Inverse-designed doped-silicon heater reduces thermal gradient from 110 K to 25 K at ~1000 K and delivers a 10-fold increase in active Sb2S3 switching area within a compact 26x26 μm footprint.
Electrically reconfigurable non-volatile metasurface using low-loss optical phase-change material,
2 Pith papers cite this work. Polarity classification is still indexing.
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2026 2verdicts
UNVERDICTED 2representative citing papers
Neural-network-guided chalcogenide nanophotonic emitters achieve high-contrast broadband emissivity switching, demonstrated by a 31.5°C stratospheric temperature differential and projected to modulate over 600 W/m² radiative heat in space.
citing papers explorer
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Inverse designed resistive heaters for uniform switching of Phase Change Materials
Inverse-designed doped-silicon heater reduces thermal gradient from 110 K to 25 K at ~1000 K and delivers a 10-fold increase in active Sb2S3 switching area within a compact 26x26 μm footprint.
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Adaptive and ultrabroadband thermal control with solid-state nanophotonic emitters
Neural-network-guided chalcogenide nanophotonic emitters achieve high-contrast broadband emissivity switching, demonstrated by a 31.5°C stratospheric temperature differential and projected to modulate over 600 W/m² radiative heat in space.