English

Extremely thin perfect absorber by generalized multipole bianisotropic effect

Optics 2023-08-15 v1

Abstract

Symmetry breaking plays a crucial role in understanding the fundamental physics underlying numerous physical phenomena, including the electromagnetic response in resonators, giving rise to intriguing effects such as directional light scattering, supercavity lasing, and topologically protected states. In this work, we demonstrate that adding a small fraction of lossy metal (as low as 1×1061\times10^{-6} in volume), to a lossless dielectric resonator breaks inversion symmetry thereby lifting its degeneracy, leading to a strong bianisotropic response. In the case of the metasurface composed of such resonators, this effect leads to unidirectional perfect absorption while maintaining nearly perfect reflection from the opposite direction. We have developed more general Onsager-Casimir relations for the polarizabilities of particle arrays, taking into account the contributions of quadrupoles, which shows that bianisotropy is not solely due to dipoles, but also involves high-order multipoles. Our experimental validation demonstrates an extremely thin terahertz-perfect absorber with a wavelength-to-thickness ratio of up to 25,000, where the material thickness is only 2% of the theoretical minimum thickness dictated by the fundamental limit. Our findings have significant implications for a variety of applications, including energy harvesting, thermal management, single-photon detection, and low-power directional emission.

Keywords

Cite

@article{arxiv.2308.07139,
  title  = {Extremely thin perfect absorber by generalized multipole bianisotropic effect},
  author = {Hao Ma and Andrey B. Evlyukhin and Andrey E. Miroshnichenko and Fengjie Zhu and Siyu Duan and Jingbo Wu and Caihong Zhang and Jian Chen and Biao-Bing Jin and Willie J. Padilla and Kebin Fan},
  journal= {arXiv preprint arXiv:2308.07139},
  year   = {2023}
}
R2 v1 2026-06-28T11:55:08.369Z