Litcius/Paper detail

Plasmonic Split-Trench Resonator for Trapping and Sensing

Daehan Yoo, Avijit Barik, Fernando de León‐Pérez, Daniel A. Mohr, Matthew Pelton, L. Martı́n-Moreno, Sang‐Hyun Oh

2021ACS Nano27 citationsDOIOpen Access PDF

Abstract

On-chip integration of plasmonics and electronics can benefit a broad range of applications in biosensing, signal processing, and optoelectronics. A key requirement is a chip-scale manufacturing method. Here, we demonstrate a split-trench resonator platform that combines a high-quality-factor resonant plasmonic biosensor with radio frequency (RF) nanogap tweezers. The split-trench resonator can simultaneously serve as a dielectrophoretic trap and a nanoplasmonic sensor. Trapping is accomplished by applying an RF electrical bias across a 10 nm gap, thereby either attracting or repelling analytes. Trapped analytes are detected in a label-free manner using refractive-index sensing, enabled by interference between surface-plasmon standing waves in the trench and light transmitted through the gap. This active sample concentration mechanism enables detection of nanoparticles and proteins at a concentration as low as 10 pM. We can manufacture centimeter-long split-trench cavity resonators with high throughput via photolithography and atomic layer deposition, toward practical applications in biosensing, spectroscopy, and optoelectronics.

Topics & Concepts

PlasmonMaterials scienceResonatorTrenchOptoelectronicsBiosensorTweezersPhotolithographyNanotechnologyRefractive indexOpticsLayer (electronics)PhysicsPlasmonic and Surface Plasmon ResearchPhotonic and Optical DevicesOrbital Angular Momentum in Optics