Towards the integration of nanoemitters by direct laser writing on optical glass waveguides

Xu, Xiaolun; Broussier, Aurélie; Ritacco, Tiziana; Nahra, Mackrine; Geoffray, Fabien; Issa, Ali; Jradi, Safi; Bachelot, Renaud; Couteau, Christophe; Blaize, Sylvain

doi:10.1364/prj.392706

Cited by 17 publications

(19 citation statements)

References 55 publications

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“…45 Fe2O3 NPs are prepared following the procedure mentioned in Nigam's et al article. 48 The synthesized solutions are used directly for immersion process without any dilution. Commercial PSNPs solution (size~ 800 nm, 4% solid in 5 mL H2O) is diluted 500 times in water and nanodiamonds solution (1 mg / 1 mL H2O) is diluted 100 times in water.…”

Section: Methodsmentioning

confidence: 99%

“…Controlling the number of QDs and their positioning is a very important asset for nano-optics where the selective integration of nano-emitters with high spatial resolution on waveguides and on plasmonic devices is needed. [47][48][49] The ability to manipulate light at the nanoscale is one of the most important features in integrated photonic quantum technologies. However, conventional optical devices suffer from the diffraction limit of light.…”

Section: The Importance Of the Monomer Functionalization Is Shown Inmentioning

confidence: 99%

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One Strategy for Nanoparticle Assembly onto 1D, 2D, and 3D Polymer Micro and Nanostructures

Issa

Izquierdo

Merheb

et al. 2021

ACS Appl. Mater. Interfaces

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The integration of nanoparticles (NPs) into photonic devices and plasmonic sensors requires selective patterning of these NPs with fine control of their size, shape and spatial positioning. In this article, we report on a general strategy to pattern different types of NPs. This strategy involves the functionalization of photopolymers before their patterning by two-photon laser writing to fabricate micro-and nanostructures that selectively attract colloidal 2 NPs with suitable ligands, allowing their precise immobilization and organization even within complex 3D structures. Monolayers of NPs without aggregations are obtained and the surface density of NPs on the polymer surface can be controlled by changing either the time of immersion in the colloidal solution or the type of amine molecule chemically grafted on the polymer surface. Different types of NPs (gold, silver, polystyrene, iron oxide, colloidal quantum dots and nanodiamonds) of different sizes are introduced showing a potential towards nanophotonic applications. To validate the great potential of our method, we successfully demonstrate the integration of quantum dots within a gold nanocube with high spatial resolution and nanometer precision. The promise of this hybrid nano-source of light (plasmonic/polymer/QDs) as optical nanoswitch is illustrated through photoluminescence measurements under polarized exciting light.

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Section: Methodsmentioning

confidence: 99%

Section: The Importance Of the Monomer Functionalization Is Shown Inmentioning

confidence: 99%

One Strategy for Nanoparticle Assembly onto 1D, 2D, and 3D Polymer Micro and Nanostructures

Issa

Izquierdo

Merheb

et al. 2021

ACS Appl. Mater. Interfaces

Self Cite

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“…In particular, UCNPs based on the energy transfer mechanism between sensitized and activator dopants have been extensively developed in recent years due to the capabilities of the chemical synthesis, their chemical endurance, low toxicity and excellent optical stability (Wang et al, 2010;Chen et al, 2014). Luminescent NCPRs have many applications: photo-curing of PRs with embedded QDs has been studied for on-chip detection of heavy metal ions (Xu et al, 2013), bar-coding particles (Zhao et al, 2011), development of high quality displays (Li et al, 2019c) and deterministic integration of quantum emitters into waveguides (Lio et al, 2019;Xu et al, 2020b), nanoantennas (Broussier et al, 2019) and remotely controllable magnetic structures (Au et al, 2020). A recent review by Smith et al contains a section on lithographically pattered QD NCPRs (Smith et al, 2019).…”

Section: Luminescent Nanofillersmentioning

confidence: 99%

Recent Advances on Nanocomposite Resists With Design Functionality for Lithographic Microfabrication

et al. 2021

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Nanocomposites formed by a phase-dispersed nanomaterial and a polymeric host matrix are highly attractive for nano- and micro-fabrication. The combination of nanoscale and bulk materials aims at achieving an effective interplay between extensive and intensive physical properties. Nanofillers display size-dependent effects, paving the way for the design of tunable functional composites. The matrix, on the other hand, can facilitate or even enhance the applicability of nanomaterials by allowing their easy processing for device manufacturing. In this article, we review the field of polymer-based nanocomposites acting as resist materials, i.e. being patternable through radiation-based lithographic methods. A comprehensive explanation of the synthesis of nanofillers, their functionalization and the physicochemical concepts behind the formulation of nanocomposites resists will be given. We will consider nanocomposites containing different types of fillers, such as metallic, magnetic, ceramic, luminescent and carbon-based nanomaterials. We will outline the role of nanofillers in modifying various properties of the polymer matrix, such as the mechanical strength, the refractive index and their performance during lithography. Also, we will discuss the lithographic techniques employed for transferring 2D patterns and 3D shapes with high spatial resolution. The capabilities of nanocomposites to act as structural and functional materials in novel devices and selected applications in photonics, electronics, magnetism and bioscience will be presented. Finally, we will conclude with a discussion of the current trends in this field and perspectives for its development in the near future.

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“…Due to the low propagation losses of 0.059 dB∕cm 22 and high process homogeneity, integrated functions can be focused in the future. On wafer level and on laboratory scale, multiple functions could be presented, 23 with just one of many examples being direction coupler 24 Y-junctions. 25 In recent years, sensing applications using quantum dots 26,27 and surface plasmon polaritons 28 were also developed.…”

Section: Glass Integrated Waveguidesmentioning

confidence: 99%

Hybrid photonic system integration using thin glass platform technology

Schröder

Schwietering

Bottger

et al. 2021

J. Optical Microsystems

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Demand for high integration of optoelectronic and micro-optical components into micro-electronic systems for communication, computing, medical, and sensing applications is increasing. Advanced hybrid packaging technologies are used to enhance glass-based substrates featuring electrical, thermal, and optical functionalities with laser diodes, modulators, isolators, photonic integrated circuits (PIC), beam-splitting components, and micro-lenses. Such glassbased substrates can be thin glass layers on large panels or more mini-bench-like boards that can be embedded into organic printed circuit boards (PCBs). Optical fiber interconnects, connectors, and electrical-optical integration platforms are used for higher level system integration and need to be miniaturized on module and board level to fulfill decreasing channel pitch requirements. We provide background on and discuss thin glass as a suitable base material for ion exchanged waveguide panels and interposers, precise glass structuring for posts and holders, the related high precision assembly techniques, and advanced fiber interconnects. Some examples of PCB photonic integration, micro-bench optical sub-assemblies, including PIC, and 3D optical resonator packages that combine most of these approaches will be shown. © The Authors.Published by SPIE under a Creative Commons Attribution 4.0 Unported License. Distribution or reproduction of this work in whole or in part requires full attribution of the original publication, including its DOI.

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Towards the integration of nanoemitters by direct laser writing on optical glass waveguides

Cited by 17 publications

References 55 publications

One Strategy for Nanoparticle Assembly onto 1D, 2D, and 3D Polymer Micro and Nanostructures

One Strategy for Nanoparticle Assembly onto 1D, 2D, and 3D Polymer Micro and Nanostructures

Recent Advances on Nanocomposite Resists With Design Functionality for Lithographic Microfabrication

Hybrid photonic system integration using thin glass platform technology

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