Plasmonic metasurfaces have been realized for efficient light absorption, thereby leading to
photothermal conversion through nonradiative decay of plasmonic modes. However, current …

Metasurfaces, artificially engineered surfaces comprised of subwavelength resonators, show
promise for realizing a new generation of optical materials and devices. However, current …

Thermal scanning-probe lithography (t-SPL) is a high-resolution nanolithography technique
that enables the nanopatterning of thermosensitive materials by means of a heated silicon …

Solar-thermal technologies for converting chemicals using thermochemistry require extreme
light concentration. Exploiting plasmonic nanostructures can dramatically increase the …

Plasmonic metasurfaces with adjustable optical responses can be achieved through phase
change materials (PCMs) with high optical contrast. However, the on–off behavior of the …

Thermal emission from objects tends to be spectrally broadband, unpolarized, and
temporally invariant. These common notions are now challenged with the emergence of new …

The nonradiative conversion of light to heat by plasmonic nanostructures, the so‐called
plasmonic photothermal effect, has attracted enormous attention due to their widespread …

Engineering the heat flux between two surfaces kept at different temperatures relies on the
ability to tailor the dispersion of modes sustained by the system. Metasurfaces made of …

Tuning optical properties of plasmonic nanostructures, including their absorption, scattering,
and local‐field distribution is of great interest for various applications that rely on optical …

Hydrogen, as a type of sustainable energy, has the potential to facilitate the achievement of
carbon neutrality by replacing fossil fuels. Conventional plasmonic metal nanostructures as …