Baù, EnricoEnricoBaùHeimig, ConnorConnorHeimigBiechteler, JonasJonasBiechtelerMangold, FlorianFlorianMangoldSchwab, JulianJulianSchwabMenezes, LeonardoLeonardoMenezesKarmakar, ManobinaManobinaKarmakarRen, HaoranHaoranRenMaier, Stefan A.Stefan A.MaierGiessen, HaraldHaraldGiessenTittl, AndreasAndreasTittl2026-05-282026-05-282026-05-12Nature Nanotechnology (in Press): (2026)https://hdl.handle.net/11420/63236Photonic skyrmions are topological textures that exhibit remarkable resilience to environmental perturbations and support deeply subwavelength features, making them promising candidates for high-resolution microscopy, optical computing devices and ultrahigh-density information encoding. However, in contrast to free-space optical skyrmions, all existing approaches to generate polaritonic field skyrmions are limited by a lack of dynamic tunability. In general, without engineering the phase of the incident light, both their lattice site diameter and total topological charges remain fixed after fabrication. These constraints originate from a shared reliance on wavelength-dependent coupling structures or complex excitation conditions. To overcome these limitations, we introduce the concept of dynamically controllable polaritonic topologies generated by non-local photonic modes. Here we leverage quasi-bound states in the continuum resonances in dielectric metasurfaces to launch hyperbolic phonon polaritons in hexagonal boron nitride that interfere to create highly confined photonic skyrmion lattices with diameters down to 271 nm (λ/25). Thanks to the steep dispersion of hexagonal boron nitride, we can change the excitation frequency to achieve control over the size of individual photonic skyrmions within the same physical resonator structure. In addition, our platform is not limited to one type of topology but can generate optical meron lattices and kπ-twist skyrmions through straightforward variations in resonator shape, providing a feasible path towards skyrmion multiplexing and near-arbitrary topologies. The synergistic integration of resonant metasurfaces with polaritonic topologies has potential applications for nanophotonics, such as topological lasing, nonlinear optics and twistronics, as well as for condensed matter physics, such as Chern insulators and topological edge states.en1748-33952026Nature Publishing Grouphttps://creativecommons.org/licenses/by/4.0/Technology::620: Engineering::620.5: NanotechnologyJournal Articlehttps://doi.org/10.15480/882.1720410.1038/s41565-026-02174-510.15480/882.17204