Chao; Moskovits, Martin; Zhang, Tian

doi:10.1016/j.matt.2020.03.019

Cited by 71 publications

(60 citation statements)

References 77 publications

(116 reference statements)

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“…[ 63,64 ] These conduction electrons collectively behave as a coherent electron cloud, and LSPR occurs when incident light wave with frequencies matching the frequency of the electron cloud of the plasmonic metals. [ 61,63 ] The displacement of the electron cloud under the effect of the external field induces the creation of surface charges, negative where the electrons are concentrated and positive where there is a lack of electrons. [ 63 ] That is why LSPR is coined with “surface” effect, while LSPR actually results from the collective oscillation of all conduction electrons in the metallic nanostructure.…”

Section: Localized Surface Plasmon Resonance Of Cu Metalmentioning

confidence: 99%

“…A series of reviews have been published on the topic of plasmonic catalysis, mainly covering the aspects of synthetic methods, applications in catalysis, and mechanism study of plasmonic catalysis. [ 38–40,43,55–62 ] Nam et al. reported designing and synthetic approaches of multicomponent plasmonic nanoparticles (NPs) with new or improved plasmonic functionality.…”

Section: Introductionmentioning

confidence: 99%

“…[ 38,43,60 ] A recent review by Qiao and coworkers also focused on the investigation of operating mechanism of plasmon‐mediated chemical reaction. [ 61 ] In recent years, non‐noble‐based plasmonic catalysts have attracted increasing attention. [ 55,57,62 ] Nam's group systematically summarized the synthesis, plasmonic properties, and applications of non‐noble‐based plasmonic nanomaterials, including Cu, Al, Mg, In, Ga, Pb, Ni, Co, Fe, and related hybrids.…”

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Copper‐Based Plasmonic Catalysis: Recent Advances and Future Perspectives

et al. 2021

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With the capability of inducing intense electromagnetic field, energetic charge carriers, and photothermal effect, plasmonic metals provide a unique opportunity for efficient light utilization and chemical transformation. Earth‐abundant low‐cost Cu possesses intense and tunable localized surface plasmon resonance from ultraviolet‐visible to near infrared region. Moreover, Cu essentially exhibits remarkable catalytic performance toward various reactions owing to its intriguing physical and chemical properties. Coupling with light‐harvesting ability and catalytic function, plasmonic Cu serves as a promising platform for efficient light‐driven chemical reaction. Herein, recent advancements of Cu‐based plasmonic photocatalysis are systematically summarized, including designing and synthetic strategies for Cu‐based catalysts, plasmonic catalytic performance, and mechanistic understanding over Cu‐based plasmonic catalysts. What's more, approaches for the enhancement of light utilization efficiency and construction of active centers on Cu‐based plasmonic catalysts are highlighted and discussed in detail, such as morphology and size control, regulation of electronic structure, defect and strain engineering, etc. Remaining challenges and future perspectives for further development of Cu‐based plasmonic catalysis are also proposed.

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Section: Localized Surface Plasmon Resonance Of Cu Metalmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Copper‐Based Plasmonic Catalysis: Recent Advances and Future Perspectives

et al. 2021

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“…[ 1–7 ] These electrons can be transferred into the electronic states of molecules close to the surface of the plasmonic nanostructures, and thus induce chemical reactions which would otherwise be energetically demanding. [ 8–10 ] They can also be injected into the conduction band of a semiconductor for use in photovoltaics, [ 11–13 ] photodetectors, [ 14,15 ] and photoelectrochemical systems. [ 13,16 ]…”

Section: Introductionmentioning

confidence: 99%

“…[1][2][3][4][5][6][7] These electrons can be transferred into the electronic states of molecules close to the surface of the plasmonic nanostructures, and thus induce chemical reactions which would otherwise be energetically demanding. [8][9][10] They can also be injected into the conduction band of a semiconductor for use in photovoltaics, [11][12][13] photodetectors, [14,15] and photoelectrochemical systems. [13,16] Upon excitation, energetic electrons are produced in a nonthermal distribution, that is, the electron energies are skewed to high energies not describable by even a high temperature Fermi-Dirac distribution.…”

Section: Introductionmentioning

confidence: 99%

Disentangling the Temporal Dynamics of Nonthermal Electrons in Photoexcited Gold Nanostructures

O’Keeffe

Catone

Mario

et al. 2021

Laser & Photonics Reviews

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The study of nonthermal electrons, generated upon photoexcitation of plasmonic nanostructures, plays a key role in a variety of contexts, from photocatalysis and energy conversion to photodetection and nonlinear optics. Their ultrafast relaxation and subsequent release of energy to a low energy distribution of thermalized hot electrons has been the subject of a myriad of papers, mostly based on femtosecond transient absorption spectroscopy (FTAS). However, the FTAS signal stems from a complex interplay of different contributions arising from both nonthermal and thermal electrons, making the disentanglement of the two a very challenging task, so far accomplished only in terms of numerical simulations. Here a combined approach is introduced, based on a post-processing of the FTAS measurements guided by a reduced semiclassical model, the so-called extended two-temperature model, which has allowed the purely nonthermal contribution to the pump-probe experimental map recorded for 2D arrays of gold nanoellipsoids to be isolated. This approach displays the intimate correlation between electron energy and probe photon energy on the ultrafast time-scale of electron thermalization. It also sheds new light on the ultrafast transient optical response of gold nanostructures, and will help the development of optimized plasmonic configurations for nonthermal electrons generation and harvesting.

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Complementary Surface‐Enhanced Raman Scattering (SERS) and IR Absorption Spectroscopy (SEIRAS) with Nanorods‐on‐a‐Mirror

Oksenberg

Shlesinger

Tek

et al. 2022

Adv Funct Materials

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The surface-enhanced counterparts of Raman scattering (SERS) and infrared (IR) absorption (SEIRAS) are commonly used to probe and identify nanoscale matter and small populations of molecules. The contrasting selection rules offer complementary vibrational information of bulk solids or solutions. In this study, a complementary surface-enhanced vibrational spectroscopy approach is presented to probe the vibrational signature of metal-bound molecular monolayers. Nanocavities are designed and produced with sharp and tunable visible (VIS) and mid-IR gap resonances by placing nanorods on a mirror that is coated with a thin dielectric spacer. Their VIS resonances are tuned to match a 1.61 eV (770 nm) resonant excitation for SERS, while their mid-IR resonances span the 1500-2800 cm −1 range (6.5-3.5 µm) in high resolution for SEIRAS, targeting CN bond vibrations at 2220 cm −1 . Both the VIS and mid-IR gap modes support spatially overlapping and highly enhanced near-fields ensuring strong SERS and SEIRAS signals from the same monolayer molecular population. The differences in the vibrational information obtained with the two surface-enhanced spectroscopies when probing coupled molecular vibrations are highlighted and the advantages of using such a platform for investigating cavity-modified chemical reactions are discussed.

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Recent Progress and Prospects in Plasmon-Mediated Chemical Reaction

Cited by 71 publications

References 77 publications

Copper‐Based Plasmonic Catalysis: Recent Advances and Future Perspectives

Copper‐Based Plasmonic Catalysis: Recent Advances and Future Perspectives

Disentangling the Temporal Dynamics of Nonthermal Electrons in Photoexcited Gold Nanostructures

Complementary Surface‐Enhanced Raman Scattering (SERS) and IR Absorption Spectroscopy (SEIRAS) with Nanorods‐on‐a‐Mirror

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