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Highly-efficient electrically-driven localized surface plasmon source enabled by resonant inelastic electron tunneling

Haoliang Qian, Shilong Li, Su‐Wen Hsu, Ching‐Fu Chen, Fanglin Tian, Andrea R. Tao, Zhaowei Liu

2021Nature Communications44 citationsDOIOpen Access PDF

Abstract

Abstract On-chip plasmonic circuitry offers a promising route to meet the ever-increasing requirement for device density and data bandwidth in information processing. As the key building block, electrically-driven nanoscale plasmonic sources such as nanoLEDs, nanolasers, and nanojunctions have attracted intense interest in recent years. Among them, surface plasmon (SP) sources based on inelastic electron tunneling (IET) have been demonstrated as an appealing candidate owing to the ultrafast quantum-mechanical tunneling response and great tunability. However, the major barrier to the demonstrated IET-based SP sources is their low SP excitation efficiency due to the fact that elastic tunneling of electrons is much more efficient than inelastic tunneling. Here, we remove this barrier by introducing resonant inelastic electron tunneling (RIET)—follow a recent theoretical proposal—at the visible/near-infrared (NIR) frequencies and demonstrate highly-efficient electrically-driven SP sources. In our system, RIET is supported by a TiN/Al 2 O 3 metallic quantum well (MQW) heterostructure, while monocrystalline silver nanorods (AgNRs) were used for the SP generation (localized surface plasmons (LSPs)). In principle, this RIET approach can push the external quantum efficiency (EQE) close to unity, opening up a new era of SP sources for not only high-performance plasmonic circuitry, but also advanced optical sensing applications.

Topics & Concepts

PlasmonQuantum tunnellingOptoelectronicsMaterials scienceSurface plasmonQuantum efficiencyElectronHeterojunctionNanotechnologyPhysicsQuantum mechanicsPlasmonic and Surface Plasmon ResearchGold and Silver Nanoparticles Synthesis and ApplicationsMolecular Junctions and Nanostructures