Your search keyword '"Optical engineering"' showing total 39,394 results

1. Purcell-enhanced x-ray scintillation.

Author

Kurman, Yaniv, Lahav, Neta, Schuetz, Roman, Shultzman, Avner, Roques-Carmes, Charles, Lifshits, Alon, Zaken, Segev, Lenkiewicz, Tom, Strassberg, Rotem, Be'er, Orr, Bekenstein, Yehonadav, and Kaminer, Ido

Subjects

*SCINTILLATORS, *OPTICAL engineering, *X-rays, *NANOSTRUCTURED materials, *RADIATION doses, *DOPING agents (Chemistry)

Abstract

Scintillation materials convert high-energy radiation to optical light through a complex multistage process. The last stage of the process is spontaneous light emission, which usually governs and limits the scintillator emission rate and light yield. For decades, scintillator research focused on developing faster-emitting materials or external photonic coatings for improving light yields. Here, we experimentally demonstrate a fundamentally different approach: enhancing the scintillation rate and yield via the Purcell effect, utilizing optical environment engineering to boost spontaneous emission. This enhancement is universally applicable to any scintillating material and dopant when the material's nanoscale geometry is engineered. We design a thin multilayer nanophotonic scintillator, demonstrating Purcell-enhanced scintillation with 50% enhancement in emission rate and 80% enhancement in light yield. The emission is robust to fabrication disorder, further highlighting its potential for x-ray applications. Our results show prospects for bridging nanophotonics and scintillator science toward reduced radiation dosage and increased resolution for high-energy particle detection. [ABSTRACT FROM AUTHOR]

Published

2024

2. Influence of Machining Condition and Nano-Graphene Incorporation on Drilling Load and Hole Quality in Both Conventional Drilling and Ultrasonic-Assisted Drilling of CFRP.

Author

Baraheni, Mohammad and Amini, Saeid

Subjects

*CARBON fiber-reinforced plastics, *ULTRASONIC machining, *MACHINING, *OPTICAL engineering, *CUTTING force

Abstract

Carbon fiber-reinforced polymers (CFRPs) are widely used in biomedical, optical and tissue engineering applications. Nevertheless, machining these materials significantly differs from other materials and faces special challenges. In recent years, ultrasonic drilling as a new technique was introduced in the field of composites' machining. This study evaluates the effects of nano-graphene incorporation and machining parameters including feed rate, tool type in both conventional and ultrasonic vibration assisted drilling. Besides, statistical analysis is conducted in order to identify contribution of the parameters. The results suggest that feed rate is the most influential factor on cutting force and hole quality including delamination and hole roundness. In addition, in order to acquire the best optimal process parameters, desirability method was established. That was indicated the best hole quality is achieved in CFRP samples at the least feed rate by the HSS-8% cobalt tool (M42 tool) and in presence of the ultrasonic vibration. [ABSTRACT FROM AUTHOR]

Published

2024

3. Photoelectrodes with Enhanced Carrier Generation and Collection Through Optical Simulation and Materials Engineering.

Author

Liu, Huiya, Shao, Jialin, Zhao, Jia, Zhao, Jingjing, Zhang, Zemin, and Huo, Hongqing

Subjects

*OPTICAL materials, *OPTICAL engineering, *ENGINEERING simulations, *LIGHT absorption, *FINITE element method, *NANOWIRES

Abstract

The efficiency of solar‐fuel conversion in photoelectrochemical (PEC) systems is hindered by significant losses of photons and photocarriers within the photoelectrodes. This study introduces an innovative ITO@In2S3 core‐shell nanowire structure designed to overcome these challenges through cutting‐edge materials engineering and sophisticated simulation techniques. Optical modeling and finite element simulations highlight the conflict between photocarrier generation and collection in planar In2S3 thin films and demonstrate how the core‐shell nanowire geometry can significantly enhance light absorption. The developed ITO@In2S3 nanowire photoanodes achieve a photocurrent of 11.3 mA cm−2 at 1.23 V versus RHE, which is nearly five times greater than that of planar ITO/In2S3 thin films. Characterization techniques, including UV–vis absorption and charge separation efficiency measurements, confirm the enhanced light absorption and improved carrier collection facilitated by broadening the optical absorption range and reducing carrier transport distances. This research not only deepens the understanding of the dynamics within thin‐film photoelectrodes but also paves the way for the development of more efficient technologies for solar fuel conversion. [ABSTRACT FROM AUTHOR]

Published

2024

4. Remote Vector Velocimetry with Fiber‐Delivered Scalar Fields.

Author

Tang, Ziyi, Wan, Zhenyu, Zhang, Xi, Liang, Yize, and Wang, Jian

Subjects

*ROTATIONAL motion, *DOPPLER velocimetry, *OPTICAL engineering, *SPEED of light, *SCALAR field theory, *DOPPLER effect

Abstract

The Doppler effect reveals the law that light waves undergo frequency changes in interacting with motion, which is highly significant in velocity detection and has applications in fields such as astrophysics, aerospace, and advanced manufacturing. A typical Doppler velocimetry involves illuminating a moving object with interference fringes generated based on phase gradients while detecting the frequency shift of scattered light to determine the velocity. Beyond the spatial phase distributions, the spatial amplitude is a unique dimension of light fields that can be directly controlled, but its application prospects in motion detection are rarely revealed, particularly in both the magnitude and orientation of velocity measurements. In this work, a remote vector velocimeter based on spatially structured amplitude fields is proposed for monitoring angular velocities of objects in situ. Guided through a 40 km seven‐core fiber, the structured beams with spatially‐distributed amplitude are constructed at the remote fiber facet by adjustable mode excitation in outer cores, and the Doppler signals reflected by the target are collected and transmitted back by the inner core, enabling the remote measurement of rotational motion vectors with a probe‐signal‐integrated configuration. These results suggest the great potential of spatial amplitude fields in motion detection, the cost‐efficient and compact velocimetry may contribute to the communities of optical sensing and engineering. [ABSTRACT FROM AUTHOR]

Published

2024

5. Θ-Net: A Deep Neural Network Architecture for the Resolution Enhancement of Phase-Modulated Optical Micrographs In Silico.

Author

Kaderuppan, Shiraz S., Sharma, Anurag, Saifuddin, Muhammad Ramadan, Wong, Wai Leong Eugene, and Woo, Wai Lok

Subjects

*ARTIFICIAL neural networks, *PHASE-contrast microscopy, *MICROSCOPY, *OPTICAL engineering, *IMAGE denoising, *NEAR-field microscopy, *INTERFERENCE microscopy

Abstract

Optical microscopy is widely regarded to be an indispensable tool in healthcare and manufacturing quality control processes, although its inability to resolve structures separated by a lateral distance under ~200 nm has culminated in the emergence of a new field named fluorescence nanoscopy, while this too is prone to several caveats (namely phototoxicity, interference caused by exogenous probes and cost). In this regard, we present a triplet string of concatenated O-Net ('bead') architectures (termed 'Θ-Net' in the present study) as a cost-efficient and non-invasive approach to enhancing the resolution of non-fluorescent phase-modulated optical microscopical images in silico. The quality of the afore-mentioned enhanced resolution (ER) images was compared with that obtained via other popular frameworks (such as ANNA-PALM, BSRGAN and 3D RCAN), with the Θ-Net-generated ER images depicting an increased level of detail (unlike previous DNNs). In addition, the use of cross-domain (transfer) learning to enhance the capabilities of models trained on differential interference contrast (DIC) datasets [where phasic variations are not as prominently manifested as amplitude/intensity differences in the individual pixels unlike phase-contrast microscopy (PCM)] has resulted in the Θ-Net-generated images closely approximating that of the expected (ground truth) images for both the DIC and PCM datasets. This thus demonstrates the viability of our current Θ-Net architecture in attaining highly resolved images under poor signal-to-noise ratios while eliminating the need for a priori PSF and OTF information, thereby potentially impacting several engineering fronts (particularly biomedical imaging and sensing, precision engineering and optical metrology). [ABSTRACT FROM AUTHOR]

Published

2024

6. Temperature mapping methods for thermoelastic analyses of the ARIEL spacecraft payload module.

Author

García-Pérez, Andrés, Fernández-Soler, Alejandro, Morgante, Gianluca, Pérez-Álvarez, Javier, Alonso, Gustavo, García-Moreno, Laura, Scippa, Antonio, Gottini, Daniele, and Lilli, Riccardo

Subjects

*OPTICAL engineering, *THERMAL analysis, *STRUCTURAL models, *HEAT transfer, *ORBITS (Astronomy)

Abstract

The ARIEL mission is a European space project that aims to detect exoplanets with a spacecraft orbiting around the L2 point of the Sun-Earth system. The main payload consists of a Cassegrain telescope composed of mirrors that reflect and concentrate the incoming light from the deep space observations to finally guide it to the detectors. As in many other space missions, a dedicated complex assessment is established during the design phase to evaluate the impact on the optical performance caused by thermoelastic effects, which involves the coordinated work of the thermal, structural, and optical engineers. Despite that well-known and standardized processes and tools are established separately in each involved area, there is a lack of standardization about the way of exchanging the data between them, where additional calculations are required in some cases. This work focuses on the temperature mapping, which is the intermediate step between thermal and structural analyses, where temperatures are transferred to the structural model. The main difficulty of this process is related to the differences in modelling methods and approaches between both models, being necessary the development of an adequate algorithm to find the most accurate transfer of temperatures. This paper shows two different options for temperature mapping, detailing the proposed flowcharts. One of these methods requires the performance of an additional thermal conductive analysis, where a new improved procedure has been implemented in this work to solve some computational issues that made its application for large models difficult or even unfeasible. Both temperature mapping methods have been applied to the payload module of the ARIEL spacecraft, comparing the output results in terms of temperatures, stresses, forces, and displacements to evaluate their differences. • Structural, Thermal and Optical Performance (STOP) analysis on the ARIEL spacecraft. • Development of two procedures for temperature transfer between thermal and structural models. • Definition of a process to overcome computational issues found in thermal analysis in NASTRAN. • Validation of the proposed procedures for the temperature mapping of a large and complex model. • Comparison of results between two temperature mapping methods (PWT and PAT) on ARIEL. [ABSTRACT FROM AUTHOR]

Published

2024

7. Configurable lateral optical forces from twisted mixed-dimensional MoO3 homostructures.

Author

Yan, Qizhi, Chen, Runkun, Li, Peining, and Zhang, Xinliang

Subjects

*LATERAL loads, *POLARITONS, *PHONONS, *GOLD nanoparticles, *OPTICAL engineering

Abstract

In recent years, the concept of hyperbolic phonon polaritons (HPPs) has revolutionized the field of nanophotonic, enabling unprecedented control over light-matter interactions at the nanoscale. Here, we theoretically propose and study the lateral optical forces in twisted mixed-dimensional MoO3 homostructures. Assisted with the low-symmetry HPPs, we realize a lateral optical force exerted on the Au nanoparticles near the surface of mixed-dimensional MoO3 homostructures with a linear polarized incident light. By controlling the polarization state, incident angle of light and the twisted angle of MoO3, the amplitude and direction of the lateral optical forces can be tailored in the mid-infrared range. Our findings provide a new platform for engineering lateral optical forces to manipulate diverse objects in a flexible and efficient manner. [ABSTRACT FROM AUTHOR]

Published

2024

8. Switching of three-dimensional optical cages using spatial coherence engineering.

Author

Xu, Ying, Wu, Jidong, Zhao, Xinshun, Zhang, Yongtao, Zhu, Xinlei, Cai, Yangjian, and Yu, Jiayi

Subjects

COHERENCE (Optics), OPTICAL engineering, ENGINEERING, HOPE

Abstract

Precisely capturing and manipulating microparticles is the key to exploring microscopic mysteries. Optical tweezers play a crucial role in facilitating these tasks. However, existing optical tweezers are limited by their dependence on specific beam modes, which restrict their ability to flexibly switch and manipulate optical traps, thereby limiting their application in complex scientific challenges. Here, we propose a new method to achieve type switching and manipulation of optical traps using a single structured beam via optical coherence engineering. A conjugate-model random structured beam with a switch is designed. By altering the state of the switch, we can change the type of optical cage, enabling the capture of different particle types. Furthermore, the range, strength, and position of the optical trap can be controlled by adjusting the initial beam parameters. We hope that optical coherence engineering will extend the capabilities of existing structured optical tweezers, paving the way for advances in future optical tweezers applications. [ABSTRACT FROM AUTHOR]

Published

2024

9. 3D Multi-Phase Sub-Pixel PSF Estimation Based on Space Debris Detection System.

Author

Bu, Fan, Yao, Dalei, and Wen, Yan

Subjects

PEARSON correlation (Statistics), OPTICAL dispersion, OPTICAL engineering, FOCAL planes, OPTICAL aberrations

Abstract

The distribution of diffuse spot energy can be used to sensitively evaluate the aberrations and defects of optical systems. Therefore, the objective and quantitative measurement of diffuse spot parameters is an important means to control the detection quality of space debris detection systems. At present, the existing optical system dispersion measurement method can only judge whether the energy distribution meets the index. However, these methods ca not provide an objective quantitative basis to guide the installation process. To solve this problem, a mathematical simulation model of 3D multi-phase sub-pixel PSF distribution is proposed. According to the relation between the CCD target plane and the theoretical image plane (focal plane, defocus, and deflection), the diffuse spot distribution of the optical system is simulated with different phase combinations. Then, Pearson Correlation Coefficient (PCC) is used to evaluate the matching similarity of the diffuse spot image. The simulation results show that when the PCC is greater than 0.96, the distribution of the two diffuse spots can be identified as matching. This also confirms the accuracy of the proposed PSF model. Then, the focusing deviation of the system being tested can be analyzed according to the phase size of the diffuse spot simulation image. This method can quickly and accurately guide the focal surface installation and testing of the system. Therefore, the purpose of improving the detection accuracy of space debris is achieved. It also provides a quantitative basis for the engineering application of optical detection systems in the future. [ABSTRACT FROM AUTHOR]

Published

2024

10. Strain Engineering on the Electronic Structure and Optical Properties of Monolayer WSi2X4 (X = N, P, As).

Author

Wang, Jianfei, Li, Zhiqiang, Ma, Liang, and Zhao, Yipeng

Subjects

OPTOELECTRONIC devices, ELECTRONIC structure, OPTICAL properties, OPTICAL engineering, MONOMOLECULAR films

Abstract

Two-dimensional WSi2X4 (X = N, P, As) has stimulated extensive studies due to its structural diversity and intriguing properties. Here, a systematic study on the strain engineering of electronic and optical properties in monolayer WSi2X4 is presented. Our results demonstrate that the monolayer WSi2X4 can withstand biaxial tensile strains of 13.1%, 16.3%, and 12.2% for X = N, P, and As, respectively, while the corresponding critical stresses are 27.90 GPa, 14.58 GPa,and 13.56 GPa, respectively. Furthermore, the bandgap of monolayer WSi2X4 can undergo a direct-to-indirect transition and even achieve a semiconductor-to-metal transition under appropriate biaxial strains. In addition, the light absorption of monolayer WSi2X4 in the visible region can be effectively improved by tensile strain, and the red (blue) shift of the absorption peak can be observed by tensile (compression) strain. The results show that monolayer WSi2X4 exhibits outstanding mechanical strength and physical properties, which is promising for future optoelectronic devices. [ABSTRACT FROM AUTHOR]

Published

2024

11. Atomic-engineered gradient tunable solid-state metamaterials.

Author

Zhiyuan Yan, Handoko, Albertus Denny, Weikang Wu, Chuchu Yang, Hao Wang, Yilmaz, Meltem, Zhiyong Zhang, Libo Cheng, Xinbin Cheng, Ghim Wei Ho, Bin Feng, Shibata, Naoya, Rong Zhao, Yang, Joel K. W., Chong Tow Chong, Yuichi Ikuhara, and Cheng-Wei Qiu

Subjects

*OPTICAL materials, *PHASE transitions, *OPTICAL engineering, *VISIBLE spectra, *ATOMIC structure

Abstract

Metamaterial has been captivated a popular notion, offering photonic functionalities beyond the capabilities of natural materials. Its desirable functionality primarily relies on well-controlled conditions such as structural resonance, dispersion, geometry, filling fraction, external actuation, etc. However, its fundamental building blocks--meta-atoms--still rely on naturally occurring substances. Here, we propose and validate the concept of gradient and reversible atomic-engineered metamaterials (GRAM), which represents a platform for continuously tunable solid metaphotonics by atomic manipulation. GRAM consists of an atomic heterogenous interface of amorphous host and noble metals at the bottom, and the top interface was designed to facilitate the reversible movement of foreign atoms. Continuous and reversible changes in GRAM's refractive index and atomic structures are observed in the presence of a thermal field. We achieve multiple optical states of GRAM at varying temperature and time and demonstrate GRAM-based tunable nanophotonic devices in the visible spectrum. Further, high-efficiency and programmable laser raster-scanning patterns can be locally controlled by adjusting power and speed, without any mask-assisted or complex nanofabrication. Our approach casts a distinct, multilevel, and reversible postfabrication recipe to modify a solid material's properties at the atomic scale, opening avenues for optical materials engineering, information storage, display, and encryption, as well as advanced thermal optics and photonics. [ABSTRACT FROM AUTHOR]

Published

2024

12. Advances in Bioreceptor Layer Engineering in Nanomaterial‐based Sensing of Pseudomonas Aeruginosa and its Metabolites.

Author

Lapitan, Lorico DS., Felisilda, Bren Mark B., Tiangco, Cristina E., and Rosin Jose, Ammu

Subjects

*ENGINEERING design, *OPTICAL engineering, *PSEUDOMONAS aeruginosa, *METABOLITES, *TRANSDUCERS, *BIOSENSORS

Abstract

Pseudomonas aeruginosa is a pathogen that infects wounds and burns and causes severe infections in immunocompromised humans. The high virulence, the rise of antibiotic‐resistant strains, and the easy transmissibility of P. aeruginosa necessitate its fast detection and control. The gold standard for detecting P. aeruginosa, the plate culture method, though reliable, takes several days to complete. Therefore, developing accurate, rapid, and easy‐to‐use diagnostic tools for P. aeruginosa is highly desirable. Nanomaterial‐based biosensors are at the forefront of detecting P. aeruginosa and its secondary metabolites. This review summarises the biorecognition elements, biomarkers, immobilisation strategies, and current state‐of‐the‐art biosensors for P. aeruginosa. The review highlights the underlying principles of bioreceptor layer engineering and the design of optical, electrochemical, mass‐based, and thermal biosensors based on nanomaterials. The advantages and disadvantages of these biosensors and their future point‐of‐care applications are also discussed. This review outlines significant advancements in biosensors and sensors for detecting P. aeruginosa and its metabolites. Research efforts have identified biorecognition elements specific and selective towards P. aeruginosa. The stability, ease of preparation, cost‐effectiveness, and integration of these biorecognition elements onto transducers are pivotal for their application in biosensors and sensors. At the same time, when developing sensors for clinically significant analytes such as P. aeruginosa, virulence factors need to be addressed, such as the sensor's sensitivity, reliability, and response time in samples obtained from patients. The point‐of‐care applicability of the developed sensor may be an added advantage since it enables onsite determination. In this context, optical methods developed for P. aeruginosa offer promising potential. [ABSTRACT FROM AUTHOR]

Published

2024

13. Omnidirectional Optical Engineering and Ternary Strategy for High‐Performance Indoor Organic Photovoltaics.

Author

Zheng, Kaiwen, Deng, Baozhong, Lu, Zhouyi, Yin, Luqiao, Wang, Shenghao, Dong, Hongliang, Mbina, Esther, N'konou, Kekeli, Grandidier, Bruno, and Xu, Tao

Subjects

OPTICAL engineering, PHOTOVOLTAIC power systems, LIGHT absorption, SUSTAINABILITY, ABSORPTION spectra, ANTIREFLECTIVE coatings

Abstract

Indoor organic photovoltaics (IOPVs) with tunable absorption spectra and relatively high power conversion efficiency (PCE) have emerged as one of the most promising energy sources for Internet of Things devices, but enhancing the device performance under various directions of indoor illumination is challenging. Herein, it is proposed to combine omnidirectional optical engineering and ternary strategy for achieving high‐performance IOPVs. The advantage is taken of a ternary bulk heterojunction (BHJ) with a polymer donor having aligned absorption spectra with the light‐emitting diode (LED) spectrum and a guest component that not only blueshifts the near‐infrared absorption of the acceptor but also improves electrical and morphological properties of the BHJ. A 2D photonic‐structured antireflection coating is further developed to selectively improve the light absorption of IOPVs, leading to a PCE of 29.07% under 1000 lux LED illumination. More importantly, the antireflection coating maintains the initial PCE even when irradiated by light incident at large angles, demonstrating an omnidirectional effectiveness. This weaker angular dependency on light absorption provides practical prospects for future sustainable indoor photovoltaic systems. [ABSTRACT FROM AUTHOR]

Published

2024

14. Gouy Phase Induced Optical Skyrmion Transformation in Diffraction Limited Scale.

Author

Chen, Jian, Shen, Xi, Zhan, Qiwen, and Qiu, Cheng‐Wei

Subjects

*ANGULAR momentum (Mechanics), *STOKES parameters, *VECTOR topology, *SKYRMIONS, *OPTICAL engineering

Abstract

Optical skyrmions are topologically stable quasiparticles that can be constructed with electric field, spin angular momentum, polarization Stokes vector, pseudospin, etc. In this letter, both theoretical and experimental studies are carried out to reveal the role of Gouy phase in the topology transformation during the tight focusing of Stokes skyrmions. The Stokes skyrmionic beam can be constructed by superposing two orthogonally polarized components with orthogonal spatial modes. The Gouy phase produced in the focused field depends on the orbital angular momentum carried by the high order mode component of the incident Stokes skyrmionic beam. While the beam size of the focused field is diffraction limited, the variation of the Stokes vectors in the skyrmion topology is in the sub‐diffraction limited scale. The presented results shed light on the understanding of the topology transformation between the incident and the tightly focused fields, paving the way for engineering the optical skyrmions in micro‐nano scale and their applications in information processing, quantum technology, metrology, etc. [ABSTRACT FROM AUTHOR]

Published

2024

15. Optical Simulation and Development towards Compact Sensor Heads using Deep Frequency Modulation Interferometry.

Author

An, Sangmin and Isleif, Katharina-Sophie

Subjects

GRAVITATIONAL wave detectors, LIGHT propagation, COMPACTING, MIRRORS, SENSOR networks

Abstract

Copyright of Technisches Messen is the property of De Gruyter and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2024

16. Recent advances in light patterned optogenetic photostimulation in freely moving mice.

Author

Lorca-Cámara, Antonio, Blot, François G. C., and Accanto, Nicolò

Subjects

OPTICAL engineering, ROAD maps, OPTOGENETICS, RESEARCH personnel, HOLOGRAPHY

Abstract

Optogenetics opened the door to a new era of neuroscience. New optical developments are under way to enable high-resolution neuronal activity imaging and selective photostimulation of neuronal ensembles in freely moving animals. These advancements could allow researchers to interrogate, with cellular precision, functionally relevant neuronal circuits in the framework of naturalistic brain activity. We provide an overview of the current state-of-the-art of imaging and photostimulation in freely moving rodents and present a road map for future optical and engineering developments toward miniaturized microscopes that could reach beyond the currently existing systems. [ABSTRACT FROM AUTHOR]

Published

2024

17. Unveiling optical anisotropy in disrupted symmetry WSe2/SiP heterostructures.

Author

Hu, Biqi, Xie, Xing, Ouyang, Xinyu, Chen, Junying, Li, Shaofei, He, Jun, Liu, Zongwen, Wang, Jian-Tao, and Liu, Yanping

Subjects

ISOTROPIC properties, MIRROR symmetry, ROTATIONAL symmetry, OPTOELECTRONIC devices, OPTICAL engineering

Abstract

Two-dimensional (2D) transition metal dichalcogenides (TMDs) have garnered considerable attention for their promising applications in sensors and optoelectronic devices, owing to their exceptional optical, electronic, and optoelectronic properties. However, the inherent high symmetry of TMD lattices imposes limitations on their functional versatility. Here, we present a strategy to disrupt the C3 rotational symmetry of monolayer WSe2 by fabricating a heterostructure incorporating WSe2 and SiP flakes. Through comprehensive experimental investigations and first-principle calculations, we elucidate that in the WSe2/SiP heterostructure, excitons—both neutral and charged—emanating from WSe2 exhibit pronounced anisotropy, which remains robust against temperature variations. Notably, we observe an anisotropic ratio reaching up to 1.5, indicating a substantial degree of anisotropy. Furthermore, we demonstrate the tunability of exciton anisotropy through the application of a magnetic field, resulting in a significant reduction in the anisotropic ratio with increasing field strength, from 1.57 to 1.18. Remarkably, the change in heterojunction anisotropy ratio reaches 24.8% as the magnetic field increases. Our findings elucidate that the perturbation of the C3 rotational symmetry of the WSe2 monolayer arises from a non-uniform charge density distribution within the layer, exhibiting mirror symmetry. These results underscore the potential of heterostructure engineering in tailoring the properties of isotropic materials and provide a promising avenue for advancing the application of anisotropic devices across various fields. [ABSTRACT FROM AUTHOR]

Published

2024

18. Oxidation-induced graded bandgap narrowing in Two-dimensional tin sulfide for high-sensitivity broadband photodetection.

Author

Yu, Yue, Cao, Dan, Yang, Lingang, Guan, Haibiao, Liu, Zehao, Liu, Changlong, Chen, Xiaoshuang, and Shu, Haibo

Subjects

*PHYSICAL vapor deposition, *LIGHT absorption, *PHOTODETECTORS, *ELECTRONIC structure, *OPTICAL engineering

Abstract

[Display omitted] Two-dimensional (2D) layered group-IV monochalcogenides with large surface-to-volume ratio and high surface activity make that their structural and optoelectronic properties are sensitive to air oxidation. Here, we report the utilization of oxidation-induced gradient doping to modulate electronic structures and optoelectronic properties of 2D group-IV monochalcogenides by using SnS nanoplates grown by physical vapor deposition as a model system. By a precise control of oxidation time and temperature, the structural transition from SnS to SnSO x could be driven by the layer-by-layer oxygen doping and intercalation. The resulting SnSO x with a graded narrowing bandgap exhibits the enhanced optical absorption and photocurrent, leading to the fabricated SnSO x photodetector with remarkable photoresponsivity and fast response speed (<64 μs) at a broadband spectrum range of 520–1550 nm. The peak responsivity (7294 A/W) and detectivity (9.54 × 109 Jones) of SnSO x device are at least two orders of magnitude larger than those of SnS photodetector. Moreover, its photodetection performance can be competed with state-of-the-art of 2D materials-based photodetectors. This work suggests that the air oxidation could be utilized as an efficient strategy to engineer the electronic and optical properties of SnS and other 2D group-IV monochalcogenides for the development of high-performance broadband photodetectors. [ABSTRACT FROM AUTHOR]

Published

2025

19. Fiber Optic Devices for Diagnostics and Therapy in Photomedicine.

Author

Hu, Yubing, Minzioni, Paolo, Hui, Jie, Yun, Seok‐Hyun, and Yetisen, Ali K.

Subjects

*FIBER optics, *OPTICAL waveguides, *OPTICAL engineering, *OPTICAL fibers, *ARTIFICIAL implants

Abstract

Photonic technologies have made enormous impacts on modern medicine, advancing disease diagnostics and treatments as well as health monitoring. A long‐standing challenge in the use of light and its widespread effects in photomedicine is the finite penetration of light in tissues. However, judiciously engineered optical fibers helped overcome this challenge and advance light delivery to deep tissues with spatial precision and desired accessibility. In recent years, the development of photonic technologies including optical biomaterials, fiber functionalization, and biomedical device innovations has greatly expanded the scope of light‐based healthcare. Here, the fundamentals and materials of fiber optics to endow themselves with biocompatibility, flexibility, and diverse functionalities required for long‐term implantation are overviewed. The design strategies of lab‐on‐fiber techniques, operation requirements to construct fiber optic sensors, and their health monitoring applications as wearable and implantable devices are presented. The use of fiber optics in major light‐based therapeutic modalities including optogenetics, photodynamic therapy, photobiomodulation, photochemical cross–linking, and photothermal therapy is illustrated to enhance their effectiveness, specificity, and feasibility. In short, a comprehensive review is provided on the fiber optic techniques and the latest photonic devices, which are envisioned to evolve photomedicine in clinical and point‐of‐care practices. [ABSTRACT FROM AUTHOR]

Published

2024

20. Application of machine learning for signal recognition in distributed fibre optic acoustic sensing technology.

Author

Zhan, Yage, Liu, Lirui, and Li, Kehan

Subjects

*PATTERN recognition systems, *OPTICAL computing, *OPTICAL engineering, *OBJECT recognition (Computer vision), *SIGNAL processing, *DEEP learning, *FEATURE extraction

Abstract

Coherent Rayleigh scattering‐based distributed fibre optic sensing technology enables real‐time acquisition of vibration and acoustic information along the optical fibres. However, the complexity of monitoring environments often leads to false alarms and missed detections during the process of information source identification with distributed acoustic sensing (DAS). Therefore, it becomes crucial to effectively extract meaningful signal features and perform accurate pattern recognition in the presence of external noise disturbance. The authors provide a comprehensive review of signal feature extraction and pattern recognition techniques applied in DAS technology. After introducing the fundamentals of DAS, specific applications are considered, and the following techniques have been analysed and compared: feature extraction algorithms based on wavelet decomposition, feature extraction schemes utilising other decomposition models, traditional recognition classifiers, and neural network‐based recognition classifiers using deep learning. The advantages and limitations of each scheme are discussed, along with their potential applications in various scenarios. The aim is to provide insights into the latest technologies in signal processing and pattern recognition for DAS, fostering further advancements in this field. [ABSTRACT FROM AUTHOR]

Published

2024

21. Dual Mode Ratiometric Analysis of Cu2+ and Ni2+ Ions at Physiological pH: Effect of Signalling Units on Analytical Efficacy.

Author

Dey, Nilanjan, Ray, Tathagata, and Bhattacharya, Santanu

Subjects

METAL ions, PH effect, OPTICAL properties, OPTICAL engineering, STOICHIOMETRY

Abstract

Herein, we report the metal ion sensing property of two 2,2'‐bis (pyridylmethyl) amine‐based chromogenic probes at physiological pH in buffered media. The binding of metal ions to the bispicolyl site alters its electronic property, which subsequently influences the optical property of the covalently‐linked signaling unit. The compound experienced a change in the solution color from red to deep and light yellow respectively upon the addition of Cu2+ and Ni2+ ions. Further, it is observed that by modifying the signaling unit, one can tune the mode of metal ion binding and sensitivity. The compound with an electron‐deficient quinolinium unit as the signaling moiety, showed 2 : 1 stoichiometry of binding with metal ions, while the compound functionalized with a pyrene unit formed complexes with 1 : 1 stoichiometry. It was conferred that changes in the signaling moiety not only alter the basicity/nucleophilicity of the pyridine nitrogen ends but also influence their aggregation properties. Such kind of studies will be beneficial for engineering new optical probes with tuneable sensitivity. [ABSTRACT FROM AUTHOR]

Published

2024

22. Optical engineering perspectives on fractional analysis: A comprehensive study of the conformable Gross–Pitaevskii equation in the Bose–Einstein condensation.

Author

Alessa, Nazek, Rehman, Hamood Ur, Muneer, Sadia, and Iqbal, Ifrah

Subjects

*GROSS-Pitaevskii equations, *OPTICAL engineering, *BOSE-Einstein condensation, *ENGINEERING design, *RICCATI equation

Abstract

In this study, we examine the dynamic behavior of optical solitons in the nonlinear conformable Gross–Pitaevskii equation (GPE) within Bose–Einstein condensates, which refer to the phenomenon of many ultra-cold bosonic particles occupying a single quantum state. The GPE is a cornerstone of advanced statistical physics, has application in various engineering disciplines, particularly in the realm of quantum mechanics and optical engineering. By precisely encoding the GPE’s steady-state solutions, we make it possible to compute nonlinear models pertinent to engineering systems and clarify solutions within particular parameter regimes that are essential for engineering applications. Our study encompasses repulsive and attractive nonlinearities in GPE, including quadratic and double-well potentials. We focus on discovering solutions, employing the generalized Riccati equation mapping method and modified extended tanh-function method to extract soliton solutions. The study yields a variety of soliton including combined dark–bright, singular, combo dark-singular, periodic-singular, and rational solutions with physical perspectives. Through 2D and 3D representations, the internal structure of these phenomena is effectively illustrated, offering insights into their behavior and dynamics, which is significant for optimization process and engineering design. [ABSTRACT FROM AUTHOR]

Published

2024

23. Ferromagnetism, bandgap, and impedance analysis of Mn-doped SnO2 synthesized by single-step wet chemical approach.

Author

Parveen, Bushra, Hassan, Mahmood-ul-, Ali, Ghulam, Wattoo, Abdul Ghafar, Ali, Asghar, Riaz, Saira, Naseem, Shahzad, and Song, Zhenlun

Subjects

DOPED semiconductors, SEMICONDUCTOR doping, FERROMAGNETISM, ELECTRIC conductivity, OPTICAL engineering

Abstract

Doped semiconductors are more advantageous than pure semiconductors, because doping of a semiconductor can tune electrical conductivity and optical bandgap engineering that allows flexible designs of microelectronic and optoelectronic devices, respectively. In the present work, pure and Mn-doped SnO2 nanocrystallites have been prepared using single-step wet chemical method calcined at 500 °C and 650 °C to investigate structural, optical, impedance, and ferromagnetic properties. X-ray diffraction confirmed single-phase Mn-doped SnO2, and NEXAFS spectra further revealed + 2 oxidation state of Mn ions in SnO2. The surface morphology depicted densely packed grains and optical spectra showed Mn and temperature-dependent variation of bandgaps. While dielectric and impedance study disclosed frequency response and dominance of grains resistance. Further, conduction mechanism and room temperature ferromagnetism were improved with doping and sintering temperature. Hence, prepared compounds are attractive for frequency-related devices and data storage applications. [ABSTRACT FROM AUTHOR]

Published

2024

24. Perspectives on endoscopic functional photoacoustic microscopy.

Author

Yang, Shuo and Hu, Song

Subjects

*MICROSCOPY, *OPTICAL engineering, *FIBER optics, *MICROFABRICATION, *ENDOSCOPIC ultrasonography, *ENDOSCOPY, *PHOTOACOUSTIC spectroscopy

Abstract

Endoscopy, enabling high-resolution imaging of deep tissues and internal organs, plays an important role in basic research and clinical practice. Recent advances in photoacoustic microscopy (PAM), demonstrating excellent capabilities in high-resolution functional imaging, have sparked significant interest in its integration into the field of endoscopy. However, there are challenges in achieving functional PAM in the endoscopic setting. This Perspective article discusses current progress in the development of endoscopic PAM and the challenges related to functional measurements. Then, it points out potential directions to advance endoscopic PAM for functional imaging by leveraging fiber optics, microfabrication, optical engineering, and computational approaches. Finally, it highlights emerging opportunities for functional endoscopic PAM in basic and translational biomedicine. [ABSTRACT FROM AUTHOR]

Published

2024

25. Dynamical study of optical soliton structure to the nonlinear Landau–Ginzburg–Higgs equation through computational simulation.

Author

Iqbal, Mujahid, Faridi, Waqas Ali, Ali, Rashid, Seadawy, Aly R., Rajhi, Ali A., Anqi, Ali E., Duhduh, Alaauldeen A., and Alamri, Sagr

Subjects

*NONLINEAR equations, *SOLITONS, *NONLINEAR waves, *THEORY of wave motion, *OPTICAL engineering, *OCEAN engineering, *NONLINEAR Schrodinger equation, *MODE-locked lasers

Abstract

In this research work, the nonlinear Landau–Ginzburg–Higgs model under investigation on the base of auxiliary equation method. The nonlinear Landau–Ginzburg–Higgs equation mainly describe nonlinear wave propagation, categorizes wave velocity, and materializes several phenomena through the dispersive system. The secured optical soliton solutions are interested, more general and some novel in kink solitons, bright solitons, periodic singular solitons, anti-kink solitons and dark solitons. The physical structure of some explored solitons solutions are represented graphically as contour, 2D and 3D plots by utilizing the symbolic computational tool Mathematica. The secured soliton will be play important role to the investigation of nonlinear phenomena in the various domains of nonlinear sciences and engineering such as optical fibers, nonlinear dynamics, communication system, solitons wave theory, nonlinear optics, transmission system, electronic engineering and ocean engineering. The auxiliary equation method is a basic analytical, powerful, efficient approach for the investigation of optical soliton inside the nonlinear Landau–Ginzburg–Higgs equation and also other nonlinear equations. [ABSTRACT FROM AUTHOR]

Published

2024

26. Open-source neurophotonic tools for neuroscience.

Author

Kodandaramaiah, Suhasa B., Aharoni, Daniel, and Gibson, Emily A.

Subjects

OPTICAL engineering, OPTICAL control, IMAGING systems, ANIMAL tracks, HIGH power lasers, FOOTPRINTS

Abstract

The article discusses the development and dissemination of open-source neurophotonic tools for neuroscience research. It highlights the importance of accessibility for technology adoption in neurobiology and showcases examples of successful open-source tools like the UCLA Miniscope Project. The document also includes papers on widefield imaging systems, software packages for dendritic analysis, advancements in miniaturized neurophotonic interfaces, and evaluation methods for neuroscience imaging tools. Overall, the article emphasizes the impact of open-source development on advancing neuroscience research and encourages collaboration among scientists from diverse fields for innovative discoveries. [Extracted from the article]

Published

2024

27. Te Cluster Engineering for Tunable Optical Response.

Author

Dong, Quan, Huang, Yupeng, Chen, Jingfei, Zhang, Ke, Feng, Xu, Li, Xueliang, Qiu, Jianrong, and Zhou, Shifeng

Subjects

*OPTICAL engineering, *PHOTON emission, *GLASS fibers, *OPTICAL materials, *GLASS structure

Abstract

The construction of active materials with controllable optical response facilitates the development of advanced photonic devices. However, the achievement of robust active materials with wide wavelength tunable and broadband emission remains a great challenge, mainly due to the fixed energy levels of conventional active dopants and limited inhomogeneous broadening in common hosts. Here, the study proposes that the cluster in the mesoscopic scale of ≈1 nm may break this bottleneck issue and demonstrate a strategy for the management of photon emission by engineering the cluster evolution. The amorphous glass as the host to tailor the characteristic configuration of Te clusters from 1 to 2 nm by control of the topological structures in glass is employed. Impressively, it presents a distinct optical response totally different from the conventional active centers and this enables to construct of active photonic glass with continuously tunable emission from 888 to 1064 nm. More importantly, Te cluster‐activated photonic glass fibers are fabricated and the broadband on‐off gain is successfully achieved. Furthermore, benefiting from the unique tunable emission, novel near‐infrared devices are constructed and their application in imaging is demonstrated. The approach of cluster engineering mediated tunable optical response is believed to bring new opportunities for developing advanced photonic devices. [ABSTRACT FROM AUTHOR]

Published

2024

28. Depth-enhanced high-throughput microscopy by compact PSF engineering.

Author

Opatovski, Nadav, Nehme, Elias, Zoref, Noam, Barzilai, Ilana, Orange Kedem, Reut, Ferdman, Boris, Keselman, Paul, Alalouf, Onit, and Shechtman, Yoav

Subjects

DEEP learning, DEPTH of field, MICROSCOPY, THREE-dimensional imaging, OPTICAL engineering, ENGINEERING

Abstract

High-throughput microscopy is vital for screening applications, where three-dimensional (3D) cellular models play a key role. However, due to defocus susceptibility, current 3D high-throughput microscopes require axial scanning, which lowers throughput and increases photobleaching and photodamage. Point spread function (PSF) engineering is an optical method that enables various 3D imaging capabilities, yet it has not been implemented in high-throughput microscopy due to the cumbersome optical extension it typically requires. Here we demonstrate compact PSF engineering in the objective lens, which allows us to enhance the imaging depth of field and, combined with deep learning, recover 3D information using single snapshots. Beyond the applications shown here, this work showcases the usefulness of high-throughput microscopy in obtaining training data for deep learning-based algorithms, applicable to a variety of microscopy modalities. Implementing point spread function (PSF) engineering in high-throughput microscopy has proved challenging. Here, the authors propose a compact PSF engineering approach, which allows for enhanced depth of field and for the recovery of 3D information using single snapshots. [ABSTRACT FROM AUTHOR]

Published

2024

29. Density functional theory-based strain engineering of electronic optical and thermoelectric properties of A2OX (A = Ga, in and X = S, Se) monolayers.

Author

Khan, Fawad, Ahmad, Iftikhar, Amin, Bin, Ilyas, Muhammad, Sheraz, Khalid, Sidra, Fatima, Misbah Anwar, and Abdullah

Subjects

*THERMOELECTRIC materials, *ELECTRONIC band structure, *MONOMOLECULAR films, *OPTICAL properties, *OPTICAL engineering, *THERMOELECTRIC apparatus & appliances, *INDIUM, *CHALCOGENS

Abstract

The realization of Janus monolayers presents an exciting opportunity to disrupt structural symmetry, opening up novel avenues in the realm of layered materials. While several ternary systems, comprising the group-III monochalcogenides, has been proposed for this purpose, the impact of oxygen interaction on the electronic, thermoelectric and optical characteristics of gallium and indium monochalcogenides has been observed. Interestingly, the concept of incorporating oxygen as a third element in ternary systems has not yet been explored extensively. Here we embark on the design and exploration of 2D A2OX (A = Ga, In and X = S, Se) monolayer through first-principles calculations. Our investigation includes the analysis of electronic band structure, optical and thermoelectric properties, revealing that Ga2OS, Ga2OSe and In2OS exhibit direct band nature. However, In2OSe is found to be metallic in unstrained condition. Moreover, the band gap in these materials can be fine-tuned through the application of tensile or compressive strain. Additionally, our analysis suggests strong optical absorption within the visible, and/or ultraviolet regions, depending on the specific system under consideration. Our findings reveal that Ga2OS and In2OS monolayers elevated power factors with application of tensile strain, rendering them as compelling candidates for applications in thermoelectric devices. [ABSTRACT FROM AUTHOR]

Published

2024

30. A highly effective analytical approach to innovate the novel closed form soliton solutions of the Kadomtsev–Petviashivili equations with applications.

Author

Borhan, J. R. M., Ganie, Abdul Hamid, Miah, M. Mamun, Iqbal, M. Ashik, Seadawy, Aly R., and Mishra, Nidhish Kumar

Subjects

*KADOMTSEV-Petviashvili equation, *INTEGRO-differential equations, *QUANTUM electronics, *NONLINEAR waves, *OPTICAL engineering, *SOLITONS, *DARBOUX transformations, *SINE-Gordon equation

Abstract

Nonlinear partial integro-differential equations (PIDEs) are applied to present the various practical phenomena in a multitude of sectors of modern science and engineering, especially in optic fiber, quantum electronics, modern physics, and the special field of nonlinear wave motion. Basically, our research demonstrates a way to generate a significant quantity of solutions to these types of two PIDEs. In this research, we have used an efficient mathematical tool namely the generalized G ′ / G -expansion method to acquire the closed form soliton solutions for the (2 + 1)-dimensional first integro-differential Kadomtsev–Petviashivili (KP) hierarchy equation and the (2 + 1)-dimensional second integro-differential KP hierarchy equation utilizing a code likely Mathematica. The explicit closed form soliton solutions of these two PIDEs are found in the pattern of trigonometric, hyperbolic, and rational functions which are compared to all the well-known results that are yielded in the paper. We attain solutions that are graphically displayed in addition to physically described in 3D structure, contour, and 2D, such as a bell-shaped soliton, a singular bell-shaped soliton, and some kink-shaped solitons. As far as the authors' wisdom, the outcomes of these problems gained by the offered expansion method are renewed closed form solitary wave and investigated here for the first time. The analysis of obtained results will be able to provide a constructive explanation of the physical phenomena in optical physics and engineering. [ABSTRACT FROM AUTHOR]

Published

2024

31. Optical engineering using UV ozone treatment in flexible copper electrode deposited on PET.

Author

Abdullah, Mohammedali, Selvamani, Muthamizh, Ramamurthy, Praveen C., and Kesavan, Arul Varman

Subjects

*COPPER electrodes, *POLYETHYLENE terephthalate, *OPTICAL engineering, *COPPER, *OZONE, *ULTRAVIOLET-visible spectroscopy

Abstract

The need of high transparency and high conducting electrode is largely required in modern flexible and wearable electronics. To fabricate the transparent conducting electrode copper is one of the choices. In this work, copper electrodes of various thicknesses were thermally deposited on the flexible PET substrate. Optical properties of flexible Cu electrodes were treated for various exposer times of UV-Ozone and at various temperature combinations were studied. The optical properties of the electrodes were studied by UV-visible spectroscopy. The change in UV-Ozone treatment alone as well as UV-Ozone exposure at elevated temperatures on the transparency of the Cu electrode were mainly studied. This study suggests that UV-Ozone treatment along with temperature or UV-Ozone exposure alone can be used to alter the transparency of Cu electrode coated on PET substrate. Results suggest that as the Cu film thickness reduces, the reduction in optical transmittance due to UV-O is large. Finally, the mechanism of change in the optical properties of the treated Cu electrodes were discussed. [ABSTRACT FROM AUTHOR]

Published

2024

32. Introduction to Coded Optical Imaging

Author

Liang, Jinyang and Liang, Jinyang, editor

Published

2024

33. Photodiodes can help save apples and the planet.

Author

RUVALCABA PEREZ, ABDEL K., SIESS, GUNTER, BÖHM, VOLKER, and TÜNNERMANN, ANDREAS

Subjects

*PHOTODIODES, *GREENHOUSE gases, *ENGINEERS, *OPTICAL engineering, *LIGHT filters

Abstract

The article discusses how photodiodes can be used to address food waste, particularly in apple production, by providing low-cost, non-invasive sensors to assess fruit ripeness. It highlights that a significant portion of food is wasted globally, contributing to greenhouse gas emissions, and describes a collaborative effort from scientists and engineers to develop sensors capable of measuring apple ripeness through spectroscopic techniques.

Published

2024

34. SEE MORE DEER!

Author

COOK, WILLIAM

Subjects

OPTICAL instruments, DEER, ACHROMATISM, LIGHT transmission, BINOCULAR vision, OPTICAL engineering

Abstract

This document discusses common vision problems that hunters may encounter when using binoculars. It emphasizes that these issues are often due to misunderstandings of optics, binoculars, and physiological conditions, rather than the binoculars themselves. The document provides examples of these misunderstandings, such as incorrect focusing, spatial accommodation issues, and dioptric accommodation issues. It offers solutions and recommendations to address these problems and enhance the hunting experience. Additionally, the document includes advertisements for various binocular models, highlighting their features and benefits. [Extracted from the article]

Published

2024

35. An autonomous design algorithm to experimentally realize three-dimensionally isotropic auxetic network structures without compromising density.

Author

Shen, Meng, Reyes-Martinez, Marcos A., Powell, Louise Ahure, Iadicola, Mark A., Sharma, Abhishek, Byléhn, Fabian, Pashine, Nidhi, Chan, Edwin P., Soles, Christopher L., Jaeger, Heinrich M., and de Pablo, Juan J.

Subjects

AUXETIC materials, POISSON'S ratio, BULK modulus, MODULUS of rigidity, OPTICAL engineering, MEMBRANE separation, DENSITY

Abstract

Auxetic materials have a negative Poisson's ratio and are of significant interest in applications that include impact mitigation, membrane separations and biomedical engineering. While there are numerous examples of structured materials that exhibit auxetic behavior, the examples of engineered auxetic structures is largely limited to periodic lattice structures that are limited to directional or anisotropic auxetic response. Structures that exhibit a three-dimensionally isotropic auxetic response have been, unfortunately, slow to evolve. Here we introduce an inverse design algorithm based on global node optimization to design three-dimensional auxetic metamaterial structures from disordered networks. After specifying the target Poisson's ratio for a structure, an inverse design algorithm is used to adjust the positions of all nodes in a disordered network structure until the desired mechanical response is achieved. The proposed algorithm allows independent control of shear and bulk moduli, while preserving the density and connectivity of the networks. When the angle bending stiffness in the network is kept low, it is possible to realize optimized structures with a Poisson's ratios as low as −0.6. During the optimization, the bulk modulus of these networks decreases by almost two orders of magnitude, but the shear modulus remains largely unaltered. The materials designed in this manner are fabricated by dual-material 3D-printing, and are found to exhibit the mechanical responses that were originally encoded in the computational design engine. The approach proposed here provides a materials-by-design platform that could be extended for engineering of optical, acoustic, and electrical properties, beyond the design of auxetic metamaterials. [ABSTRACT FROM AUTHOR]

Published

2024

36. Interview with optical scientist and engineer Joseph Braat.

Author

Yifeng Shao

Subjects

OPTICAL engineering, OPTICAL transfer function, JOB applications, ANTIREFLECTIVE coatings, FOURIER transform optics, OPTICAL astronomy

Abstract

This article is an interview with optical scientist and engineer Joseph Braat, who discusses his career and contributions to the field of optics. He talks about his experiences at the Institut d'Optique in Paris and his work on holography using spatially incoherent light. Braat also discusses his role in designing the light path for recording and reading optical discs, including CD, DVD, and Blu-ray technology. The article explores the development of optical data storage and lithography technology, noting the challenges faced and advancements made. It concludes with Braat's reflections on his career and advice for students and researchers in the field of optics and photonics. [Extracted from the article]

Published

2024

37. Certification Grade Quantum Dot Luminescent Solar Concentrator Glazing with Optical Wireless Communication Capability for Connected Sustainable Architecture.

Author

Meinardi, Francesco, Bruni, Francesco, Castellan, Claudio, Meucci, Marco, Umair, Ali Muhammad, La Rosa, Marcello, Catani, Jacopo, and Brovelli, Sergio

Subjects

*SOLAR concentrators, *SUSTAINABLE architecture, *QUANTUM dots, *OPTICAL communications, *WIRELESS communications, *OPTICAL engineering

Abstract

Energy sustainability and interconnectivity are the two main pillars on which cutting‐edge architecture is based and require the realization of energy and intelligent devices that can be fully integrated into buildings, capable of meeting stringent regulatory requirements and operating in real‐world conditions. Luminescent solar concentrators, particularly those based on near‐infrared emitting reabsorption‐free quantum dots, are considered good candidates for the realization of semi‐transparent photovoltaic glazing, but despite important advances in optical property engineering strategies, studies of finished devices suitable for real‐world operation are still lacking. In this paper, the first example of a fully assembled quantum dot luminescent solar concentrator‐based photovoltaic glazing is demonstrated that meets all international standards for photovoltaic and building elements. It is also shown that these devices are capable of functioning as efficient Visible Light Communication (VLC) receivers even under full sunlight, thus combining energy and wireless connectivity functions in a realistic solution for smart, sustainable buildings. [ABSTRACT FROM AUTHOR]

Published

2024

38. Prospects and challenges for all-optical thermal management of fiber lasers.

Author

Ballato, John, Dragic, Peter D, and Digonnet, Michel J F

Subjects

*OPTICAL engineering, *OPTICAL glass, *OPTICAL fibers, *FIBER lasers, *LASERS, *LASER cooling, *OPTICAL fiber detectors

Abstract

It is hard to overstate the utility of lasers in modern technology. Optical-fiber-based lasers are of particular value thanks to their combination of small form factors, afforded by the coilability of the thin strands of fiber, and high beam-quality output. The optical fiber geometry also possesses a relatively high surface-area-to-volume ratio, rendering thermal management somewhat more straightforward than in other bulk laser types. Regardless, the generation of heat during the lasing process can still be problematic for a myriad of reasons, and conventional methods of thermal management do not comport with the potential compactness and elegance of fiber lasers as technological solutions. This Perspective summarizes recent advances in glass science and optical fiber engineering to support the provocative premise that heat generation in future laser systems can be entirely managed by a combination of fiber materials and novel laser physics. Letting the fiber manage heat itself would have significant impacts on enhancing system performance while greatly reducing size, weight, power-consumption, and cost. [ABSTRACT FROM AUTHOR]

Published

2024

39. Bandgap engineering and enhanced optical properties of Hf3X2O2 (X = N, P, As) novel 2D MXene structures using first-principles study.

Author

Rahman, S. M. Mahbubur, Hasan Khan, Md. Sakib, and Islam, Md. Rafiqul

Subjects

*OPTICAL properties, *OPTICAL engineering, *LIGHT absorption, *DENSITY functional theory

Abstract

Two-dimensional (2D) MXenes, having comparable transport properties like graphene and a wide spectrum application, are often limited to being used in optoelectronics due to metallic bandgap. Here, by employing density functional theory we report the bandgap engineering and tuning optoelectronic properties through modulating the anions of novel 2D spinel Hf3X2O2 (X = N, P and As) MXenes structures and show that the material class can be among the few semiconducting MXenes. Phonon spectra and cohesive energies confirm that these structures are dynamically stable and chemically exothermic. Modulating anions X = N, P, and As in Hf3X2O2, the electronic bandgaps are found ∼0.46 eV for N, metallic for P, and ∼48 meV for As atoms, suggesting the semiconducting, metallic, and semi-metallic MXenes. The biaxial strains are incorporated to tune the features: In the Hf3N2O2 structure, the bandgap is increased with both compressive and tensile strains, while for the Hf3As2O2 structure, the gap decreased at the GGA-PBE level. For Hf3P2O2 structures, the bandgaps are all metallic irrespective of pristine or biaxial strain. Spin–orbit coupling SOC+GGA reveals that Hf3N2O2 is highly spin responsive while Hf3As2O2 shows semi-metal-to-metallic bandgap transition for pristine as well as biaxial strained conditions. From optical properties analysis, optical absorptions are found located in the visible spectral regions that are also highly receptive to biaxial strains. These properties we have unleashed for the novel Hf3X2O2 (X = N, P, As) semiconducting MXene, thus, show the potentiality of the utilization of the material class in nanoelectronics and optoelectronics applications. [ABSTRACT FROM AUTHOR]

Published

2024

40. Computational Optical Scanning Holography.

Author

Yoneda, Naru, Liu, Jung-Ping, Matoba, Osamu, Saita, Yusuke, and Nomura, Takanori

Subjects

HOLOGRAPHY, SPATIAL light modulators, DIGITAL holographic microscopy, OPTICAL engineering, SEMICONDUCTOR technology

Abstract

Holographic techniques are indispensable tools for modern optical engineering. Over the past two decades, research about incoherent digital holography has continued to attract attention. Optical scanning holography (OSH) can obtain incoherent holograms using single-pixel detection and structured illumination with Fresnel zone patterns (FZPs). Particularly by changing the size of a detector, OSH can also obtain holograms under coherently illuminated conditions. Since 1979, OSH has continuously evolved. According to the evolution of semiconductor technology, spatial light modulators (SLMs) come to be useful for various imaging fields. By using SLM techniques for OSH, the practicality of OSH is improved. These SLM-based OSH methods are termed computational OSH (COSH). In this review, the configurations, recording and reconstruction methods, and proposed applications of COSH are reviewed. [ABSTRACT FROM AUTHOR]

Published

2024

41. A Regional Aerosol Model for the Oceanic Area around Eastern China Based on Aerosol Robotic Network (AERONET).

Author

Chen, Shunping, Dai, Congming, Liu, Nana, Lian, Wentao, Zhang, Yuxuan, Wu, Fan, Zhang, Cong, Cui, Shengcheng, and Wei, Heli

Subjects

*AEROSOLS, *PARTICLE size distribution, *LOGNORMAL distribution, *ATMOSPHERIC models, *OPTICAL engineering

Abstract

A regional aerosol model can complement globally averaged models and improve the accuracy of atmospheric numerical models in local applications. This study established a seasonal aerosol model based on data from the Aerosol Robotic Network (AERONET) of the sea area around eastern China, and its performance in calculating the aerosol optical depth (AOD) was evaluated. The seasonal columnar volume particle size distributions (VPSDs) illustrated a bimodal structure consisting of fine and coarse modes. The VPSDs of spring, autumn, and winter roughly agreed with each other, with their amplitudes of fine and coarse modes being almost equal; however, the fine mode of the summer VPSD was approximately twice as high as that of the coarse mode. Lognormal mode decomposition analysis revealed that fine and coarse modes comprised two sub-modes. Fitting the seasonal VPSDs to the four-mode lognormal distribution yielded a parameterized aerosol size distribution model. Furthermore, seasonal variations in complex refractive indices (CRIs) indicated unignorable changes in aerosol compositions. Overall, error analysis validated that the proposed model could meet accuracy requirements for optical engineering applications, with median AOD calculation errors of less than 0.01. [ABSTRACT FROM AUTHOR]

Published

2024

42. Periodic dynamics of optical skyrmion lattices driven by symmetry.

Author

Zhang, Qiang, Yang, Aiping, Xie, Zhenwei, Shi, Peng, Du, Luping, and Yuan, Xiaocong

Subjects

*OPTICAL vortices, *OPTICAL lattices, *MOMENTUM space, *OPTICAL engineering, *QUANTUM gases, *SYMMETRY, *SKYRMIONS, *QUANTUM states

Abstract

The recently developed concept of optical skyrmions has introduced an exciting dimension to the emerging field of Poincaré engineering in optical lattices. There remains an unexplored territory in investigating system geometries to enhance the versatility of manipulating the topological landscape within optical lattices. Here, we present both experimental and theoretical evidence showcasing the periodic vectorial characteristics of field- and spin-based skyrmion lattices, generated by plasmonic vortices with varying topological charges. Our findings reveal that the geometric symmetry of the system plays a pivotal role in governing the periodic arrangement of these vortex patterns. Building upon this arrangement, the orbital–orbital coupling of plasmonic vortices gives rise to densely packed energy flow distributions, intricately bonded to topological charges. Consequently, this results in the formation of sublattices within the momentum space, each characterized by distinct k-vectors. Skyrmion and meron topologies, driven by the intrinsic spin–orbital coupling, are presented in these lattices. This proposed framework illuminates how symmetry serves as a fundamental tool in the manipulation of optical lattice topologies, opening up new avenues in fields ranging from optical trapping, laser writing, quantum gas microscopy, to electron quantum state control, each of which is poised to benefit from these nontrivial advances. [ABSTRACT FROM AUTHOR]

Published

2024

43. Modeling the Impact of Dye Concentration on Polymer Optical Properties via the Complex Refractive Index: A Pathway to Optical Engineering.

Author

Brissinger, Damien

Subjects

*REFRACTIVE index, *OPTICAL properties, *OPTICAL engineering, *CHEMICAL fingerprinting, *POLYMERS, *DYES & dyeing

Abstract

This work investigates the potential to rely on the complex refractive index to correlate the chemical composition of polymers with their optical properties, including transmittance, reflectance and absorbance. The optical properties of polycarbonate slabs with various controlled concentrations of two dyes were initially measured and analyzed. The reflection and transmission measurements obtained were used to determine the corresponding complex refractive index over a wide range of wavelengths. Comparing it with that of a clear material provided the spectral deviation of the complex refractive index induced by the dye concentrations and resulted in assigning a spectral efficiency to both of them. A modification function of the complex refractive index was established based on this spectral efficiency, which acts as a spectral fingerprint related to each dye. Finally, two samples doped with the two dyes mixed were studied to assess the model's capabilities. On the one hand, based on the measured transmittance, the dye concentrations were determined within a deviation below 8% in comparison with the values provided by the manufacturer. On the other hand, when the dye concentrations were known, the model reproduced the optical properties with good accuracy beyond the limitations of the experimental setup. The model's effectiveness in correlating the chemical composition of polymer with its optical properties through the complex refractive index makes it a valuable asset in analyzing and formulating plastics with intended optical properties. [ABSTRACT FROM AUTHOR]

Published

2024

44. Creating an Array of Parallel Vortical Optical Needles.

Author

Šlevas, Paulius and Orlov, Sergej

Subjects

BESSEL beams, SPATIAL light modulators, OPTICAL vortices, MANUFACTURING processes, LASER beams, NEEDLES & pins

Abstract

We propose a method for creating parallel Bessel-like vortical optical needles with an arbitrary axial intensity distribution via the superposition of different cone-angle Bessel vortices. We analyzed the interplay between the separation of individual optical vortical needles and their respective lengths and introduce a super-Gaussian function as their axial profile. We also analyzed the physical limitations to observe well-separated optical needles, as they are influenced by the mutual interference of the individual beams. To verify our theoretical and numerical results, we generated controllable spatial arrays of individual Bessel beams with various numbers and spatial separations by altering the spectrum of the incoming laser beam via the spatial light modulator. We demonstrate experimentally how to implement such beams using a diffractive mask. The presented method facilitates the creation of diverse spatial intensity distributions in three dimensions, potentially finding applications in specific microfabrication tasks or other contexts. These beams may have benefits in laser material processing applications such as nanochannel machining, glass via production, modification of glass refractive indices, and glass dicing. [ABSTRACT FROM AUTHOR]

Published

2024

45. Advancements in Biomedical Applications of Calcium Phosphate Glass and Glass-Based Devices—A Review.

Author

Pandayil, Jawad T., Boetti, Nadia G., and Janner, Davide

Subjects

PHOSPHATE glass, CALCIUM phosphate, GLASS fibers, BIOMATERIALS, BIOACTIVE glasses, OPTICAL engineering, DOPING agents (Chemistry)

Abstract

Calcium phosphate (CaP) glass has recently gained popularity as a promising material for a wide range of biomedical applications. Recent developments have seen CaP glasses moving from a passive implant material to an active degradable material, particularly as a major constituent of bioresorbable photonic devices. This holds great promise in advanced biomedical applications, since the main constituents of CaP glasses are present in the human body. In this review, the progressive advancements in the biomedical applications of calcium phosphate glass-based devices over the past 50 years are discussed. An overview of their role as reinforcing agents and the studies on doping their matrices for ion releasing and drug and gene delivery are reviewed. Recent applications of CaP glass and fibers in soft-tissue engineering and their potential for optical quality bioresorbable devices are then discussed along with the current challenges and potential future directions, emphasizing the promising role of CaP glass in the next generation of biomaterials. Considering their progress and potential in performing several biomedical functionalities over time, CaP glass-based devices hold promise for becoming enabling tools as an implantable, bioresorbable, multifunctional class of devices in future biomedicine. [ABSTRACT FROM AUTHOR]

Published

2024

46. Lightweight mini-endoscope for two color imaging of neural activities with large field of view

Author

Loïc Tabourin, Frédéric Bretzner, and Tigran Galstian

Subjects

Miniaturized microscopy, 2-color microscopy, Optical engineering, Brain imaging, Freely behaving animal, Optics. Light, QC350-467

Abstract

We present the design and the experimental characterization of a miniature “portable” mini-endoscope with a large field-of-view (≈360rmmum) that operates with two spectral bands adapted for mCherry (peak emission at 610 nm) and GCaMP6s (peak emission at 513 nm) fluorophores. The diameter of the implant is very small (0.5 mm), the total weight is 1.8 g, the size is 10×12×21mm3, and the lateral resolution of the device is ≈4.5μm. This compact and lightweight system allows investigation of the neural activity of two different neuronal populations.

Published

2024

47. Electron irradiation-induced paramagnetic and fluorescent defects in type Ib high pressure–high temperature microcrystalline diamonds and their evolution upon annealing.

Author

Nunn, Nicholas, Milikisiyants, Sergey, Danilov, Evgeny O., Torelli, Marco D., Dei Cas, Laura, Zaitsev, Alexander, Shenderova, Olga, Smirnov, Alex I., and Shames, Alexander I.

Subjects

*ELECTRON beams, *NANODIAMONDS, *ELECTRON paramagnetic resonance, *ELECTRON paramagnetic resonance spectroscopy, *DIAMONDS, *HIGH temperatures, *OPTICAL engineering

Abstract

Defects introduced to synthetic type Ib diamond micrometer-size particles by electron-beam irradiation were studied by electron paramagnetic resonance and photoluminescence (PL) spectroscopy as a function of e-beam fluence and post-irradiation thermal annealing. Increasing electron-beam fluence causes a substantial reduction of the substitutional nitrogen (P1) content, accompanied by progressively higher concentrations of paramagnetic negatively charged vacancies (V−) and triplet interstitials (R1/R2). Annealing results in a drastic decrease in the V− and R1/R2 content and an increase in the negatively charged nitrogen-vacancies (NV− or W15). Analysis of PL spectra allows for identification of color centers in the irradiated diamond samples and following their evolution after annealing. These data facilitate understanding of different factors contributing to the formation of color centers in diamond and promote efforts toward controlled engineering of optical centers in fluorescent diamond particles. [ABSTRACT FROM AUTHOR]

Published

2022

48. P‐48: Evaluation of Field of View in Optical See‐through Near Eye Displays.

Author

Mou, Xi, Peng, Xiaopeng, and Wang, Jianping

Subjects

OPTICAL engineering, VIRTUAL reality, OPTICAL measurements, AUGMENTED reality, DIGITAL technology

Abstract

See‐through near‐eye displays, such as head‐mounted displays and augmented reality glasses, integrate physical environment with virtual digital contents to form a cohesive world that combines both realities. Field‐of‐view (FOV) is a critical parameter determines the optical performance of these displays. Here we evaluate the see‐through FOV of an optical see‐through near eye display. The evaluation is based on the standardized Michelson contrast method, which provides a unified metric for the measurement of see‐through FOV in near‐eye displays. [ABSTRACT FROM AUTHOR]

Published

2024

49. Electrically controlled optical nonlinear effects in the hybrid opto-electromechanical system with the cross-Kerr effect.

Author

Zhou, Ya-Fei, Qin, Li-Guo, Huang, Jie-Hui, Wang, Li-Li, Tian, Li-Jun, Wang, Zhong-Yang, and Gong, Shang-Qing

Subjects

*HYBRID systems, *KERR electro-optical effect, *OPTICAL control, *FOUR-wave mixing, *PHOTON counting, *OPTICAL engineering

Abstract

We theoretically study the nonlinear optical phenomena including optical stability state and four-wave mixing (FWM) process in a hybrid opto-electromechanical system with the cross-Kerr (CK) effect. The hybrid system consists of an optomechanical cavity in which the cross-Kerr (CK) effect and Coulomb interaction are simultaneously introduced by the CK medium and the mechanical resonator capacitively coupling to an external circuit, respectively. The CK interaction induces a tristability behavior of the mean intracavity photon number, which can be modulated by the strength of the CK effect and electrically controlled by the voltage on the capacitor. In addition, we give the effects of the optomechanical, CK, and Coulomb coupling strengths on the FWM of the output field. The results show that the voltage can be employed to electrically engineer the optical nonlinear phenomena. [ABSTRACT FROM AUTHOR]

Published

2022

50. Spinning meta-optics for spectro-polarimetric thermal imaging?

Author

JOHNSON, SALLY COLE

Subjects

*THERMOGRAPHY, *POLARIMETRY, *THERMAL imaging cameras, *OPTICAL engineering, *IMAGING systems, *OPTICAL materials, *ANTIREFLECTIVE coatings, *INFRARED cameras

Abstract

The article focuses on improving thermal imaging through heat-assisted detection and ranging (HADAR), developed by Professor Zubin Jacob's group at Purdue University, which enhances texture details and enables machine perception in darkness. It reports that recent advancements in meta-optics have led to a metasurface-based approach for spectro-polarimetric thermal imaging, allowing for compact and effective capture of spectral and polarization details.

Published

2024