2018
DOI: 10.1021/acsphotonics.8b00231
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Photothermal Heating of Plasmonic Nanoantennas: Influence on Trapped Particle Dynamics and Colloid Distribution

Abstract: Plasmonic antennas are well-known and extremely powerful platforms for optical spectroscopy, sensing, and manipulation of molecules and nanoparticles. However, resistive antenna losses, resulting in highly localized photothermal heat generation, may significantly compromise their applicability. Here we investigate how the interplay between plasmon-enhanced optical and thermal forces affects the dynamics of nanocolloids diffusing in close proximity to gold bowtie nanoantennas. The study is based on an anti-Stok… Show more

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Cited by 82 publications
(81 citation statements)
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“…Immobilized plasmonic nanostructures can work as plasmonic nanotweezers to confine and manipulate small objects because of the strong optical field gradient generated in the surrounding of these nanostructures when they are excited at their resonance wavelengths . In many applications, photothermal effect will influence the trapping stability and has to be taken into account . For example, Au nanopillars for plasmonic near‐field trapping are integrated with a heat sink composed of Au film deposited on Si substrate‐supported Cu film (Figure a) to achieve a stable trapping and controllable rotation of nanomotors .…”
Section: Nanomotor Movement Control Powered By Optical Resonancesmentioning
confidence: 99%
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“…Immobilized plasmonic nanostructures can work as plasmonic nanotweezers to confine and manipulate small objects because of the strong optical field gradient generated in the surrounding of these nanostructures when they are excited at their resonance wavelengths . In many applications, photothermal effect will influence the trapping stability and has to be taken into account . For example, Au nanopillars for plasmonic near‐field trapping are integrated with a heat sink composed of Au film deposited on Si substrate‐supported Cu film (Figure a) to achieve a stable trapping and controllable rotation of nanomotors .…”
Section: Nanomotor Movement Control Powered By Optical Resonancesmentioning
confidence: 99%
“…This technique therefore suffers from the limited working area. In addition, the photothermal heating of the plasmonic nanostructure is usually a hindrance to the stable trapping and movement control of the nanomotors driven by plasmonic tweezers …”
Section: Nanomotor Movement Control Powered By Optical Resonancesmentioning
confidence: 99%
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“…To date, PoMs are usually composed of purely metallic systems and light confinement comes at the price of a low scattering‐to‐absorption ratio—primarily due to absorptive losses in the metallic nanoparticle. The significant absorption induces appreciable heating of the nanoantenna under strong illumination intensities and might hinder applications in thermosensitive systems . The large Ohmic losses also pose a serious limit to the radiative Purcell enhancement of photon emitters coupled to the cavity as the nonradiative relaxation path of the electromagnetic excitation takes place at short timescales.…”
Section: Introductionmentioning
confidence: 99%
“…The significant absorption induces appreciable heating of the nanoantenna under strong illumination intensities and might hinder applications in thermosensitive systems. [29][30][31] The large Ohmic losses also pose a serious limit to the radiative Purcell enhancement of photon emitters coupled to the cavity as the nonradiative relaxation path of the electromagnetic excitation takes place at short timescales. To reduce these parasitic absorptions, it has recently been proposed to create PoM systems with high-index dielectric nanoparticles as opposed to plasmonic nanoparticles.…”
mentioning
confidence: 99%