Themed collection Hot-electron science and microscopic processes in plasmonics and catalysis

This paper summarises the challenges and perspectives arising from the Faraday Discussion on Hot-electron science and microscopic processes in plasmonics and catalysis held in February 2019.

An ab initio computational study of direct hot-carrier transfer at metal–molecule interfaces with relevance to plasmonic catalysis.

In these introductory remarks we discuss the generation of nonequilibrium electrons in metals, their properties, and how they can be utilized in two emerging applications: for extending the capabilities of photodetection (left), and for photocatalysis (right), lowering the barriers of chemical reactions.

We have developed a method to measure photocurrents produced by photoexcited hot electrons and holes in bulk metal films.

Direct electronic transitions act as a preferential dissipation pathway for plasmon energy in multicomponent plasmonic systems.

We use an analytical representation of electronic friction for H₂ on Ag(111) to assess the validity and robustness of the MDEF method based on TDPT.

A physically transparent unified theory of optically- and plasmon-induced hot carrier generation in metals is developed with all of the relevant mechanisms included.

The thickness and crystallinity of MoS₂ in a Ag@MoS₂ hybrid film can strongly affect the Raman enhancement and plasmon-driven chemical reactions.

Radicals on-demand with plasmon-mediated in situ dissociation of dithionite “fuel”, for optically controlled redox chemistry.

We describe the complex interplay of spin, layer and valley indexing involved in two different stacking orientations of bilayer TMDCs MoS₂ and WSe₂via an ab initio treatment of electron–electron and electron–phonon interactions.

We synthesize TiO₂-coated gold nanostar- and gold nanorod-based photocatalysts and identify the most important design parameters for the optimization of hot electron-based photocatalysts.

We report on plasmonic near-field and hot electron enhanced ammonia production.

We show the impact of structural, chemical and interfacial features of gold–titania composites on solar and visible photocatalytic gas phase reduction of CO₂ and the specificities of the hot electron-based process.

Optical rectification of plasmon resonances is shown to induce areas of altered surface charge that affect electrochemical reactivity.

We report the enhancement of the plasmon-assisted water oxidation photocurrent in ultrathin (10–20 nm) hematite films.

Using a combination of quantum calculations and classical modelling we study the dynamics of strong-field emission currents in plasmonic gaps.

Plasmonic heterostructures were designed to optimize hot carrier extraction by controlling nanoparticle surface states.

We demonstrate the excitation of dark modes and creation of hot electrons using linearly polarized light and scalable, cost-effective plasmonic surfaces.

Mechanistic understanding of hot electron dynamics at inverse oxide/metal interfaces from a new catalytic nanodiode that exhibits nanoscale metal–oxide interfaces.

We look to understand the enhancement and spatial resolution of a tip-enhanced Raman scattering (TERS) system containing a metal tip and plasmonic substrate.

We show that the number of high energy non-thermal electrons in a metal under CW illumination is very low but much higher than in thermal equilibrium, implying that faster chemical reactions reported previously are extremely likely to originate from a pure thermal effect.

We investigate the ultrafast nonlinear response of silver upon excitation by infrared electromagnetic radiation pulses with a duration of a few femtoseconds.

A collimated beam of ‘projectiles’ strikes a chemisorbed ‘target’ thereby selecting the impact parameter, achieving an elusive goal of reaction dynamics.

The choice of materials for hot electron generation and injection: peak efficiency or broadband.

We characterized the change in photon absorption and scattering properties of plasmonic Au nanoparticles by chemical interface damping.

Nanoscopic inspection of reactivity in single plasmonic photocatalysts.