ABSTRACT Multilayer metasurfaces provide substantially greater spectral design freedom than single‐layer devices, yet their implementation in the visible and near‐infrared remains limited by the complexity, cost, and low throughput of conventional nanofabrication. Here, we establish a recently proposed direct‐write electron‐beam lithography approach as a high‐throughput fabrication platform for multilayer resonant metasurfaces, based on an antimony precursor that decomposes in situ into high‐index . This method eliminates deposition–etch cycles and reduces each layer to only two fabrication steps, enabling efficient realization of multilayer architectures. Using this platform, we demonstrate multilayer q‐BIC–like metasurfaces with independently tunable resonance wavelengths and linewidths, allowing the construction of compact multi‐resonant filters with spectrally decoupled layers. We experimentally demonstrate three‐layer devices supporting three resonances and show independent control of resonance wavelength and Q factor across layers. Leveraging this capability, we generate decorrelated filter arrays for compressive sensing and hyperspectral reconstruction, achieving sets of 9 and 36 filters with average absolute Pearson correlation coefficients of 0.11 and 0.21, surpassing prior metasurface and photonic‐crystal implementations. These results establish a practical route toward scalable multilayer resonant metasurfaces for spectral filtering, on‐chip spectroscopy, and computational imaging.
Baspinar et al. (Fri,) studied this question.
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