Fully Solution‐Processed Photonic Structures from Inorganic/Organic Molecular Hybrid Materials and Commodity Polymers

Bachevillier, Stefan; Yuan, Hua-Kang; Strang, A.; Levitsky, Artem; Frey, Gitti L.; Hafner, Andreas; Bradley, Donal D. C.; Stavrinou, Paul N.; Stingelin, Natalie

doi:10.1002/adfm.201808152

Cited by 17 publications

(57 citation statements)

References 28 publications

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“…In order to scrutinize 3D laser machining as a methodology toward complex photonic structures, we selected titanium oxide hydrates/PVAl hybrids as model material system for RI patterning because it has been shown that this hybrid material's RI can be readily tuned via its composition and heat exposure. Indeed, an increase of the RI of up to 1.83 at 550 nm, induced upon a thermal treatment (multistep annealing on hot plate at 150 °C), has been reported, [ 19 ] achieved for a material of 60 vol% inorganic content. For such a hybrid material, e.g., made from TiCl 4 , the change in refractive index was attributed to the thermal activation of further hydrolysis and condensation reactions of OH and Cl groups present in the pristine hybrid material.…”

Section: Resultsmentioning

confidence: 99%

“…Accordingly, the presence of the inorganic species still leads to an increase in RI while keeping the light transmission high (no light scattering occurs as no nanoparticles or aggregates form) and the chromatic dispersion low. [18,19] Such hybrids offer many opportunities for optical device engineering, and they may pave the way for the straightforward design and fabrication of high-performance 3D photonic circuits, provided a suitable index patterning procedure is identified. The reason is that the overall light management in photonic devices requires precise patterning of the refractive index, ideally in two or three dimensions.…”

Section: Introductionmentioning

confidence: 99%

“…[ 34 ] Here, we demonstrate the relatively high‐resolution local enhancement of the refractive index by ultrashort pulse direct laser processing in solution‐processable inorganic/organic hybrid materials, thus approaching the requirements for use in high‐efficiency photonic devices and possible integration with standard light generation or sensor applications (e.g., LEDs, CCD/CMOS). [ 4 ] As model system, we selected an organic/inorganic hybrid material formed from poly(vinyl alcohol) (PVAl) cross‐linked with different contents of titanium oxide hydrates [ 19 ] to cover a broad RI range, prepared with a water‐based sol–gel method and deposited by spin coating starting from an aqueous solution. Through femtosecond laser micromachining, a large increase of the local RI (Δ n ≈ 10 −1 , up to n = 1.86 at 550 nm) with a transmittance >90% over the entire visible wavelength regime is obtained in the irradiated regions.…”

Section: Introductionmentioning

confidence: 99%

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Femtosecond Laser‐Induced Refractive Index Patterning in Inorganic/Organic Hybrid Films

Bonfadini

Nicolini

Storti

et al. 2022

Advanced Photonics Research

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The desire to increase the performance of optoelectronic devices has driven research into new, versatile optical materials. Among these, materials combinations composed of organic polymers and inorganic materials have sparked a strong interest due to the wide range of refractive indices that are obtainable. However, in parallel to these materials design and discovery activities, simple, broadly applicable fabrication techniques need to be advanced that are adapted to novel materials systems and allow, for instance, straightforward, large‐area manufacturing and integration of 3D photonic circuits. Herein, the use of a 3D direct writing laser technique is proposed to locally enhance the refractive index of a recently developed inorganic/organic molecular hybrid that is only composed of the commodity polymer poly(vinyl alcohol) cross‐linked with titanium oxide hydrates, for the creation of photonic structures. A spatially controlled refractive index increase of 0.13 between pristine and laser‐treated regions is achieved, with the potential of this adaptable 3D‐fabrication technique being demonstrated by manufacturing an optical diffraction grating. Considering that the synthesis and deposition of the hybrid material is water based and does not require toxic heavy metals, the work, thus, provides a processing and materials platform toward environment‐friendly, green processing of integrated photonic systems and beyond.

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Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Femtosecond Laser‐Induced Refractive Index Patterning in Inorganic/Organic Hybrid Films

Bonfadini

Nicolini

Storti

et al. 2022

Advanced Photonics Research

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“…The Bragg modes do not require precise layer thicknesses which means low-quality, low-cost DBRs such as all-plastic ones can be used. 37,38 Importantly, the color temperature depends on the DBR while the internal quantum efficiency depends on the preconversion OLED. Naturally, changing the emitter to something other than TDAF can also affect the color temperature.…”

Section: Discussionmentioning

confidence: 99%

“…Our device architecture does not depend on the substrate and incorporates metallic contacts instead of indium tin oxide films which are difficult to control and contain the scarce material indium. The Bragg modes do not require precise layer thicknesses which means low-quality, low-cost DBRs such as all-plastic ones can be used. , Importantly, the color temperature depends on the DBR while the internal quantum efficiency depends on the preconversion OLED. Naturally, changing the emitter to something other than TDAF can also affect the color temperature.…”

Section: Discussionmentioning

confidence: 99%

Converting an Organic Light-Emitting Diode from Blue to White with Bragg Modes

et al. 2019

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Organic light-emitting diodes (OLEDs) have been established as versatile light sources that allow for easy integration in large-area surfaces and flexible substrates. In addition, the low fabrication cost of OLEDs renders them particularly attractive as general lighting sources. Current methods for the fabrication of white-light OLEDs rely on the combination of multiple organic emitters and/or the incorporation of multiple cavity modes in a thick active medium. These architectures introduce formidable challenges in both device design and performance improvements, namely, the decrease of efficiency with increasing brightness (efficiency roll-off) and short operational lifetime. Here we demonstrate, for the first time, white-light generation in an OLED consisting of a sub-100 nm thick blue single-emissive layer coupled to the photonic Bragg modes of a dielectric distributed Bragg reflector (DBR). We show that the Bragg modes, although primarily located inside the DBR stack, can significantly overlap with the emissive layer, thus efficiently enhancing emission and outcoupling of photons at selected wavelengths across the entire visible light spectrum. Moreover, we show that color temperature can be tuned by the DBR parameters, offering great versatility in the optimization of white-light emission spectra.

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Simple and Versatile Platforms for Manipulating Light with Matter: Strong Light–Matter Coupling in Fully Solution‐Processed Optical Microcavities

Strang,

Quirós‐Cordero,

Grégoire

et al. 2023

Advanced Materials

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Planar microcavities with strong light–matter coupling, monolithically processed fully from solution, consisting of two polymer‐based distributed Bragg reflectors (DBRs) comprising alternating layers of a high‐refractive‐index titanium oxide hydrate/poly(vinyl alcohol) hybrid material and a low‐refractive‐index fluorinated polymer are presented. The DBRs enclose a perylene diimide derivative (b‐PDI‐1) film positioned at the antinode of the optical mode. Strong light–matter coupling is achieved in these structures at the target excitation of the b‐PDI‐1. Indeed, the energy‐dispersion relation (energy vs in‐plane wavevector or output angle) in reflectance and the group delay of transmitted light in the microcavities show a clear anti‐crossing—an energy gap between two distinct exciton‐polariton dispersion branches. The agreement between classical electrodynamic simulations of the microcavity response and the experimental data demonstrates that the entire microcavity stack can be controllably produced as designed. Promisingly, the refractive index of the inorganic/organic hybrid layers used in the microcavity DBRs can be precisely manipulated between values of 1.50 to 2.10. Hence, microcavities with a wide spectral range of optical modes might be designed and produced with straightforward coating methodologies, enabling fine‐tuning of the energy and lifetime of the microcavities‘ optical modes to harness strong light–matter coupling in a wide variety of solution processable active materials.

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Fully Solution‐Processed Photonic Structures from Inorganic/Organic Molecular Hybrid Materials and Commodity Polymers

Cited by 17 publications

References 28 publications

Femtosecond Laser‐Induced Refractive Index Patterning in Inorganic/Organic Hybrid Films

Femtosecond Laser‐Induced Refractive Index Patterning in Inorganic/Organic Hybrid Films

Converting an Organic Light-Emitting Diode from Blue to White with Bragg Modes

Simple and Versatile Platforms for Manipulating Light with Matter: Strong Light–Matter Coupling in Fully Solution‐Processed Optical Microcavities

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