Generating topological non-diffracting beams using high quality factor nonlocal metasurfaces

Non-diffracting optical beams are essential tools in photonics, enabling robust light transport, super-resolution imaging, and spatiotemporal control. While nonlocal metasurfaces have been proposed for structured-light generation due to their broad angular dispersion and topological characteristics, experimental generation of a non-diffracting beam with nonlocal metasurfaces has not been demonstrated. Here we experimentally realize vortex Bessel beams using a nonlocal metasurface and establish a direct link between non-diffracting-beam generation and photonic band curvature. Depending on the sign of the curvature, the beams exhibit spatially asymmetric non-diffraction, emerging either in front of or behind the metasurface. This asymmetry arises from a radial phase gradient in momentum space, which induces effective space compression or expansion. Furthermore, we demonstrate wavelength-dependent tunability of the beam diameter and propagation distance, and show an order-of-magnitude enhancement in propagation distance compared to conventional Laguerre--Gaussian modes. These results position nonlocal metasurfaces as a compact, tunable platform for spatiotemporally controlled non-diffracting light.