基于超薄金属间隙的极端纳米光子学。

Extreme nanophotonics from ultrathin metallic gaps.

作者信息

Baumberg Jeremy J, Aizpurua Javier, Mikkelsen Maiken H, Smith David R

机构信息

NanoPhotonics Centre, Cavendish Laboratory, University of Cambridge, Cambridge, UK.

Materials Physics Center CSIC-UPV/EHU and Donostia International Physics Center DIPC, Paseo Manuel de Lardizabal, Donostia-San Sebastiàn, Spain.

出版信息

Nat Mater. 2019 Jul;18(7):668-678. doi: 10.1038/s41563-019-0290-y. Epub 2019 Apr 1.

DOI:10.1038/s41563-019-0290-y

PMID:30936482

Abstract

Ultrathin dielectric gaps between metals can trap plasmonic optical modes with surprisingly low loss and with volumes below 1 nm. We review the origin and subtle properties of these modes, and show how they can be well accounted for by simple models. Particularly important is the mixing between radiating antennas and confined nanogap modes, which is extremely sensitive to precise nanogeometry, right down to the single-atom level. Coupling nanogap plasmons to electronic and vibronic transitions yields a host of phenomena including single-molecule strong coupling and molecular optomechanics, opening access to atomic-scale chemistry and materials science, as well as quantum metamaterials. Ultimate low-energy devices such as robust bottom-up assembled single-atom switches are thus in prospect.

摘要

金属之间的超薄介电间隙能够捕获具有惊人低损耗且体积低于1纳米的表面等离激元光学模式。我们回顾了这些模式的起源和微妙特性，并展示了如何通过简单模型对其进行很好的解释。特别重要的是辐射天线与受限纳米间隙模式之间的混合，这种混合对精确的纳米几何结构极其敏感，甚至到单原子水平。将纳米间隙等离激元与电子和振动跃迁耦合会产生一系列现象，包括单分子强耦合和分子光机械学，从而开启了通往原子尺度化学、材料科学以及量子超材料的大门。因此，诸如坚固的自下而上组装单原子开关等终极低能量器件有望实现。

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基于超薄金属间隙的极端纳米光子学。

Extreme nanophotonics from ultrathin metallic gaps.

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