Tracking Nanoelectrochemistry Using Individual Plasmonic Nanocavities

Martino, Giuliana Di; Turek, Vladimir A.; Lombardi, Anna Maria; Szabó, István; Nijs, Bart de; Kuhn, Alexander; Rosta, Edina; Baumberg, Jeremy J.

doi:10.1021/acs.nanolett.7b01676

Cited by 43 publications

(61 citation statements)

References 28 publications

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“…It should be noted that the electric and magnetic field enhancement is strongly dependent on the NP diameter at fixed wavelength (Figure a, b), providing maxima values at the NP diameters of ∼160, 190, 240, and 280 nm. These numerical results correlate with experiment on light scattering by such NPs in dark field geometry (see Supporting Information, Figure S3), where the intrinsic NP optical resonances and pump/scattering are merged …”

Section: Resultssupporting

confidence: 81%

“…Despite high thermal stability of dielectrics within broad temperature range, applicability of such nanoscale Raman thermometers for the most of chemical and biological processes is hindered by relatively long data acquisition time (hundreds of second for commercial Raman spectrometers), which is due to low RS signal intensity from non‐resonant nanometer scale objects.…”

Section: Resultsmentioning

confidence: 99%

“…In light of the multifunctionality of the hybrid nanocavity, its performance should be critically discussed in details. We compare our design with numerous approaches to nanoscale thermometry, heating and monitoring of molecular events, which have been developed for biomedical, cell biological and chemical applications, as well as for material science, physics, and engineering of nanodevices (i)Despite the diameter of the focused radiation (860 nm) we use in Raman measurements is much greater than the average diameter of NPs (100‐300 nm), most of the collected RS signal (Figure c) originates from the BSA molecules hosted inside the nanocavity (inset in Figure c).…”

Section: Discussionmentioning

confidence: 99%

“…Nanometer scale gap between metallic film and adjacent plasmonic nanoparticle (NP) ensures extremely localized and enhanced optical field . Such plasmonic nanocavity brings unique opportunities for strong light‐matter interaction, enhancement of Purcell factor and Raman scattering (RS), as well as for lasing, bio‐sensing, and initiation/monitoring the molecular events . However, the interaction of light with such nanocavity is accompanied by inevitable heating due to Joule losses resulting in irreversible modification of shape, composition and optical properties of the metallic components .…”

Section: Introductionmentioning

confidence: 99%

“…[1][2][3] Such plasmonic nanocavity brings unique opportunities for strong light-matter interaction, [4] enhancement of Purcell factor [5,6] and Raman scattering (RS), [7][8][9][10] as well as for lasing, [11] biosensing, [12] and initiation/monitoring the molecular events. [13][14][15][16] However, the interaction of light with such nanocavity is accompanied by inevitable heating due to Joule losses [17] resulting in irreversible modification of shape, composition and optical properties of the metallic components. [18][19][20] This motivates to seek for alternatives for localization and enhancement of light when the local temperature plays a crucial (positive or negative) role.…”

Section: Introductionmentioning

confidence: 99%

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Metal‐Dielectric Nanocavity for Real‐Time Tracing Molecular Events with Temperature Feedback

Milichko

Zuev

Baranov

et al. 2017

Laser & Photonics Reviews

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Plasmonic nanoparticles coupled with metallic films forming nanometer scale cavities have recently emerged as a powerful tool for enhancement of light-matter interaction. Despite high efficiency for sensing and light emission, such nanocavities exhibit harmful and uncontrolled optical heating which limits the ranges of light intensities and working temperature. In contrast to plasmonic nanoparticles, all-dielectric counterparts possess low Ohmic losses, high temperature stability along with a strong temperature-dependent Raman response. Here, we demonstrate that a silicon nanoparticle coupled with a thin gold film can serve as a multifunctional metal-dielectric (hybrid) nanocavity operating up to 1200 K. Resonant interaction of light with such nanocavity enables molecular sensing, heat-induced molecular events (protein unfolding), and their real-time tracing with a nanoscale thermometry through the monitoring enhanced Raman scattering both from the nanoparticle and analyzed molecules. We model numerically the thermo-optical properties of the hybrid nanocavity and reveal two alternative regimes of operation -with and without strong optical heating while other functionalities are preserved. We believe that the concept of the multifunctional hybrid nanocavities holds great potential for diverse photochemical and photophysical applications.

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Section: Resultssupporting

confidence: 81%

Section: Resultsmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 3 more Smart Citations

Metal‐Dielectric Nanocavity for Real‐Time Tracing Molecular Events with Temperature Feedback

Milichko

Zuev

Baranov

et al. 2017

Laser & Photonics Reviews

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Quantum Plasmonics: Energy Transport Through Plasmonic Gap

2021

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scanning tunneling microscopy (STM), [5,6] atomic force microscopy (AFM), [7] and other techniques allowing resolution to be reduced to the atomic scale can help realize atomic-scale world exploration. This is the starting point of the nanotechnology era; since its inception, this technology has changed the nature of almost every human-made object. Six decades after Richard Feynman's lecture, we find that there is still plenty of room at the bottom, through the incorporation of nanophotonics. [8] To elucidate: quantum plasmonics has emerged as an attractive research field in new nanophotonics; research is underway to reveal and accurately describe the quantum nature of electrons at the bottom of extremely confined nano-or sub-nanometer scale materials, using light. [9,10] By exploring the quantum mechanical interactions of matter with light (in particular, using the coherent interactions between the plasmonic cavity and the material), [11][12][13][14][15][16][17][18] these efforts seek to establish new frontiers in information processing technology and to satisfy the everincreasing requirements for speed and capacity in quantum computing, quantum cryptography, and quantum metrology. They might also suggest research fields beyond this, involving the ultimate miniaturization of photonic components and the extreme limits of the light-matter interaction. These advantages may help solve some fundamental problems of electronics, such as those of bandwidth, frequency, and energy consumption. [19] In this review, we describe recent developments in the research of exotic materials capable of mediating quantum plasmonics and inducing quantum energy transport. We briefly provide classical and quantum descriptions of matter, from the bulk, nano, and cluster scales down to atomic matter, exploring the band structures via their optical responses. By considering a single nanoplasmonic material, we describe the theoretical and experimental findings pertaining to assembled nanoplasmonic structures, in the context of the plasmonic gap distance and the type of advanced functional material. The plasmonic gap herein refers to a nanometer or sub-nanometer gap that transports (couples, tunnels, exchanges, confines) electromagnetic energy between plasmonic resonators. Advanced functional materials within an extremely confined metallic resonator are described; these include air/vacuum, aliphatic and conjugated molecules, 2D materials, organic and inorganic materials with At the interfaces of metal and dielectric materials, strong light-matter interactions excite surface plasmons; this allows electromagnetic field confinement and enhancement on the sub-wavelength scale. Such phenomena have attracted considerable interest in the field of exotic material-based nanophotonic research, with potential applications including nonlinear spectroscopies, information processing, single-molecule sensing, organic-molecule devices, and plasmon chemistry. These innovative plasmonics-based technologies can meet the ever-increasing demands for speed and ca...

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Biosensors and Bioelectronics on Smartphone

et al. 2021

Handbook of Cell Biosensors

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Tracking Nanoelectrochemistry Using Individual Plasmonic Nanocavities

Cited by 43 publications

References 28 publications

Metal‐Dielectric Nanocavity for Real‐Time Tracing Molecular Events with Temperature Feedback

Metal‐Dielectric Nanocavity for Real‐Time Tracing Molecular Events with Temperature Feedback

Quantum Plasmonics: Energy Transport Through Plasmonic Gap

Biosensors and Bioelectronics on Smartphone

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