Determination of the Zak phase of one-dimensional photonic systems via far-field diffraction

TL;DR

This paper introduces a method to determine the Zak phase in 1D photonic systems by analyzing far-field diffraction patterns, linking spectral profiles to Bloch wave symmetries and topological properties.

Contribution

The study presents a novel approach to measure Zak phases through far-field diffraction, enabling band topology characterization in non-Hermitian photonic systems.

Findings

Spectral profiles reveal Bloch wave symmetries and Zak phases.

Far-field diffraction can identify topological interface states.

Method validated on plasmonic and photonic crystals.

Abstract

Bloch waves in 1D periodic systems carry Zak phase, which plays a key role in determining the band topology. In general, for systems that possess inversion symmetry, the Zak phase of an isolated band is quantized as 0 or Pi and is associated with the spatial field symmetries at the Brillouin zone center and boundary. The phase is Pi if the field symmetries are different but is 0 when they are the same. Since the radiation losses from leaky systems are strongly associated with the Bloch waves, one may probe the far-field continuum to determine the Zak phases. Here, we formulate the diffractions from photonic systems at the zone center and boundary and find their spectral profiles reveal the Bloch wave symmetries and thereby the corresponding Zak phase. The field symmetries also generalize the occurrence of bound states in the continuum at high symmetry points. For verification, we have studied the Zak phases of one-dimensional TM plasmonic and TE photonic crystals by electrodynamic simulations and measuring the optical properties of plasmonic crystals using Fourier space diffraction spectroscopy and common path interferometry. In addition, a topological protected interface state is demonstrated when two 0 and Pi systems are joined together. The results prove our method provides a simple way for characterizing the band topology of non-Hermitian systems via far-fields.