Coherent Control of a Plasmonic Nanoantenna Integrated on a Silicon Chip

Espinosa-Soria, Alba; Pinilla-Cienfuegos, Elena; Díaz‐Fernández, Francisco J.; Griol, Amadeu; Martí, J.; Martı́nez, Alejandro

doi:10.1021/acsphotonics.8b00447

Cited by 28 publications

(32 citation statements)

References 31 publications

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“…This is quite striking since the fields in the evanescent region are much weaker than in the gap spacing two waveguides, wherein they are essentially similar to those in the waveguide core. [77,78] Yet, this configuration still retain common features with respect to the previous case, in particular, the peak position (or resonance frequency) dependent on the helix radius, and the intermodal conversion between L-and R-CPGM, and vice versa, as a result of the interaction between the CPGMs and the chiral structure (Figure 4b).…”

Section: Probing the Chiroptical Response In Dielectric Strip Waveguimentioning

confidence: 51%

“…Then, using an end-fire coupling setup, the light exiting the input waveguide will excite the chiral structure in the near-field, here acting as a probe. The output waveguide will collect the light both scattered by the structure and transmitted from waveguide to waveguide, [77,78] thus enabling the read-out of the chiroptical interaction. To account for the chiral spectral response, we first represent the transmission and mode conversion spectra for L-and R-CPGM (Figure 3b).…”

Section: Probing the Chiroptical Response In Dielectric Strip Waveguimentioning

confidence: 99%

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Toward Chiral Sensing and Spectroscopy Enabled by All‐Dielectric Integrated Photonic Waveguides

Vázquez‐Lozano

Martı́nez

2020

Laser & Photonics Reviews

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Chiral spectroscopy is a powerful technique enabling to identify optically the chirality of matter. So far, most experiments to check the chirality of matter or nanostructures have been performed through arrangements wherein both the optical excitation and detection are realized via circularly polarized light propagating in free space. However, for the sake of miniaturization, it would be desirable to perform chiral spectroscopy in photonic integrated platforms, with the additional benefit of massive parallel detection, low‐cost production, repeatability, and portability. Here it is shown that all‐dielectric photonic waveguides can support chiral modes under proper combination of fundamental eigenmodes. Two mainstream configurations are investigated: a dielectric wire with square cross section and a slotted waveguide. Three different scenarios in which such waveguides could be used for chiral detection are numerically analyzed: waveguides as near‐field probes, evanescent‐induced chiral fields, and chiroptical interaction in void slots. In all the cases, a metallic nanohelix is considered as a chiral probe, though all the approaches can be extended to other kinds of chiral nanostructures as well as matter. These results establish that chiral applications such as sensing and spectroscopy could be realized in standard integrated optics, in particular, with silicon‐based technology.

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Section: Probing the Chiroptical Response In Dielectric Strip Waveguimentioning

confidence: 51%

Section: Probing the Chiroptical Response In Dielectric Strip Waveguimentioning

confidence: 99%

Toward Chiral Sensing and Spectroscopy Enabled by All‐Dielectric Integrated Photonic Waveguides

Vázquez‐Lozano

Martı́nez

2020

Laser & Photonics Reviews

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“…The intense near-field in such regions can be used to boost the weak intensity of signals generated by the analytes of interest, such as Raman scattering in SERS. Plasmonic nano-antennas can be integrated onto optical waveguides, leading to the realization of integrated plasmonic sensors, which combine the signal enhancement of the plasmonic structures with the miniaturization, scaling and interfacing provided by the integrated waveguides [6][7][8][9][10][11][12]. Given the subwavelength dimensions of plasmonic nano-antennas and considering the inverse relationship between the Raman scattering cross-section and wavelength used, 785 nm is one the most used wavelengths to perform this technique since it offers a compromise between performance and technological requirements.…”

Section: Introductionmentioning

confidence: 99%

Double metal layer lift-off process for the robust fabrication of plasmonic nano-antenna arrays on dielectric substrates using e-beam lithography

Muñoz

Yong

Dijkstra

et al. 2019

Opt. Mater. Express

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Integrated plasmonic sensors often require the nanofabrication of metallic structures on top of dielectric substrates by nanolithographic methods such as electron beam lithography (EBL). One of the preferred metals for the realization of such nanostructures is gold given both its corrosion resistance and favorable refractive index in the visible and NIR regions. Due to its inert nature, gold offers very poor adhesion to dielectric layers, therefore often requiring the deposition of a thin metallic layer as adhesion promoter. The presence of this layer has a negative influence on the plasmonic behavior of the resulting nano-antennas. Thus, the thickness of the adhesion layer should be kept as thin as possible. Moreover, the use of EBL on non-conductive substrates leads to charge accumulation in the isolating materials (i.e., charging effect), which degrades the resolution of the lithography. A possible solution to this problem is the use of an anti-charging layer under the electron sensitive resist, which should be thick enough to offer high conductivity. In this work, we present a nanofabrication process that decouples the contradicting requirements for the metal layers, permitting to independently optimize both the thickness and type of the metal used as anti-charging layer and as adhesion layer underneath the nanostructures. Additionally, the proposed method permits eliminating any metal residue during the lift-off process, leading to a perfectly clean device outside the nanostructured region, which is instrumental when the nanostructures are to be integrated with other photonic functions on the chip.

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“…Given the importance of the evanescent field profile over the sensing performance, the near-field behavior of the PBG sensing structures has been studied using SNOM technology, which has been used in previous works to characterize SOI structures as nanoatennas Espinosa-Soria et al, 2018). SNOM measurements were performed with a tailored MultiView 4000 system (Nanonics Imaging Ltd.) working in collection mode as schematized below (see figure 4.2).…”

Section: Scanning Near Field Optical Microscope (Snom) Characterizationmentioning

confidence: 99%

“…To this aim, FDTD simulations were done using CST Microwave Studio, which is specially created to solve electromagnetic problems in three dimensions where the working frequencies are high, as it is the case that concerns us. For our simulations, a 61 period PBG structure has been considered, such as for the one manufactured (Espinosa-Soria et al, 2018). To perform the system of equations that the simulation resolves, a hexahedral type mesh has been performed with 1.34 million cells, with at least 4 divisions per wavelength.…”

Section: Scanning Near Field Optical Microscope (Snom) Characterizationmentioning

confidence: 99%

Combination of nanophotonic biosensors and light-assisted immobilization procedures for the detection of cardiac biomarkers

Sabek¹

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Coherent Control of a Plasmonic Nanoantenna Integrated on a Silicon Chip

Cited by 28 publications

References 31 publications

Toward Chiral Sensing and Spectroscopy Enabled by All‐Dielectric Integrated Photonic Waveguides

Toward Chiral Sensing and Spectroscopy Enabled by All‐Dielectric Integrated Photonic Waveguides

Double metal layer lift-off process for the robust fabrication of plasmonic nano-antenna arrays on dielectric substrates using e-beam lithography

Combination of nanophotonic biosensors and light-assisted immobilization procedures for the detection of cardiac biomarkers

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