Remote optical sensing on the nanometer scale with a bowtie aperture nano-antenna on a fiber tip of scanning near-field optical microscopy

Atie, Elie; Xie, Zhihua; Eter, Ali El; Salut, Roland; Nedeljković, Dušan; Tannous, Tony Abi; Baida, Fadi; Grosjean, Thierry

doi:10.1063/1.4918531

Cited by 25 publications

(17 citation statements)

References 24 publications

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“…S2 on line shows the different groups of wavelength dependent potential well depth with difference bowtie nano-aperture sizes. Incident wavelength for deepest potential well evidently increases when enlarging the aperture size, which accords to the previous works 20 .…”

Section: Resultssupporting

confidence: 92%

“…It has been proved by the previous work that the great localized and enhanced e-field exists in the center of bowtie dimmers, enabling to generate enough e-field gradients to trap nanoparticles within nanoscales. The plasmon resonance modes in metallic nano-apertures, proved as Fabry-Pérot-like interfering of TE 10 mode propagation wave, strongly depend on the aperture geometry 20 . Through modifying apertures sizes or shapes, the wavelength for plasmonic trapping can be flexibly tuned.…”

Section: Resultsmentioning

confidence: 99%

“…In this paper, the plasmonic trapping forces and the shape of the trapping potential wells depending on the wavelength of incident beams are investigated based on the finite element method (FEM). Bowtie nanoaperture, an effective structure for plasmonic trapping proved by previous works 19 20 , is applied to trap metallic nanoparticles within nanoscales. Prominent tunabilities of potential well, such as depth, width and stiffness at potential well bottom, were checked.…”

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confidence: 99%

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Tunable potential well for plasmonic trapping of metallic particles by bowtie nano-apertures

Chen

et al. 2016

Sci Rep

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In this paper, the tunable optical trapping dependence on wavelength of incident beam is theoretically investigated based on numerical simulations. The Monte Carlo method is taken into account for exploring the trapping characteristics such as average deviation and number distribution histogram of nanoparticles. It is revealed that both the width and the depth of potential well for trapping particles can be flexibly adjusted by tuning the wavelength of the incident beam. In addition, incident wavelengths for the deepest potential well and for the strongest stiffness at bottom are separated. These phenomena are explained as the strong plasmon coupling between tweezers and metallic nanoparticles. In addition, required trapping fluence and particles’ distributions show distinctive properties through carefully modifying the incident wavelengths from 1280 nm to 1300 nm. Trapping with lowest laser fluence can be realized with 1280 nm laser and trapping with highest precision can be realized with 1300 nm laser. This work will provide theoretical support for advancing the manipulation of metallic particles and related applications such as single-molecule fluorescence and surface enhanced Raman spectroscopy.

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Section: Resultssupporting

confidence: 92%

Section: Resultsmentioning

confidence: 99%

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confidence: 99%

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Tunable potential well for plasmonic trapping of metallic particles by bowtie nano-apertures

Chen

et al. 2016

Sci Rep

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“…5 and show that the resonance properties (both resonance wavelength and enhancement factors) of the DA are affected by the presence of the substrate. This phenomenon was already pointed out for another kind of nano-antennas, such as a bowtie nano-antenna 11 or the bowtie nano-aperture antenna ( BNA ) for which the resonance properties were examined as a function of the antenna-to-substrate distance 24 , 25 . In the latter cases, a shift as large as Δ λ = 500 nm of the resonance wavelength of a BNA occurs when the latter moves up over 10 nm from the substrate interface.…”

Section: Force Results: the Three Different Regimesmentioning

confidence: 70%

Optical Manipulation of nanoparticles by simultaneous electric and magnetic field enhancement within diabolo nanoantenna

Hameed

Ali

Baida

2017

Sci Rep

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In this paper, we propose and numerically simulate a novel optical trapping process based on the enhancement and the confinement of both magnetic and electric near-fields by using gold Diabolo Antenna (DA). The later was recently proposed to generate huge magnetic near-field when illuminated by linearly polarized wave along its axis. Numerical 3D – FDTD simulation results demonstrate the high confinement of the electromagnetic field in the vicinity of the DA. This enhancement is then exploited for the trapping of nano-particles (NP) as small as 30 nm radius. Results show that the trapping process greatly depends on the particle dimensions and that three different regimes of, trapping at contact, trapping without contact, or pushing can be achieved within the same DA. This doubly resonant structure opens the way to the design of a novel generation of efficient optical nano-tweezers that allow manipulation of nano-particles by simply changing the operation wavelength.

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“…3D optical trapping of 0.5 µ m latex beads was successfully conducted, which demonstrates that the device has promising applications such as biological and chemical probing and trapping. Similar structures could be found in several following works [216,217]. To overcome the fragility of the fiber taper-based optical trapping devices, a more robust structure was proposed by Gordon et al by engraving double nanohole aperture at the cleaved fiber end through FIB milling as shown in Figure 15c [218].…”

Section: Focused Ion Beam (Fib) Micro-machined Devicesmentioning

confidence: 62%

Recent Developments in Micro-Structured Fiber Optic Sensors

Chen

et al. 2017

Fibers

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Recent developments in fiber-optic sensing have involved booming research in the design and manufacturing of novel micro-structured optical fiber devices. From the conventional tapered fiber architectures to the novel micro-machined devices by advanced laser systems, thousands of micro-structured fiber-optic sensors have been proposed and fabricated for applications in measuring temperature, strain, refractive index (RI), electric current, displacement, bending, acceleration, force, rotation, acoustic, and magnetic field. The renowned and unparalleled merits of sensors-based micro-machined optical fibers including small footprint, light weight, immunity to electromagnetic interferences, durability to harsh environment, capability of remote control, and flexibility of directly embedding into the structured system have placed them in highly demand for practical use in diverse industries. With the rapid advancement in micro-technology, micro-structured fiber sensors have benefitted from the trends of possessing high performance, versatilities and spatial miniaturization. Here, we comprehensively review the recent progress in the micro-structured fiber-optic sensors with a variety of architectures regarding their fabrications, waveguide properties and sensing applications.

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Remote optical sensing on the nanometer scale with a bowtie aperture nano-antenna on a fiber tip of scanning near-field optical microscopy

Cited by 25 publications

References 24 publications

Tunable potential well for plasmonic trapping of metallic particles by bowtie nano-apertures

Tunable potential well for plasmonic trapping of metallic particles by bowtie nano-apertures

Optical Manipulation of nanoparticles by simultaneous electric and magnetic field enhancement within diabolo nanoantenna

Recent Developments in Micro-Structured Fiber Optic Sensors

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