Flow and extraction of energy and charge carriers in hybrid plasmonic nanostructures

Strong interactions of electromagnetic fields with plasmonic nanomaterials have been exploited in various applications. These applications have centred on plasmon-enhanced scattering rates in nearby molecules or plasmon-induced heating. A question that has emerged recently is whether it is possible to use plasmonic nanostructures in a range of hot electron (hole) applications, including photocatalysis, photovoltaics and photodetection. These applications require coupling of a plasmonic component, which amplifies the interaction of light with the material, to an attached non-plasmonic component that extracts this energy in the form of electronic excitations to perform a function. In this Perspective, we discuss recent work in the emerging field of hybrid plasmonics. We focus on fundamental questions related to the nanoscopic flow of energy and excited charge carriers in these multicomponent materials. We also address critical misconceptions, challenges and opportunities that require more attention. Recent developments in the emerging field of hybrid plasmonics focusing on fundamental aspects related to nanoscopic flow of energy and excited charge carriers in these multicomponent materials and their potential applications are now discussed.

Automated summary

Strong interactions between electromagnetic fields and plasmonic nanomaterials have been used in various applications, particularly in hot electron applications such as photocatalysis and photodetection. The emerging field of hybrid plasmonics focuses on fundamental aspects related to nanoscopic flow of energy and excited charge carriers in these multicomponent materials.