Abstract
Non-Euclidean geometry, which violates the traditional parallel postulate, encompasses a wide class of physical systems, including fullerenes, space-time structures, and complex networks. A notable example is the hyperbolic lattice, which exhibits unique band properties and topological phenomena compared with those of Euclidean lattices. Although hyperbolic lattices have been effectively realized on a Euclidean plane using projections onto the Poincaré disk, the poor scalability of this approach hinders large-size implementations essential for examining lattice physics. Here, we demonstrate a scalable and reconfigurable emulation of wave dynamics in a hyperbolic lattice by employing programmable photonics. We develop a one-dimensional coupled-resonator lattice with reconfigurable gauge fields and resonances, which emulates unitary wave evolutions inside a hyperbolic lattice. The programmability of our system allows for modeling time-varying hyperbolic lattices including dynamic defects. The superior scalability of our system compared to the realizations using the Poincaré disk and spatial-domain circuits paves the way to extending non-Euclidean photonics into large-scale and dynamical systems.
Original language | English |
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Pages (from-to) | 3890-3897 |
Number of pages | 8 |
Journal | ACS Photonics |
Volume | 11 |
Issue number | 9 |
DOIs | |
State | Published - 18 Sep 2024 |
Keywords
- coupled resonator
- gauge field
- hyperbolic lattice
- programmable photonics
- scaling
- unitary operation