Thermo‐plasmonics: using metallic nanostructures as nano‐sources of heat

Baffou, Guillaume; Quidant, Romain

doi:10.1002/lpor.201200003

Cited by 1,207 publications

(1,253 citation statements)

References 139 publications

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“…Thermo-plasmonic convection arises due to the electromagnetic heating in metallic nanostructures that results from dissipative losses 3 . This in turn establishes a temperature gradient and produces buoyancy-driven natural convection currents.…”

Section: Resultsmentioning

confidence: 99%

“…P lasmonic systems are drawing much attention due to their broad applications in several fields such as biology 1 , sensing 2 , nanoscale heating 3 , nonlinear optics 4,5 , optofluidics [6][7][8] and optical trapping [9][10][11][12][13][14] . Indeed, light-absorbing nanotextured surfaces such as those utilizing metal pads, dipole antennas and bowtie nanoantennas have recently been shown to be very effective for optical manipulation 9,13,15 .…”

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confidence: 99%

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Understanding and controlling plasmon-induced convection

et al. 2014

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The heat generation and fluid convection induced by plasmonic nanostructures is attractive for optofluidic applications. However, previously published theoretical studies predict only nanometre per second fluid velocities that are inadequate for microscale mass transport. Here we show both theoretically and experimentally that an array of plasmonic nanoantennas coupled to an optically absorptive indium-tin-oxide (ITO) substrate can generate 4micro-metre per second fluid convection. Crucially, the ITO distributes thermal energy created by the nanoantennas generating an order of magnitude increase in convection velocities compared with nanoantennas on a SiO 2 base layer. In addition, the plasmonic array alters absorption in the ITO, causing a deviation from Beer-Lambert absorption that results in an optimum ITO thickness for a given system. This work elucidates the role of convection in plasmonic optical trapping and particle assembly, and opens up new avenues for controlling fluid and mass transport on the micro-and nanoscale.

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Section: Resultsmentioning

confidence: 99%

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confidence: 99%

Understanding and controlling plasmon-induced convection

et al. 2014

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“…Although much effort has been devoted to mitigating plasmon nonradiative decay, recent research has uncovered exciting opportunities for harnessing the process [27,34], such as in photothermal heat generation [35,36], photovoltaic devices [27,37], photocatalysis [38][39][40], driving material phase transitions [41,42], photon energy conversion [43], and photodetection [44][45][46][47][48][49][50]. For instance, the decay of hot electrons can lead to the local heating of the plasmonic nanostructures, making them candidates for nanoscale heat sources [35,36] for use in cancer therapy [51] and solar steam generation [52,53]. On the contrary, hot electrons can be captured before thermalization by an adjacent semiconductor, providing a novel photoelectrical energy conversion scheme for photovoltaics or for driving chemical reactions [39,40].…”

Section: Introductionmentioning

confidence: 99%

Harvesting the loss: surface plasmon-based hot electron photodetection

2016

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Abstract:Although the nonradiative decay of surface plasmons was once thought to be only a parasitic process within the plasmonic and metamaterial communities, hot carriers generated from nonradiative plasmon decay offer new opportunities for harnessing absorption loss. Hot carriers can be harnessed for applications ranging from chemical catalysis, photothermal heating, photovoltaics, and photodetection. Here, we present a review on the recent developments concerning photodetection based on hot electrons. The basic principles and recent progress on hot electron photodetectors are summarized. The challenges and potential future directions are also discussed.

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“…1,2 Light−matter interaction around nanoparticles is at the core of a wide range applications including optical antennas, 3 light harvesting, 4 thermoplasmonics, 5 and local surface plasmon resonance sensing. 6 In this context, optimizing the design of nanoparticles to maximize absorption of light is of crucial importance.…”

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confidence: 99%

Optimizing Nanoparticle Designs for Ideal Absorption of Light

et al. 2015

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Resonant interaction of light with nanoparticles is essential for a broad range of nanophotonics and plasmonics applications, including optical antennas, photovoltaics, thermoplasmonics, and sensing. Given this broad interest, analytical formulas are highly desirable to provide design guidelines for reaching the conditions of ideal absorption. Here we derive analytical expressions to accurately describe the electric and magnetic modes leading to ideal absorption. Our model significantly improves on accuracy as compared to classical models using Green's functions or a Mie coefficient expansion. We demonstrate its applicability over a broad parameter space of frequencies and particle diameters up to several wavelengths. We reveal that ideal absorption is attainable in homogeneous spherical nanoparticles made of gold or silver at specific sizes and illumination frequencies. To reach ideal absorption at virtually any frequency in the visible and near-infrared range, we provide explicit guidelines to design core−shell nanoparticle absorbers. This work should prove useful for providing experimental designs that optimize absorption and for a better understanding of the physics of ideal absorption.

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Thermo‐plasmonics: using metallic nanostructures as nano‐sources of heat

Cited by 1,207 publications

References 139 publications

Understanding and controlling plasmon-induced convection

Understanding and controlling plasmon-induced convection

Harvesting the loss: surface plasmon-based hot electron photodetection

Optimizing Nanoparticle Designs for Ideal Absorption of Light

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