mit researchers have developed design rules for the engineering of hybrid optical-thermal antennas that offer “orders-of-magnitude intensity enhancement at the operating wavelength and nanoscale temperature control.”
(wikimedia commons)
the research was originally published in august. the abstract of the report reads:
“metal nanoantennas supporting localized surface plasmon resonances have become an indispensable tool in bio(chemical) sensing and nanoscale imaging applications. the high plasmon-enhanced electric field intensity in the visible or near-ir range that enables the above applications may also cause local heating of nanoantennas.
“we present a design of hybrid optical–thermal antennas that simultaneously enable intensity enhancement at the operating wavelength in the visible and nanoscale local temperature control. we demonstrate a possibility to reduce the hybrid antenna operating temperature via enhanced infrared thermal emission. we predict via rigorous numerical modeling that hybrid optical–thermal antennas that support high-quality-factor photonic-plasmonic modes enable up to 2 orders of magnitude enhancement of localized electric fields and of the optical power absorbed in the nanoscale metal volume.
“at the same time, the hybrid antenna temperature can be lowered by several hundred degrees with respect to its all-metal counterpart under continuous irradiance of 104–105 w/m2. the temperature reduction effect is attributed to the enhanced radiative cooling, which is mediated by the thermally excited localized surface phonon polariton modes. we further show that temperature reduction under even higher irradiances can be achieved by a combination of enhanced radiative and convective cooling in hybrid antennas.
“finally, we demonstrate how hybrid optical–thermal antennas can be used to achieve strong localized heating of nanoparticles while keeping the rest of the optical chip at low temperature.”
according to a report from the school, this breakthrough could lead to advancements in sensing, imaging, coherent thermal emission generation, radiative cooling, and local catalysis.
read the full report at http://pubs.acs.org/doi/abs/10.1021/acsphotonics.6b00374.
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