量化光发射的磁性质。

Quantifying the magnetic nature of light emission.

机构信息

Brown University, School of Engineering, Providence, Rhode Island 02912, USA.

出版信息

Nat Commun. 2012;3:979. doi: 10.1038/ncomms1984.

DOI:10.1038/ncomms1984

Abstract

Tremendous advances in the study of magnetic light-matter interactions have recently been achieved using man-made nanostructures that exhibit and exploit an optical magnetic response. However, naturally occurring emitters can also exhibit magnetic resonances in the form of optical-frequency magnetic-dipole transitions. Here we quantify the magnetic nature of light emission using energy- and momentum-resolved spectroscopy, and leverage a pair of spectrally close electric- and magnetic-dipole transitions in trivalent europium to probe vacuum fluctuations in the electric and magnetic fields at the nanometre scale. These results reveal a new tool for nano-optics: an atomic-size quantum emitter that interacts with the magnetic component of light.

摘要

近年来，通过研究具有光学各向异性的人工纳米结构，人们在磁光相互作用领域取得了巨大的进展。然而，天然发射体也可以表现出以光频磁偶极跃迁形式的磁共振。在这里，我们使用能量和动量分辨光谱学来量化光发射的磁性，并利用三价铕的两个光谱上接近的电偶极和磁偶极跃迁来探测纳米尺度下电磁场的真空涨落。这些结果揭示了一种新的纳米光学工具：一个与光的磁场分量相互作用的原子级量子发射器。

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量化光发射的磁性质。

Quantifying the magnetic nature of light emission.

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