Hyperbolic phonon-polaritons in boron nitride for near-field optical imaging

TL;DR

This paper demonstrates that hexagonal boron nitride can be used for near-field optical imaging with extremely high resolution and multifunctional capabilities, surpassing traditional diffraction limits.

Contribution

It provides the first combined theoretical and experimental analysis of hyperbolic phonon-polaritons in boron nitride for high-resolution near-field imaging and multifunctional optical operations.

Findings

Achieved lambda/32 resolution in near-field imaging.

Enabled geometric outline reconstruction of objects.

Demonstrated wavelength-dependent multifunctionality of hBN.

Abstract

Optical imaging beyond the diffraction limit was one of the primary motivations for negative-index metamaterials, resulting in Pendry's perfect lens and the more attainable superlens. While these approaches offer sub-diffractional resolution, they do not provide a mechanism for magnification of the image. Hyperbolic (or indefinite-permittivity) metamaterials have been theoretically considered and experimentally demonstrated to provide simultaneously subdiffractive imaging and magnification; however, they are plagued with low efficiency and complex fabrication. In this work, we present theoretical and experimental studies of near-field optical imaging through a flat slab of the low-loss, natural hyperbolic material, hexagonal boron nitride (hBN). This thin hBN layer exhibits wavelength-dependent multifunctional operations, offering both an enhanced near-field imaging of single buried objects with down to lambda/32 resolution (0.4 um at lambda=12.8 um), as well as enabling an enlarged reconstruction of the geometric outline of the investigated objects. Both the excellent resolution and the multifunctional operation can be explained based on the volume-confined, wavelength-dependent propagation angle of Type I hyperbolic polaritons. Our results provide both the understanding of near-field imaging performance through this natural hyperbolic media, as well as inspire their exciting potential for guiding and sensing of light at an extreme sub-diffractional scale.