Controlling Light, Heat, and Vibrations in Plasmonics and Phononics

Cunha, João Paulo Silva; Guo, Tianlong; Valle, Giuseppe Della; Koya, Alemayehu Nana; Zaccaria, Remo Proietti; Alabastri, Alessandro

doi:10.1002/adom.202001225

Cited by 54 publications

(36 citation statements)

References 277 publications

(486 reference statements)

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“…In nanomedicine, for example, the accurate determination of the temperature can yield the development of new thermal diagnosis and therapy methods, [8,11,34] whereas in micro or nanoelectronics tracking the thermal exchanges at submicrometric length scales can afford a detailed understanding of the thermal properties in spatial domains for which the macroscopic transfer laws are not valid anymore. [35] In fact, real-world applications of luminescence thermometry are hindered by the accuracy of the nanothermometers, which is given by the temperature uncertainty, 𝛿T = 1 S r 𝛿Δ Δ , [7] where 𝛿Δ/Δ is the relative uncertainty in Δ, determined by the detection system used. The best 𝛿T value reported by now was achieved by using lanthanide-bearing nanomaterials, with 𝛿T ranging between 0.1 and 0.3 K. [4,20] Nowadays, cutting-edge reports on luminescence nanothermometry are reaching the boundary of the accuracy of the nanothermometers.…”

Section: Introductionmentioning

confidence: 99%

Going Above and Beyond: A Tenfold Gain in the Performance of Luminescence Thermometers Joining Multiparametric Sensing and Multiple Regression

Maturi

Brites

Ximendes

et al. 2021

Laser & Photonics Reviews

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Luminescence thermometry has substantially progressed in the last decade, rapidly approaching the performance of concurrent technologies. Performance is usually assessed through the relative thermal sensitivity, Sr, and temperature uncertainty, δT. Until now, the state‐of‐the‐art values at ambient conditions do not exceed maximum Sr of 12.5% K−1 and minimum δT of 0.1 K. Although these numbers are satisfactory for most applications, they are insufficient for fields that require lower thermal uncertainties, such as biomedicine. This has motivated the development of materials with an improved thermal response, many of them responding to the temperature through distinct photophysical properties. This paper demonstrates how the performance of multiparametric luminescent thermometers can be further improved by simply applying new analysis routes. The synergy between multiparametric readouts and multiple linear regression makes possible a tenfold improvement in Sr and δT, reaching a world record of 50% K−1 and 0.05 K, respectively. This is achieved without requiring the development of new materials or upgrading the detection system as illustrated by using the green fluorescent protein and Ag2S nanoparticles. These results open a new era in biomedicine thanks to the development of new diagnosis tools based on the detection of super‐small temperature fluctuations in living specimens.

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Section: Introductionmentioning

confidence: 99%

Going Above and Beyond: A Tenfold Gain in the Performance of Luminescence Thermometers Joining Multiparametric Sensing and Multiple Regression

Maturi

Brites

Ximendes

et al. 2021

Laser & Photonics Reviews

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“…Indeed, the resonant excitation of surface plasmons in subwavelength noble metallic nanostructures gives rise to strong field enhancements in proximity of the nanostructures. These generated electromagnetic hot spots can be exploited as nanoscale heat sources [93][94][95] for low-power photothermal probing. [83,96] Generally, thermomechanical detectors rely on the structural deformation upon exposure to radiation.…”

Section: Plasmo-thermomechanical Devices For Infrared Detectionmentioning

confidence: 99%

Plasmomechanical Systems: Principles and Applications

Koya

Cunha

Guerrero-Becerra

et al. 2021

Adv Funct Materials

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Extreme confinement of electromagnetic waves and mechanical displacement fields to nanometer dimensions through plasmonic nanostructures offers unprecedented opportunities for greatly enhanced interaction strength, increased bandwidth, lower power consumption, chip-scale fabrication, and efficient actuation of mechanical systems at the nanoscale. Conversely, coupling mechanical oscillators to plasmonic nanostructures introduces mechanical degrees of freedom to otherwise static plasmonic structures thus giving rise to the generation of extremely large resonance shifts even for minor position changes. This nanoscale marriage of plasmonics and mechanics has led to the emergence of a new field of study called plasmomechanics that explores the fundamental principles underneath the coupling between light and plasmomechanical nanoresonators. In this review, both the fundamental concepts and applications of plasmomechanics as an emerging field of study are discussed. After an overview of the basic principles of plasmomechanics, the active tuning mechanisms of plasmonic nano-mechanical systems are extensively analyzed. Moreover, the recent developments on the practical implications of plasmomechanic systems for such applications as biosensing and infrared detection are highlighted. Finally, an outlook on the implications of the plasmomechanical nanosystems for development of point-of-care diagnostic devices that can help early and rapid detection of fatal diseases are forwarded.

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“…Such fundamental studies on the optomechanical coupling at the atomic level have inspired similar research at the nanoscale. [96] The marriage of plasmonic resonance and mechanical vibration at the nanometer scale has led to the emergence of a new field of study called plasmomechanics, which explores the interaction between light and plasmomechanical nanoresonators and related phenomena. [97]…”

Section: Nanoporous Metasurfaces For Enhanced Single-molecule Spectro...mentioning

confidence: 99%

Plasmonic Nanoarchitectures for Single‐Molecule Explorations: An Overview

Koya

2021

Advanced Photonics Research

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Plasmonic nanostructures have immense potentials for extreme concentration of light into deep‐subwavelength spaces with giant local field intensity, which can be exploited for novel applications including nanoscale optical trapping, biosensing, and enhanced spectroscopy. Herein, a succinct overview of the potentials of engineered plasmonic nanoarchitectures of various geometries including nanoparticles, nanodimers, nanoapertures, nanoporous surfaces, and picometer‐scale gap systems for single‐molecule analysis is provided. In particular, the potentials of single plasmonic nanoparticles for single‐molecule sensing, coupled plasmonic nanodimers for few‐molecule strong coupling, metallic nanocavities for optical manipulation of single molecules, nanoporous metasurfaces for enhanced single‐molecule spectroscopy, and plasmonic picocavities for single‐molecule optomechanics are extensively discussed. Finally, as an outlook, exploiting such novel nanoarchitectures for developing innovative biosensing platforms that will be able to trap and detect objects at the single‐molecule level is forwarded.

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Controlling Light, Heat, and Vibrations in Plasmonics and Phononics

Cited by 54 publications

References 277 publications

Going Above and Beyond: A Tenfold Gain in the Performance of Luminescence Thermometers Joining Multiparametric Sensing and Multiple Regression

Going Above and Beyond: A Tenfold Gain in the Performance of Luminescence Thermometers Joining Multiparametric Sensing and Multiple Regression

Plasmomechanical Systems: Principles and Applications

Plasmonic Nanoarchitectures for Single‐Molecule Explorations: An Overview

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