Experimental Realization of Deep Subwavelength Confinement in Dielectric Optical Resonators

TL;DR

This paper demonstrates a dielectric photonic crystal structure that achieves deep subwavelength light confinement with ultra-low losses, enabling stronger light-matter interactions without the high losses of plasmonic devices.

Contribution

We introduce a dielectric bowtie photonic crystal design that combines ultra-small mode volumes with high quality factors, overcoming losses typical of plasmonic resonators.

Findings

Achieved mode volumes comparable to plasmonic structures.

Demonstrated ultra-high quality factors in dielectric resonators.

Enabled strong light-matter interactions with low losses.

Abstract

The ability to highly localize light with strong electric field enhancement is critical for enabling higher efficiency solar cells, light sources, and modulators. While deep subwavelength modes can be realized with plasmonic resonators, large losses in these metal structures preclude most practical applications. We developed an alternative approach to achieving subwavelength confinement that is not accompanied by inhibitive losses. We experimentally demonstrate a dielectric bowtie photonic crystal structure that supports mode volumes commensurate with plasmonic elements and quality factors that reveal ultra-low losses. Our approach opens the door to the extremely strong light-matter interaction regime with simultaneously both ultra-low mode volume and ultra-high quality factor that has remained elusive in optical resonators.