4.8 Review

Plasmonic Photocatalysis for CO2 Conversion to Chemicals and Fuels

Journal

ACS MATERIALS LETTERS
Volume 3, Issue 5, Pages 574-598

Publisher

AMER CHEMICAL SOC
DOI: 10.1021/acsmaterialslett.1c00081

Keywords

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Funding

  1. Department of Atomic Energy (DAE), Government of India [RD-TFR-RTI4003]
  2. Department of Science AMP
  3. Technology (DST)-Mission Innovation India [DST/TMD(EWO)/IC5-2018-07(G)]

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The article discusses the fundamentals and applications of plasmonic catalysis, focusing on its role in CO2 conversion and methane dry reforming. Through concepts such as the dielectric function, charge carrier generation, and extraction, the surface activation mechanism of plasmonic nanocatalysts is revealed.
Localized surface plasmon resonance (LSPR) allows nanoparticles (NPs) to harvest light and concentrate it near the nanoparticle surface. Light energy is utilized in the generation of excited charge carriers as well as heat. Plasmonic catalysts used these energetic charge carriers (and the heat) to drive chemical reactions on their surface and allowed the discovery of novel and selective reaction pathways that were not possible in thermal catalysis. This review discusses the fundamentals of plasmonic catalysis and its application for CO2 conversion to fuel and chemicals. We first discussed the fundamentals of LSPR and the mechanism of plasmonic photocatalysis, using the concepts of the dielectric function, charge carrier generation, and relaxation pathways. We then reviewed various charge carrier-mediated activation of molecules (their chemical bonds) on the surface of plasmonic nanocatalysts and how the extraction of charge carriers played a critical role in plasmonic catalysis. The concept of multicomponent plasmonic catalysis, a hybrid catalyst by combining plasmonic metals (Cu, Au, Ag, Al, etc.) with nonplasmonic but active catalytic metals (Pt, Pd, Ru, Rh, etc.), in close proximity to each other, was then discussed. Photocatalytic CO2 reduction reactions using the examples of each of three major pathways, (i) direct transfer of hot charge carriers to the reactant molecules, (ii) providing heat to the reactant molecules by photothermal effect, and (iii) enhancing the photon absorption rate of reactant molecules by optical near-field enhancement close to the nanocatalyst surface, were discussed. In the last section, we reviewed plasmonic photocatalysts for dry reforming of methane (DRM) using CO2, which uses two greenhouse gases as feed to produce industrially significant syngas. Overall, the review is broadly divided into four sections: (1) Fundamentals of Plasmonic Nanomaterials, (2) Mechanism of Plasmonic Photocatalysis, (3) Plasmonic Photocatalysts for CO2 Reduction to Fuels and Chemicals, and (4) Plasmonic Photocatalysts for Methane Dry Reforming using CO2; with each section divided into several subsections.

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