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140 results on '"photonic structure"'

1. Self‐Assembled Colloidal Photonic Structures for Directional Radioluminescence of Gd and Ta Oxide Scintillators.

Author

Strassberg, Rotem, Nakanishi, Akihiro, Shamaev, Betty, Katznelson, Shaul, Schuetz, Roman, Dosovitskiy, Georgy, Levy, Shai, Be'er, Orr, Shaek, Saar, Onoe, Tomoya, Maekawa, Taiki, Hayakawa, Rino, Tsuji, Kazuma, Murai, Kei‐ichiro, Moriga, Toshihiro, and Bekenstein, Yehonadav

Subjects
*PHOTONIC band gap structures, *VISIBLE spectra, *RADIOLUMINESCENCE, *CRYSTAL surfaces, *SCINTILLATORS, *PHOTONIC crystals
Abstract

Radiation detection is being revolutionized by integrating photonic elements into scintillators. In this study, a scalable and cost‐effective method is proposed to achieve tuneable emission enhancement across the visible spectrum by colloidal self‐assembly of photonic crystals on scintillator surfaces. This concept is demonstrated for Eu3+/Tb3+‐doped Gd and Ta oxides. Widely available and affordable colloidal nanospheres of SiO2 or polymethyl methacrylate are self‐assembled on these scintillators. The size of the nanospheres is carefully optimized to match the desired emission lines of Eu3+/Tb3+. The result is homogeneous and closely‐packed structures with clear photonic bandgap in the visible range. Under X‐ray excitation, the scintillators covered with the photonic layers exhibit enhanced light extraction in the direction perpendicular to the surface, compared to isotropic emission in the bare scintillator. Such scintillation directionality, when optically matched with a proper detector, will result in higher efficiency of the overall detection system. Moreover, X‐ray imaging demonstrates an enhancement of 25% in system resolution of the scintillator supplemented with the photonic layer compared to unmodified scintillators. The proposed method is scintillator‐ and nanosphere‐agnostic, thus offering a promising versatile approach for directing the scintillation light toward a photodetector and increasing detection system performance, including high‐resolution imaging applications. [ABSTRACT FROM AUTHOR]

Published
2024
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2. Construction of the single-diamond-structured titania scaffold-Recreation of the holy grail photonic structure.

Author

Chao Wang, Congcong Cui, Quanzheng Deng, Chong Zhang, Shunsuke Asahina, Yuanyuan Cao, Yiyong Mai, Shunai Che, and Lu Han

Subjects
*ETHYLENE oxide, *DIAMOND surfaces, *MINIMAL surfaces, *DISCONTINUOUS precipitation, *SPACE groups
Abstract

As one of the most stunning biological nanostructures, the single-diamond (SD) surface discovered in beetles and weevils exoskeletons possesses the widest complete photonic bandgap known to date and is renowned as the "holy grail" of photonic materials. However, the synthesis of SD is difficult due to its thermodynamical instability compared to the energetically favoured bicontinuous double diamond and other easily formed lattices; thus, the artificial fabrication of SD has long been a formidable challenge. Herein, we report a bottom-up approach to fabricate SD titania networks via a one-pot cooperative assembly scenario employing the diblock copolymer poly(ethylene oxide)-block-polystyrene as a soft template and titanium diisopropoxide bis(acetylacetonate) as an inorganic precursor in a mixed solvent, in which the SD scaffold was obtained by kinetically controlled nucleation and growth in the skeletal channels of the diamond minimal surface formed by the polymer matrix. Electron crystallography investigations revealed the formation of tetrahedrally connected SD frameworks with the space group Fd 3 m in a polycrystalline anatase form. A photonic bandgap calculation showed that the resulting SD structure has a wide and complete bandgap. This work solves the complex synthetic enigmas and offers a frontier in hyperbolic surfaces, biorelevant materials, next-generation optical devices, etc. [ABSTRACT FROM AUTHOR]

Published
2024
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3. Optical Biosensor in a One-Dimensional Photonic Structure with Bound States in the Continuum.

Author

Ravshanjon Nazarov and Zarina Sadrieva

Abstract

In this paper, we present the main results of the numerical calculation of the bound states in the continuum (BICs) application in the refractive index (RI) sensing. We consider two types of one-dimensional rectangular photonic structure at subwavelength regime and study the Fano resonance shift for off-Γ BIC. The results obtained will make it possible to create photonic structures for biosensing, for which a high-Q resonance is observed at nonzero incidence angles. [ABSTRACT FROM AUTHOR]

Published
2023
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4. Aptameric photonic structure-based optical biosensor for the detection of microcystin.

Author

Hussain, Saddam, Al-Tabban, Awatef, and Zourob, Mohammed

Subjects
*CHOLESTERIC liquid crystals, *BIOSENSORS, *POLYACRYLIC acid, *APTAMERS, *HYDROGEN bonding
Abstract

An optical photonic biosensor for the detection of microcystin (MC) has been developed using an aptamer-immobilized interpenetrating polymeric network (IPN aptamer) intertwined with solid-state cholesteric liquid crystals (CLC solid s). The IPN was constructed with a polyacrylic acid hydrogel (PAA). Aptamer immobilization enhances polarity while blocking hydrogen bonding between the carboxylic groups of PAA-IPN hydrogel, thereby increasing the swelling ratio of the PAA-IPN hydrogel. This leads to an expansion in the helical pitch of the corresponding IPN aptamer -CLC solid biosensor chip and results in a red-shift in the reflected color. Upon exposure to an aqueous MC solution, the IPN aptamer -CLC solid biosensor chip exhibits aptamer-mediated engulfment of MC, resulting in reduced polarity of the IPN aptamer complex and a consequential blue-shift in the biosensor chip color occurred. The wavelength shift of the IPN aptamer -CLC solid biosensor chip demonstrates a linear change with an increase in MC concentration from 3.8 to 150 nM, with a limit of detection of 0.88 nM. This novel optical biosensor is characterized by its low cost, simplicity, selectivity, and sensitivity, offering a promising strategy for designing similar toxin biosensors through the modification of biological receptors. [ABSTRACT FROM AUTHOR]

Published
2024
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5. An Ultrathin Transparent Radiative Cooling Photonic Structure with a High NIR Reflection.

Author

Dang, Saichao, Wang, Xiaojia, and Ye, Hong

Subjects
COOLING, ZINC oxide films, VISIBLE spectra, HEAT radiation & absorption, SOLAR radiation, INFRARED radiation
Abstract

With a high NIR reflection, a transparent radiative cooling photonic structure consisting of 2D silica gratings atop ZnO/Ag/ZnO is conceived and demonstrated. With 77% visible light transmitted, 57% NIR solar radiation reflected and 91% thermal infrared radiation emitted, a synthetical cooling is realized by this photonic structure. The theoretical total cooling power of this structure is more than double that of a planar silica and is 63.3% higher than that of a typical NIR reflecting filter, that is, ZnO/Ag/ZnO film. The field test facing the sunlight shows that the air temperature inside a chamber sealed with this structure is 12.5 and 2.5 °C lower than that sealed with planar silica and ZnO/Ag/ZnO, respectively. This work shows that the concept of daytime radiative cooling can be applied in combination with the utilization of visible light and the proposed ultrathin photonic structure shows potentials for passive radiative cooling of transparent applications. [ABSTRACT FROM AUTHOR]

Published
2022
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6. Logical OR operation and magnetic field sensing based on layered topology.

Author

Sui, Junyang, Zhang, Dan, and Zhang, Haifeng

Subjects
*MAGNETIC fields, *MAGNETIC field effects, *ELECTROMAGNETIC waves, *PHOTONIC crystals, *MAGNETOOPTICS, *DETECTION limit
Abstract

A one-dimensional magnetized InSb photonic crystals layered topology (PCLT) proposed in this paper can realize the functions of logic OR operation and magnetic field sensing. In the proposed PCLT, under the transverse magnetic polarization, the value and frequency of the absorption peak (AP) can be controlled by the external magnetic fields and has a high-quality factor (Q), thus OR logical operation can be achieved. Additionally, since InSb has a magneto-optical effect under magnetic fields, the parity of the structure of the PCLT which adds InSb as defect layers can be broken. Electromagnetic waves obtain nonreciprocity when propagating in opposite directions within the PCLT, which means that logical operation and magnetic field sensing based on AP can be obtained on the forward and backward scales. For the detection, on the forward scale, optimum performances of Q, sensitivity (S), the figure of merit, and detection limit are 62 372.09, 0.0169 (2 Ď€c / d) /T, 4225 Tâˆ'1, 1.2 Ă— 10âˆ'5 T, and for the backward detection, the corresponding values are 63 626.25, 0.0225 (2 Ď€c / d) /T, 5200 Tâˆ'1, 1 Ă— 10âˆ'5 T. The designed PCLT is innovative in multi-functional and multi-scale, having certain research value and prospects. [ABSTRACT FROM AUTHOR]

Published
2022
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7. Optical sensor for butylamine vapour based on the photonic structure infiltrated by liquid crystal.

Author

Zhang, Yuxian, Yang, Zhou, and Wang, Qiong-Hua

Subjects
*OPTICAL sensors, *PHOTONIC band gap structures, *VAPORS, *CHOLESTERIC liquid crystals
Abstract

We propose an optical sensor based on the inverse opal (IOP) photonic structure infiltrated by a typical liquid crystalline material doped by the reactive compounds. Benefiting from the unique photonic property of the IOP structure, the composite sensor shows not only a typical textural change but also a responsive photonic band gap (PBG) upon the exposure to butylamine (BA) vapour, due to the reorientation of the liquid crystalline molecules induced by the chemical reaction between the dopant and the BA vapour. This approach simplifies the measurement process by capturing the PBG signal instead of the polarised optical texture, which does not require high cost or complex instruments and might be instructive for detecting other volatiles. [ABSTRACT FROM AUTHOR]

Published
2022
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8. TiO 2 Films with Macroscopic Chiral Nematic-Like Structure Stabilized by Copper Promoting Light-Harvesting Capability for Hydrogen Generation.

Author

Wang C, Mouchet SR, Deparis O, Li J, Paineau E, Dragoe D, Remita H, and Ghazzal MN

Abstract

Cellulose nanocrystals (CNCs) have inspired the synthesis of various advanced nanomaterials, opening opportunities for different applications. However, a simple and robust approach for transferring the long-range chiral nematic nanostructures into TiO 2 photocatalyst is still fancy. Herein, a successful fabrication of freestanding TiO 2 films maintaining their macroscopic chiral nematic structures after removing the CNCs biotemplate is reported. It is demonstrated that including copper acetate in the sol avoids the epitaxial growth of the lamellar-like structure of TiO 2 and stabilizes the chiral nematic structure instead. The experimental results and optical simulation demonstrate an enhancement at the blue and red edges of the Fabry-Pérot reflectance peak located in the visible range. This enhancement arises from the light scattering effect induced by the formation of the chiral nematic structure. The nanostructured films showed 5.3 times higher performance in the photocatalytic hydrogen generation, compared to lamellar TiO 2 , and benefited from the presence of copper species for charge carriers' separation. This work is therefore anticipated to provide a simple approach for the design of chiral nematic photocatalysts and also offers insights into the electron transfer mechanisms on TiO 2 /Cu x O with variable oxidation states for photocatalytic hydrogen generation., (© 2024 The Author(s). Small published by Wiley‐VCH GmbH.)

Published
2024
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9. Recent progress in terahertz modulation using photonic structures based on two‐dimensional materials

Author

Ziming Wang, Jie Qiao, Shuqi Zhao, Shilei Wang, Chuan He, Xutang Tao, and Shanpeng Wang

Subjects
2D material, optoelectronic device, photonic structure, terahertz modulation, Materials of engineering and construction. Mechanics of materials, TA401-492, Information technology, T58.5-58.64
Abstract

Abstract Terahertz (THz) technology has attracted great attention in the past few decades for its unique applications in various fields, including spectroscopy, noninvasive detection, wireless communications, and imaging. In parallel to this, the practical, fast, and broadband modulation of THz waves is becoming indispensable. Two‐dimensional (2D) materials exhibit unusual optical and electrical properties, which has prompted tremendous interest and significant advances in THz modulation. This review provides the recent progress in 2D materials‐based THz modulators, outlining the operating principles, including all‐optical, electro‐optic, magneto‐optic, and other exotic mechanisms. We focus on the recent advances in THz modulation by the designed photonic structures, such as heterostructure, metamaterial, capacitor, optical cavity, and waveguide integration. Lastly, we discussed the challenges and opportunities for 2D materials‐based THz modulators and presented our prospects for the future development.

Published
2021
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10. Iridescence and circular dichroism in cellulose nanocrystal thin films

Author

Hewson, Daniel James and Eichhorn, Stephen

Subjects
530, Nanocrystallline cellulose, Iridescence, Bragg stack, layer by layer assembly, Photonic structure
Abstract

Only in recent times has the true potential of cellulose as a high-end functional and sustainable material been realised. As the world’s most abundant resource cellulose has been utilised by man throughout history for timber, paper and yarns. It is found in every plant as a hierarchical material and can be extracted and converted into fibres which are of great use, especially in the form of nanofibrous materials. This thesis has focused on the utilisation and ability of cellulose nanocrystals (CNCs) to generate structural colour in fabricated thin films. This has been achieved in two ways: Firstly, the natural morphology of CNCs and their ability to form a suspension have been applied to a layer-by-layer (LbL) regime to produce tunable Bragg reflecting thin films. Secondly, a novel technique combining profilometry and spectroscopy has been developed to estimate the distribution of CNCs within EISA thin films and correlate this with the optical properties of the film. This thesis reports the successful fabrication of synthetic CNC LbL Bragg reflecting thin films. The film was compiled using an additive layer-by-layer technique which allowed the construction of a multi-layered thin film and control over individual layer thicknesses and refractive index. Also reported is the discovered reflection of both left and right handed circularly polarised light (CPL) from CNC EISA thin films. These reflections were found to correlate with CNC distribution within the thin films. The distribution of CNCs was estimated using a novel technique which combined spectroscopically measured film absorbance as a function of the volume of the film area under investigation. The specific volumes were calculated using profilometry measurements and the beam spot size used in the spectroscopy measurements.

Published
2017

11. Computational Modelling of Doubly‐Photopolymerized Holographic Biosensors.

Author

Davies, Samuel, Hu, Yubing, Guo, Dasan, Jiang, Nan, Montelongo, Yunuen, Naydenova, Izabela, and Yetisen, Ali K.

Subjects
*HOLOGRAPHIC gratings, *CROSSLINKED polymers, *OPTICAL devices, *REFRACTIVE index, *PHOTONIC crystals, *OPTICAL sensors, *BIOCOMPATIBILITY, *BIOSENSORS
Abstract

Holographic sensors are optical devices capable of tuning reflection wavelength, dependent upon nanostructured variations in refractive index. Computational modelling is utilized to simulate the recording and swelling characteristics of developed doubly photopolymerized (DP) holographic sensors. The holographic devices simplify fabrication processes, reduce financial costs, and improve biocompatibility. A holographic grating is achieved through in situ photopolymerization of a highly crosslinked polymer to produce nanostructured refractive index modulation. The unique swelling characteristics DP holographic sensors possess necessitate the development of system‐specific computational modelling. Hydrogel parameters, including film thickness, refractive index change, layer number, and external medium refractive index are examined for their effect on reflection spectra. Optimized computational models are utilized to study the effect of differential swelling rates of individual layer spacings on sensor response, indicating an idealized reduction in a swelling of 50% for the highly crosslinked region. A 2D photonic crystal geometry with additional periodicity is developed, to inform further sensor design opportunities. Optimized parameters for both 1D and 2D photonic structures will assist the further development of DP holographic sensors. [ABSTRACT FROM AUTHOR]

Published
2022
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12. A multifunctional and multiscale device of magnetic-controlled AND logical operation and detection based on the nonreciprocity of the magnetized InSb photonic structure

Author

Si-Si Rao, Jia-Tao Zhang, and Hai-Feng Zhang

Subjects
Nonreciprocity, Magneto-optical effect, Logical operation, Detection, Multiscale devices, Photonic structure, Physics, QC1-999
Abstract

In this article, a multifunctional and multiscale device which can realize the functions of the magnetic-controlled AND logical operation and detection based on the one-dimensional magnetized InSb photonic structure is proposed and theoretically investigated. Properly modulating the target resonant absorption peak by the external magnetic field, and employing the peak to determine the logical operation, the accurate AND logical operation is fulfilled. Since the target absorption peak holds a superior quality factor value, the designed structure can be considered for detecting the crucial physical quantities, magnetic field, and refractive index. Especially, owing to the magneto-optical effect, time-reversal symmetry and space-reversal symmetry are broken, and the nonreciprocity is generated, which further makes the logical operations and detection of the forward and backward scales can be simultaneously acquired. Numerical analysis gains the optimal sensitivity, the quality value and detection limit. For the detection of magnetic field, and refractive index are 3.13 × 1012 T−1, 9341, 8.4 × 10−5 T, and 1.13 × 1011 RIU−1, 10537, 5.6 × 10−4 RIU, respectively. Surpassing the conventional electromagnetic devices, the designed photonic structure in this work with the combination of magnetic-controlled AND logical operation and detection functions plays a significant constructive role in information communication and photonic computing.

Published
2021
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13. Recent progress in terahertz modulation using photonic structures based on two‐dimensional materials.

Author

Wang, Ziming, Qiao, Jie, Zhao, Shuqi, Wang, Shilei, He, Chuan, Tao, Xutang, and Wang, Shanpeng

Abstract

Terahertz (THz) technology has attracted great attention in the past few decades for its unique applications in various fields, including spectroscopy, noninvasive detection, wireless communications, and imaging. In parallel to this, the practical, fast, and broadband modulation of THz waves is becoming indispensable. Two‐dimensional (2D) materials exhibit unusual optical and electrical properties, which has prompted tremendous interest and significant advances in THz modulation. This review provides the recent progress in 2D materials‐based THz modulators, outlining the operating principles, including all‐optical, electro‐optic, magneto‐optic, and other exotic mechanisms. We focus on the recent advances in THz modulation by the designed photonic structures, such as heterostructure, metamaterial, capacitor, optical cavity, and waveguide integration. Lastly, we discussed the challenges and opportunities for 2D materials‐based THz modulators and presented our prospects for the future development. [ABSTRACT FROM AUTHOR]

Published
2021
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15. Direct writing of colloidal suspensions onto inclined surfaces: Optimizing dispense volume for homogeneous structures.

Author

Winhard, Benedikt F., Haugg, Stefanie, Blick, Robert, Schneider, Gerold A., and Furlan, Kaline P.

Subjects
*COLLOIDAL suspensions, *SILICA gel, *POLYSTYRENE, *COLLOIDS, *COLLOIDAL crystals, *SILICA, *UNIFORMITY
Abstract

[Display omitted] A process to fabricate structures on inclined substrates has the potential to yield novel applications for colloidal-based structures. However, for conventional techniques, besides the coffee ring effect (CRE), anisotropic particle deposition along the inclination direction (IE) is expected to occur. We hypothesize that both effects can be inhibited by reducing the dispense volume during printing by direct writing. We combined an additive manufacturing technique, namely direct writing, with colloidal assembly (AMCA) for an automated and localized drop-cast of polystyrene and silica suspensions onto inclined surfaces. Herein, we investigated the influence of the substrate tilting angle and the dispense volume on the printing of colloids and the resulting structures' morphology. The results demonstrate that a reduction in the dispense volume hinders the CRE and IE for both particles' systems, even though the evaporation mode is different. For polystyrene, the droplets evaporated solely in stick-mode, enabling a "surface capturing effect", while for silica, droplets evaporated in mixed stick–slip mode and a "confinement effect" was observed, which improved uniformity of the deposition. These findings were used to generate a model of the critical droplet radius needed to print homogeneous colloidal-based structures onto inclined substrates. [ABSTRACT FROM AUTHOR]

Published
2021
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16. Functional photonic structures for external interaction with flexible/wearable devices.

Author

Yoo, Young Jin, Heo, Se-Yeon, Kim, Yeong Jae, Ko, Joo Hwan, Mira, Zafrin Ferdous, and Song, Young Min

Abstract

In addition to vital functions, more subsidiary functions are being expected from wearable devices. The wearable technology thus far has achieved the ability to maintain homeostasis by continuously monitoring physiological signals. The quality of life improves if, through further developments of wearable devices to detect, announce, and even control unperceptive or noxious signals from the environment. Soft materials based on photonic engineering can fulfil the abovementioned functions. Due to the flexibility and zero-power operation of such materials, they can be applied to conventional wearables without affecting existing functions. The achievements to freely tailoring a broad range of electromagnetic waves have encouraged the development of wearable systems for independent recognition/manipulation of light, pollution, chemicals, viruses and heat. Herein, the role that photonic engineering on a flexible platform plays in detecting or reacting to environmental changes is reviewed in terms of material selection, structural design, and regulation mechanisms from the ultraviolet to infrared spectral regions. Moreover, issues emerging with the evolution of the wearable technology, such as Joule heating, battery durability, and user privacy, and the potential solution strategies are discussed. This article provides a systematic review of current progress in wearable devices based on photonic structures as well as an overview of possible ubiquitous advances and their applications, providing diachronic perspectives and future outlook on the rapidly growing research field of wearable technology. [ABSTRACT FROM AUTHOR]

Published
2021
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17. Single-layer graphene-based electrically-magnetically tunable multi-mode and broadband terahertz absorber: A comprehensive study.

Author

Mahesh, Pulimi, Panigrahy, Damodar, and Nayak, Chittaranjan

Subjects
*TERAHERTZ materials, *TRANSFER matrix, *REFRACTIVE index, *MAGNETIC fields, *GRAPHENE
Abstract

In this work, the narrowband and broadband absorption characteristics of single layer graphene-based photonic structures are investigated. The optical features were determined utilizing the 4 × 4 transfer matrix method. The results indicate that the proposed design incorporating monolayer graphene achieves absorption rates exceeding 90% across a bandwidth of 1.8 THz. Additionally, the suggested photonic configuration has the potential to function as a triple-mode narrowband absorber through the alteration of layer positioning or the substitution of materials. The numerical relationships between the refractive indexes of materials A, B, and C have been formulated to facilitate broadband and narrowband absorption. The absorption characteristics of the proposed design have been significantly influenced by the Fermi-level of Graphene and the magnetic field. The results indicate that the absorption value of both broadband and narrowband absorbers can be dynamically adjusted by manipulating the Fermi-level of Graphene and magnetic field. The photonic configuration being proposed presents novel opportunities for the development of electrically and magnetically tunable narrowband and broadband absorbers. • The proposed design can offer both broadband and multi-mode narrowband absorption. • The triple-mode narrowband absorption with a value greater than 95% achieved. • The proposed novel design provided broadband absorption over a bandwidth of 1.8 THz. • Formulated numerical relations for broadband and multi-mode absorption. • The design enables dynamic absorption tuning via electrical and magnetic biassing. [ABSTRACT FROM AUTHOR]

Published
2024
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18. Construction of the single-diamond-structured titania scaffold-Recreation of the holy grail photonic structure.

Author

Wang C, Cui C, Deng Q, Zhang C, Asahina S, Cao Y, Mai Y, Che S, and Han L

Abstract

As one of the most stunning biological nanostructures, the single-diamond (SD) surface discovered in beetles and weevils exoskeletons possesses the widest complete photonic bandgap known to date and is renowned as the "holy grail" of photonic materials. However, the synthesis of SD is difficult due to its thermodynamical instability compared to the energetically favoured bicontinuous double diamond and other easily formed lattices; thus, the artificial fabrication of SD has long been a formidable challenge. Herein, we report a bottom-up approach to fabricate SD titania networks via a one-pot cooperative assembly scenario employing the diblock copolymer poly(ethylene oxide)- block -polystyrene as a soft template and titanium diisopropoxide bis(acetylacetonate) as an inorganic precursor in a mixed solvent, in which the SD scaffold was obtained by kinetically controlled nucleation and growth in the skeletal channels of the diamond minimal surface formed by the polymer matrix. Electron crystallography investigations revealed the formation of tetrahedrally connected SD frameworks with the space group Fd [Formula: see text] m in a polycrystalline anatase form. A photonic bandgap calculation showed that the resulting SD structure has a wide and complete bandgap. This work solves the complex synthetic enigmas and offers a frontier in hyperbolic surfaces, biorelevant materials, next-generation optical devices, etc., Competing Interests: Competing interests statement:The authors declare no competing interest.

Published
2024
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19. Photonic Interpenetrating Polymer Network Fibers Comprising Intertwined Solid-State Cholesteric Liquid Crystal and Polyelectrolyte Networks for Sensor Applications.

Author

Adane AM and Park SY

Abstract

Uniform-sized photonic interpenetrating polymer network (IPN) fibers comprising intertwined solid-state cholesteric liquid crystal (CLC solid ) and anionic poly(acrylic acid) (PAA) or cationic poly(2-dimethylaminoethyl methacrylate) (PDMAEMA) networks (photonic IPN PAA or IPN PDMAEMA fibers) were developed for sensor applications. IPN PAA or IPN PDMAEMA fibers with a perfect photonic structure were fabricated inside Teflon tube templates without any treatments for realizing a planar orientation in those fibers. The dominant wavelength of the photonic color from a photograph taken with a cellular phone was used to measure the photonic color change. Photonic IPN PAA fibers treated with KOH (IPN KOH fibers) were used for sensing humidity and divalent metal ions. The linear ranges for relative humidity and Ca 2+ detection were 21-92% and 0.5-3.5 mM, and their limits of detection (LODs) were 7.86% and 0.07 mM, respectively. The photonic IPN PAA (or IPN PDMAEMA ) fiber immobilized with urease (IPN PAA-urease ) (or glucose oxidase (IPN PDMAEMA-GOx )) was used for urea (or glucose) biosensor application. The photonic IPN PAA-urease (or IPN PDMAEMA-GOx ) fiber was red-shifted in response to urea (or glucose) in the linear range of 10-60 mM (or 2-16 mM) with an LOD of 2.54 mM (or 0.76 mM). These photonic IPN fibers are promising because of their easy fabrication and miniaturization, battery-free device, cost-effectiveness, and visual detection without using sophisticated analytical instruments. The developed photonic IPN fibers provide new possibilities for the widespread use of photonic sensors in cutting-edge wearable technology and beyond.

Published
2024
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20. Ultrafast Dynamics, Optical Nonlinearities, and Chemical Sensing Application of Free-Standing Porous Silicon-Based Optical Microcavities.

Author

Shanu M, Acharyya JN, Kuriakose A, Banerjee D, Soma VR, and Vijaya Prakash G

Abstract

The present work demonstrates the ultrafast carrier dynamics and third-order nonlinear optical properties of electrochemically fabricated free-standing porous silicon (FS-PSi)-based optical microcavities via femtosecond transient absorption spectroscopy (TAS) and single-beam Z-scan techniques, respectively. The TAS (pump: 400 nm, probe: 430-780 nm, ∼70 fs, 1 kHz) decay dynamics are dominated by the photoinduced absorption (PIA, lifetime range: 4.7-156 ps) as well as photoinduced bleaching (PIB, 4.3-324 ps) for the cavity mode (λ c ) and the band edges. A fascinating switching behavior from the PIB (-ve) to the PIA (+ve) has been observed in the cavity mode, which shows the potential in ultrafast switching applications. The third-order optical nonlinearities revealed an enhanced two-photon absorption coefficient (β) in the order of 10 -10 mW -1 along with the nonlinear refractive index ( n 2 ) in the range of 10 -17 m 2 W -1 . Furthermore, a real-time sensing application of such FS-PSi microcavities has been demonstrated for detecting organic solvents by simultaneously monitoring the kinetics in reflection and transmission mode.

Published
2024
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21. Improving the Efficiency of a Polymer Nanocomposite for Formation of Photon Structures by Means of Optical Recording.

Author

Burunkova, J. A., Alkhalil, D., and Sviazhina, D. S.

Subjects
*NANOCOMPOSITE materials, *PHOTOPOLYMERS, *POLYMERIC nanocomposites, *BRAGG gratings, *OPTICAL disks
Abstract

We present the results of investigation of conditions leading to optimization of an optical recording medium based on photosensitive urethane–acrylate nanocomposites containing silicone oxide nanoparticles that is used for efficient recording of Bragg gratings by means of multiple-beam interference. It is demonstrated that the choice of most efficient monomers and their concentration in the nanocomposite depending on their structure and the rate of polymerization, followed by finding optimal intensity of recording radiation for given composition, allows regulating the conditions for component diffusion thereby optimizing their redistribution in the recording medium and formation of regions with different values of refractive index. The results of the study can be used for creation of complex 2D and 3D photonic structures based on purposeful modification of light-sensitive polymer nanocomposites exhibiting various properties (luminescent, nonlinear-optical, etc.) [ABSTRACT FROM AUTHOR]

Published
2020
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22. Anodic titania photonic crystals with high reflectance within photonic band gap via pore shape engineering.

Author

Sadykov, A.I., Kushnir, S.E., Sapoletova, N.A., Ivanov, V.K., and Napolskii, K.S.

Subjects
*PHOTONIC band gap structures, *PHOTONIC crystals, *REFLECTANCE, *SQUARE waves, *ANODIC oxidation of metals
Abstract

Anodizing of valve metals under oscillating conditions is one of versatile and reproducible methods of the preparation of one-dimensional photonic crystals. Here, an effect of anodizing voltage profile on morphology and optical properties of anodic titanium oxide photonic crystals is investigated. Samples are obtained by cyclic anodizing of titanium in ethylene glycol based electrolyte using sine, triangle, and square wave voltage versus charge density modulation. The optimization of anodizing parameters allowed us to prepare anodic titanium oxide photonic crystals with reflectance within the photonic band gap of up to 85%. Image, graphical abstract [ABSTRACT FROM AUTHOR]

Published
2020
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23. Field investigation of a photonic multi-layered TiO2 passive radiative cooler in sub-tropical climate.

Author

Jeong, Shin Young, Tso, Chi Yan, Ha, Jimyeong, Wong, Yuk Ming, Chao, Christopher Y.H., Huang, Baoling, and Qiu, Huihe

Subjects
*ATMOSPHERIC temperature, *PHOTOVOLTAIC cells, *COST control, *CLIMATOLOGY, *SOLAR energy, *SUNSHINE
Abstract

Cost reduction and enhanced cooling performance are strongly demanded for daytime passive radiative cooling due to its attractive cooling strategy that does not require any energy input. Its potential application varies widely from air conditioning systems for buildings, photovoltaic cells, electronic device cooling and automobiles. However, recently proposed daytime passive radiative coolers are based on photonic structures which are high in cost. A relatively cheap metal oxide material, TiO 2 , which lowers the cost but is highly emissive in the mid-infrared range has been used, also improving the cooling performance of the photonic daytime passive radiative cooler. An optimized TiO 2 –SiO 2 alternating multi-layered photonic daytime radiative cooler with average emissivity of 0.84 within 8–13 μm while reflecting 94% of incident solar energy is developed. Its net cooling power is estimated to be 136.3 W/m2 at ambient air temperature of 27 °C which shows an improvement of 90 W/m2 compared to that of the HfO 2 -SiO 2 photonic radiative cooler. Last, a field test has been conducted in Hong Kong's subtropical climate (i.e. relative humidity = 60–70%) to investigate its feasibility, and with the help of solar shading, successfully demonstrated temperature reduction of 7.2 °C with a net cooling power of 14.3 W/m2 under direct sunlight. • An optimized TiO 2 –SiO 2 radiative cooler showed the emissivity (8–13 μm) of 0.84. • The radiative cooler was measured to absorb 58.5 W/m2 of solar irradiance. • The net cooling power of the radiative cooler was estimated to be 136.6 W/m2. • In Hong Kong's sub-tropical climate, the cooler remained 7.2 °C below the ambient. • The radiative cooler generated a net cooling power of 14.3 W/m2 during the daytime. [ABSTRACT FROM AUTHOR]

Published
2020
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24. Strain-dependent Optical and Thermal Properties of CNT films

Author

Hewakuruppu, Hasitha Jeewana

Subjects
Mechanical engineering, CNT Films, Photonic Structure, Radiative Cooling, Raytracing, Solar Absorber, Thermoregulation
Abstract

Passive surface thermal regulation is an area of critical interest, with many potential applications ranging from the design of energy efficient building coatings to applications such as thermo camouflage. The thermoregulation of a surface requires the dynamic modulation of emissivity and reflectivity of the material; these changes are achieved via the manipulation of the surface morphology of the material. The work presented in this thesis used a strain driven CNT film to achieve the said morphology changes. In the experimental characterization of CNT films, a 0.047 increase in the average solar reflectivity was observed when strain up to 80%. When exposed to direct sunlight, this change in reflectivity was manifested as a temperature change of 2.8℃. Following the experimental work, a 3D model was developed to represent the CNT film. The developed model was simulated using raytracing under varying levels of strain, these results were used to develop a hypothesis. The developed hypothesis viewed the surface of the CNT films to be composed of many pit-like structures; the shallowing of the pit depth when strained was determined to be the driving mechanism of increased reflectivity. Later based on the developed hypothesis a simpler periodic model was created to provide an enhanced strain-dependent reflectivity increase of 0.145 in the solar region. This model was further improved by adding a silver backed layer to provide an increased averaged solar reflectivity of 0.6826 resulting in a surface temperature change of nearly 61℃.

Published
2020

25. A confined self-assembly approach towards chiral photonic materials with circularly polarized structural colors for information storage and encryption.

Author

Li, Lin-Yue, Li, Dong, Dong, Xiu, Tan, Qiang-Wu, Wang, Xiu-Li, Wang, Yu-Zhong, and Song, Fei

Subjects
*STRUCTURAL colors, *CIRCULAR polarization, *OPTICAL devices, *OPTICAL reflection, *MESOPHASES, *CHOLESTERIC liquid crystals
Abstract

[Display omitted] • A confined assembly strategy is reported for polarized structural coloration. • DCP is adjusted by kinetic trapping multi-domain cholesteric mesophases. • The chiral photonic materials can be applied for information storage and encryption. Chiroptical materials with tunable circular polarization performances have gained wide interest because of promising applications in optical devices and information communication. However, limited by their intrinsic chirality, such materials suffer from serious deficiencies in dynamical manipulation on circularly polarized light (CPL). Here, we demonstrate a kinetic trapping approach to capture multi-domain cholesteric mesophases for polarization-dependent structural coloration. The resultant photonic structures depicted by limited solvent evaporation display light control from selective left-handed circularly polarized light reflection to dual reflection, as a result of forming highly tilted and distorted domains with a phase-retardation effect. Notably, a positive linear correlation is established between the circular polarization behavior and structural orientation regulated by the solvent evaporation. The tunable circular polarization structural colors enable the application of the photonic materials for complex encryption in terms of polychromatic coding arrays. The confined-anisotropic-fabrication method of photonic structures paves a foundation toward advanced functional materials with promising applications in light science and technology. [ABSTRACT FROM AUTHOR]

Published
2024
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32. Numerical investigation of photonic crystals structure on zinc oxide film.

Author

Anghel, Iulia

Subjects
*ZINC oxide films, *PHOTONIC crystals, *ZINC crystals, *ZINC oxide synthesis, *CRYSTAL structure, *ZINC oxide, *PHOTONIC band gap structures
Abstract

In this work, the design and the performance of a two dimensional photonic structure with hexagonal geometry is numerically investigated by plane wave expansion (PWE) method. The structure consists in a zinc oxide (ZnO) substrate patterned in a hexagonal configuration with periodic holes with different radius. The photonic crystals exhibited band gaps in the near infrared wavelength range. This kind of photonic structures can be used for a wide range of optoelectronic applications. [ABSTRACT FROM AUTHOR]

Published
2019
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33. Optical Writing of Diffraction Structures in Photorefractive Lithium Niobate by Bessel-Like Optical Fields.

Author

Perin, A. S., Trushnikov, I. A., and Inyushov, A. V.

Subjects
*OPTICAL diffraction, *LITHIUM niobate, *GAUSSIAN beams, *LASER beams, *PHOTOREFRACTIVE effect, *REFRACTIVE index
Abstract

The evolution of the characteristics of one-dimensional phase diffraction structures during their optical induction by Bessel-like monochromatic beams in photorefractive samples of lithium niobate is studied experimentally. Both, one-dimensional (1D) and two-dimensional (2D) Bessel-like beams with different topology of 2D beam cross-sections are formed from Gaussian laser beams using the amplitude masks with rectangular and annular apertures. These almost diffraction-free light fields with wavelengths of 457 and 532 nm can change the refractive indices of photorefractive lithium niobate samples and form within them the nonlinear photonic diffraction structures. [ABSTRACT FROM AUTHOR]

Published
2019
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34. A new path to design near-infrared persistent luminescence materials using Yb3+-doped rare earth oxysulfides.

Author

Machado, Ian Pompermayer, Pedroso, Cássio Cardoso Santos, Carvalho, José Miranda de, Teixeira, Verônica de Carvalho, Rodrigues, Lucas Carvalho Veloso, and Brito, Hermi Felinto

Subjects
*YTTERBIUM ions, *LUMINESCENCE spectroscopy, *RARE earth metal compounds, *DOPING agents (Chemistry), *CHEMICAL potential
Abstract

Abstract RE 2 O 2 S:Yb3+ and RE 2 O 2 S:Yb3+,Ti,Mg2+ near-infrared persistent luminescence materials (RE3+: La, Gd, Y) were designed based on the efficient red-emitting RE 2 O 2 S:Eu3+,Ti,Mg2+, due to the similar ground state level positions between Eu3+ and Yb3+. The Y 2 O 2 S:Yb3+,Ti,Mg2+ showed the longest near-infrared (~983 nm) persistent luminescence time (~1 h) when excited at the charge transfer transition, demonstrating that Ti,Mg2+ co-doping enhances the persistent luminescence only for the Y 2 O 2 S host. The unprecedented relationship between Eu3+ and Yb3+ persistent luminescence opens a new path in the systematic design of efficient Yb3+-activated persistent luminescence materials e.g. Y 2 O 2 S:Yb3+,Ti,Mg2+, which present potential for photonic applications such as bioimaging probes. Graphical abstract Unlabelled Image [ABSTRACT FROM AUTHOR]

Published
2019
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35. Peculiarities of holographic microfabrication of photonic structures in functional polymer nanocomposites.

Author

Burunkova, J., Zhuk, D., Kaliabin, V., Molnar, S., and Kokenyesi, S.

Subjects
*POLYMERIC nanocomposites, *SILICA nanoparticles, *URETHANE, *ACRYLATES, *PHOTONIC crystals, *CRYSTAL structure, *MICROFABRICATION
Abstract

Abstract Nanocomposites based on urethane-acrylate monomers stabilized at high concentration of silica nanoparticles were fabricated and investigated with the aim to produce efficient volume Bragg grating elements. Their sensitivity in the green spectral region and high modulation depth of the refractive index in the optically recorded elements are determined by the redistribution of combined monomers and silica nanoparticles, by the property of initiators of polymerization as well as by the parameters of recording process. The developed materials and methods can be used for creation of versatile photonic elements, for manipulation of optical wavefronts or beam propagation, for optical sensing. Highlights • Light sensitive nanocomposites based on urethane-acrylate monomers were developed. • Sensitivity to green lasers, high modulation of the refractive index was realized. • Correlations between the composition, recording processes and parameters of gratings were established. • 1D, 2D, 3D holographic elements were recorded. [ABSTRACT FROM AUTHOR]

Published
2019
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36. InP-Substrate-Based Quantum Dashes on a DBR as Single-Photon Emitters at the Third Telecommunication Window

Author

Paweł Wyborski, Anna Musiał, Paweł Mrowiński, Paweł Podemski, Vasilij Baumann, Piotr Wroński, Fauzia Jabeen, Sven Höfling, and Grzegorz Sęk

Subjects
single-photon emitter, III–V quantum dot, telecommunication spectral range, photonic structure, extraction efficiency, Technology, Electrical engineering. Electronics. Nuclear engineering, TK1-9971, Engineering (General). Civil engineering (General), TA1-2040, Microscopy, QH201-278.5, Descriptive and experimental mechanics, QC120-168.85
Abstract

We investigated emission properties of photonic structures with InAs/InGaAlAs/InP quantum dashes grown by molecular beam epitaxy on a distributed Bragg reflector. In high-spatial-resolution photoluminescence experiment, well-resolved sharp spectral lines are observed and single-photon emission is detected in the third telecommunication window characterized by very low multiphoton events probabilities. The photoluminescence spectra measured on simple photonic structures in the form of cylindrical mesas reveal significant intensity enhancement by a factor of 4 when compared to a planar sample. These results are supported by simulations of the electromagnetic field distribution, which show emission extraction efficiencies even above 18% for optimized designs. When combined with relatively simple and undemanding fabrication approach, it makes this kind of structures competitive with the existing solutions in that spectral range and prospective in the context of efficient and practical single-photon sources for fiber-based quantum networks applications.

Published
2021
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37. Climate-dependent optimization of radiative cooling structures for year-round cold energy harvesting.

Author

Seo, Junyong, Choi, Minwoo, Yoon, Siwon, and Lee, Bong Jae

Subjects
*ENERGY harvesting, *COOLING
Abstract

The potential of radiative cooling (RC) technology to passively and sustainably harvest cold energy has received a lot of interest. Since RC surface is installed outdoors for the long term and operates under time-varying environmental conditions, photonic structures constructing the RC surface need to be carefully designed based on proper theoretical modeling. However, a theoretical model for accumulated cooling performance that reflects environmental factors was scarcely developed for photonic structure design. This paper presents a more practical approach for estimating RC performance as an accumulated cold energy production (ACEP). ACEP stands for the time integration of cooling power, which is modeled to comprehensively account for a wide range of time-dependent environmental factors, including mostly neglected cloud coverage as well. The realistic performance of an RC surface at any location on Earth can be estimated without conducting any experiments. Utilizing the benefits of ACEP, photonic structures are separately optimized for 15 different locations with different climates. As a result, the universal optimum for all climates achieves 2 to 4 percent greater ACEP than the conventionally driven optimum. Based on the optimized results, we have developed a strategy for selecting radiative cooling structures based on regional climate conditions utilizing ACEP as a guiding metric. Furthermore, the impact of each environmental factor on RC performance is investigated by analyzing the ACEP components. • Realistic model for climate-dependent radiative cooling performance is introduced. • Representative radiative cooling structures are optimized for each climatic region. • A single 4-layered optimum demonstrates robust operation across diverse climates. • We have developed a cooling structure selection strategy for specific climates. • We comprehensively analyze the impact of climatic factors on cooling performance. [ABSTRACT FROM AUTHOR]

Published
2023
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38. Design and analysis of high-efficiency perovskite solar cell using the controllable photonic structure and plasmonic nanoparticles.

Author

Ullah, Ihsan, Guo, Junjun, Wang, Changlei, Liu, Zeke, Li, Xiaofeng, Jiang, Lin, Yuan, Jianyu, and Ma, Wanli

Subjects
*PHOTOVOLTAIC power systems, *SOLAR cells, *PEROVSKITE analysis, *PLASMONICS, *OPEN-circuit voltage, *INSECT traps
Abstract

Device modeling of CH 3 NH 3 PbI 3 based controllable photonic structure and plasmonic nanoparticles perovskite solar cells (PSC) was performed. In recent years, light trapping (LT) and plasmonic structures in PSCs have been developed and attracted widespread attention and encouraged researchers to develop and test many architectures in this area. Also, using controllable photonic structures and plasmonic nanoparticles in PSCs significantly affect the power conversion efficiency (PCE). LT by photonic structure and also the interaction of incident light with plasmonic nanoparticles (NPs) is considered as a hopeful way to enhance the PCE of PSCs in this simulation. For accurate calculation and also considering all parameters on PSC, the present simulation is done using the finite element method (FEM). The simulation results showed that using a photonic structure significantly affects the photovoltaic result of the PSC, and the PCE reached from 15.62 % for the planar structure to 16.17 % for the photonic structure. Here, we concentrate on a significant aspect of nanostructures that minimizes light loss by optimizing and managing light to achieve high PCE for the PSC. Then we used plasmonic NPs at the top of the electron layer transfer (ETL), active layer, and hole transfer layer (HTL), and the best position to achieve the highest PCE was the top of HTL. Moreover, an additional layer as a complimentary layer (CH 3 NH 3 SnI 3) was used to maximize efficiency with values of short circuit current (J sc) 27.81 (mA/cm2), open circuit voltage (V oc) 0.949 (V), fill factor (FF) 81.77 % and PCE 21.85 %. Using these combined techniques opens horizons of improvement for the PCE of PSC. [Display omitted] • Light absorption increase using plasmonic nanoparticles (PNPs) was investigated. • Using the light trap (LT) mechanism increases active layer absorption over planar structure. • Performance of the proposed PSC is highly dependent on the position and location of PNPs. • Placing Au PNPs in the double active layer increased PCE to 21.85 %. [ABSTRACT FROM AUTHOR]

Published
2023
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39. Resource-efficient generation of large-area micro and nanostructures

Author

Bläsi, Benedikt, Müller, Martina, Rossmeier, Harald, and Publica

Subjects
photon management, photonic structure, laser
Abstract

Lasers are widely used in various manufacturing processes. In order to achieve sustainable production, it is important to reduce the environmental impact caused by the laser operation. One major improvement is the step from gas lasers to diode lasers.

Published
2023

44. Recent progress in terahertz modulation using photonic structures based on two‐dimensional materials

Author

Jie Qiao, Shilei Wang, Chuan He, Ziming Wang, Xutang Tao, Shuqi Zhao, and Shanpeng Wang

Subjects
terahertz modulation, Materials science, business.industry, Terahertz radiation, Physics::Optics, 2D material, Information technology, T58.5-58.64, Modulation, TA401-492, Optoelectronics, photonic structure, Photonics, business, Materials of engineering and construction. Mechanics of materials, optoelectronic device
Abstract

Terahertz (THz) technology has attracted great attention in the past few decades for its unique applications in various fields, including spectroscopy, noninvasive detection, wireless communications, and imaging. In parallel to this, the practical, fast, and broadband modulation of THz waves is becoming indispensable. Two‐dimensional (2D) materials exhibit unusual optical and electrical properties, which has prompted tremendous interest and significant advances in THz modulation. This review provides the recent progress in 2D materials‐based THz modulators, outlining the operating principles, including all‐optical, electro‐optic, magneto‐optic, and other exotic mechanisms. We focus on the recent advances in THz modulation by the designed photonic structures, such as heterostructure, metamaterial, capacitor, optical cavity, and waveguide integration. Lastly, we discussed the challenges and opportunities for 2D materials‐based THz modulators and presented our prospects for the future development.

Published
2021

48. Hierarchical Organization of Structurally Colored Cholesteric Phases of Cellulose via 3D Printing

Author

Tadeusz Balcerowski, Burak Ozbek, Ozge Akbulut, and Ahu Gümrah DUMANLI

Subjects
biomimicry, 3D-printing, Light, Phases, Color, Cholesteric phasis, Hydroxypropyl cellulose, Shear-induced, Cost Effectiveness, Filaments, Biomaterials, Biomimetics, Nanotechnology, General Materials Science, hierarchical photonic structures, Hierarchical photonic structure, Cellulose, Photonic structure, 3-D printing, cholesteric liquid crystals, shear-induced deformation, 3D printing, General Chemistry, 3D printers, Printing, Cholesteric liquid-crystal, Chemical modification, Biotechnology
Abstract

Structural color—a widespread phenomenon observed throughout nature is caused by light interference from ordered phases of matter. While state-of-the-art nanofabrication techniques can produce structural organization in small areas, we still lack a cost-effective, and scalable techniques to generate tunable color at sub-micron length scales. In this work, we produced structurally colored hydroxypropyl cellulose filaments with a suppressed angular color response by 3-d printing. Our systematic study of the morphology of the filaments reveals the key stages in the induction of a two-degree hierarchical order through 3-d printing. The first degree of order originates from the changing of the cholesteric pitch at a few hundred nm scale via chemical modification and tuning of the solid content of the lyotropic phase. Upon 3-d printing, the secondary hierarchical order of periodic wrinkling was introduced through the Helfrich-Hurault deformation of the shear-aligned cholesteric phases. Our work reveals the mechanism of the wrinkling behavior evidenced by detailed morphological characterization using SEM. In single layered filaments, we identified four morphological zones with varying order of wrinkles. Through this work, we demonstrate the possibility of modifying the wrinkling behavior and thus the angle dependence of the color response by changing the printing conditions.

Published
2022

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