Gold nanofilms at liquid-liquid interfaces: an emerging platform for redox electrocatalysis, nanoplasmonic sensors and electrovariable optics - Archive ouverte HAL Access content directly
Journal Articles Chemical Reviews Year : 2018

Gold nanofilms at liquid-liquid interfaces: an emerging platform for redox electrocatalysis, nanoplasmonic sensors and electrovariable optics

Micheál D Scanlon
  • Function : Author
  • PersonId : 1041345
Evgeny Smirnov
  • Function : Author
Pekka Peljo
  • Function : Author

Abstract

The functionality of liquid-liquid interfaces formed between two immiscible electrolyte solutions (ITIES) can be markedly enhanced by modification with supramolecular assemblies or solid nanomaterials. The focus of this review is recent progress involving ITIES modified with floating assemblies of gold nanoparticles or "nanofilms". Experimental methods to controllably modify liquid-liquid interfaces with gold nanofilms are detailed. Also, we outline an array of techniques to characterise these gold nanofilms in terms of their physiochemical properties (such as reflectivity, conductivity, catalytic activity or plasmonic properties) and physical interfacial properties (for example, interparticle spacing and immersion depth at the interface). The ability of floating gold nanofilms to impact a diverse range of fields is demonstrated, in particular redox electrocatalysis, surface-enhanced Raman spectroscopy (SERS) or surface plasmon resonance (SPR) based sensors, and electrovariable optical devices. Finally, perspectives on applications beyond the state-of-the-art are provided.
Fichier principal
Vignette du fichier
2018_Nanofilm_Review.pdf (3.02 Mo) Télécharger le fichier
Origin : Files produced by the author(s)
Loading...

Dates and versions

hal-01974503 , version 1 (08-01-2019)

Identifiers

  • HAL Id : hal-01974503 , version 1

Cite

Micheál D Scanlon, Evgeny Smirnov, Jane Talia Stockmann, Pekka Peljo. Gold nanofilms at liquid-liquid interfaces: an emerging platform for redox electrocatalysis, nanoplasmonic sensors and electrovariable optics. Chemical Reviews, 2018, 118 (7), pp.3722-3751. ⟨hal-01974503⟩
98 View
541 Download

Share

Gmail Facebook Twitter LinkedIn More