Your search keyword '"Wavelength"' showing total 191,137 results

1. Investigation of the Variability Characteristics of Sound Waves Reflected on the Sea Surface Considering Surface Wavelength

Author

Shinnosuke Hirata, Tomoya Tsukui, and Hiroyuki Hachiya

Subjects

Surface (mathematics), Wavelength, Optics, business.industry, General Medicine, business, Geology, Sound wave

Published

2023

2. Effect of Nd:YAG laser on the optical properties of nanoparticle CuO solutions

Author

Sahar Naji Rashid and Awatif Sabir Jasim

Subjects

Materials science, business.industry, Nanoparticle, General Medicine, Laser, law.invention, Absorbance, Wavelength, law, Nd:YAG laser, Transmittance, Optoelectronics, Irradiation, Thin film, business

Abstract

One of the most important industrial applications of lasers is the treatment of materials. In this work pulsed Nd:YAG laser of wavelength (1064 nm) was used to precipitate the prepared solution of CuO nanoparticles in the form of thin films using energies (300, 400, 500 and 600 mJ) at a distance (10 cm) and for an irradiation period (20 s) for each energy. The optical properties of the material were examined, which include transmittance, absorbance and some other optical constants, in addition to calculating the optical energy gap and knowing the effect of increasing the laser energy on its values.

Published

2023

3. Investigation on the theory of planar photonic crystal based CZTS/CdS solar cell

Author

K. S. Joseph Wilson and M. Ismail Fathima

Subjects

010302 applied physics, Materials science, business.industry, Photovoltaic system, 02 engineering and technology, General Medicine, Dielectric, 021001 nanoscience & nanotechnology, 01 natural sciences, law.invention, chemistry.chemical_compound, Wavelength, Planar, Stack (abstract data type), chemistry, law, 0103 physical sciences, Solar cell, Optoelectronics, CZTS, 0210 nano-technology, business, Photonic crystal

Abstract

The effect of planar photonic crystal on CZTS/CdS solar cell is systematically investigated. The reflective properties of PhC ARC which consists of the periodic stack of ZnO and HfO2 with two numbers of periods having quarter wavelength thickness are analyzed. Similarly, the DBR having periodic stacks of HfO2 and ZnO dielectric layers with four numbers of periods having half wavelength thickness in CZTS/CdS solar cells are explored. Moreover, the results of the photovoltaic properties of CZTS/CdS solar cells are also analyzed. The outcome of the findings obtained from the computation using the transfer matrix method are very well agreeable with the recent literature. The planar (ZnO /HfO2)2 PhC ARC and (ZnO/HfO2)4 DBR has been expected to provide significant improvement in the performance of CZTS/CdS solar cells.

Published

2023

4. Cell-type continuous electromagnetic radiation system generating millimeter waves for active denial system applications

Author

In-Keun Baek, Sukhwal Ma, Ohjoon Kwon, Sang Yoon Park, Seonmyeong Kim, Sun-Hong Min, Anirban Bera, Kyo Chul Lee, Han Byul Kwon, Chawon Park, Seontae Kim, Yong Jin Lee, Gun-Sik Park, Dongpyo Hong, Matlabjon Sattorov, Seunghyuk Park, Ranjan Kumar Barik, Young Joon Yoo, Bong Hwan Hong, and Minho Kim

Subjects

Materials science, business.industry, Mechanical Engineering, Metals and Alloys, Computational Mechanics, Electromagnetic radiation, Wavelength, Optics, Ceramics and Composites, Waveform, Millimeter, Radio frequency, Center frequency, Antenna (radio), Absorption (electromagnetic radiation), business

Abstract

The cell-type continuous electromagnetic radiation system is a demonstration device capable of generating high-power millimeter electromagnetic waves of a specific wavelength and observing their effects on living organisms. It irradiates a biological sample placed in a 30 × 30 × 50 cm3 cell with electromagnetic waves in the 3.15-mm-wavelength region (with an output of ≥1 W) and analyzes the temperature change of the sample. A vacuum electronic device-based coupled-cavity backward-wave oscillator converts the electron energy of the electron beam into radiofrequency (RF) energy and radiates it to the target through an antenna, increasing the temperature through the absorption of RF energy in the skin. The system causes pain and ultimately reduces combat power. A cell-type continuous electromagnetic radiation system consisting of four parts—an electromagnetic-wave generator, a high-voltage power supply, a test cell, and a system controller—generates an RF signal of ≥1 W in a continuous waveform at a 95-GHz center frequency, as well as a chemical solution with a dielectric constant similar to that of the skin of a living organism. An increase of 5 °C lasting approximately 10 s was confirmed through an experiment.

Published

2022

5. Cr3+/Y3+ co-doped persistent luminescence nanoparticles with biological window activation for in vivo repeatable imaging

Author

Yun Zhang, Junpeng Shi, Huimin Jiang, Lin Liu, Shenghui Zheng, Xianggui Yin, Kexin Yu, and Liang Song

Subjects

Materials science, business.industry, Nanoparticle, 02 engineering and technology, General Chemistry, 010402 general chemistry, 021001 nanoscience & nanotechnology, medicine.disease_cause, 01 natural sciences, 0104 chemical sciences, Ion, Wavelength, Persistent luminescence, Geochemistry and Petrology, Excited state, medicine, Optoelectronics, Surface modification, 0210 nano-technology, Luminescence, business, Ultraviolet

Abstract

The near-infrared (NIR) persistent luminescence materials (PLMs) can remain long-lasting luminescence after removal of the excitation light, which permits bioimaging with high sensitivity owing to the absence of background fluorescence interference from in situ excitation. Recently, the NIR PLMs have aroused intensive research interest in bioimaging. However, the optimal excitation wavelength of current NIR PLMs is located in the ultraviolet region with shallow tissue penetration, making it difficult to activate effectively in vivo, and seriously hindering their further application in bioimaging. Herein, we report a novel kind of Cr3+ ions and Y3+ ions co-doped NIR PLM, Zn1.3Ga1.4Sn0.3O4:Cr3+,Y3+ (ZGSCY), which emits NIR persistent luminescence at 696 nm. Compared with Zn1.3Ga1.4Sn0.3O4:Cr3+ (ZGSC) excited by the light with a wavelength in the biological window (>650 nm), after being co-doped with Y3+ ions, the NIR persistent luminescence performance of ZGSCY is significantly improved because of the increase of trap concentration in the matrix. In addition, we synthesized ZGSCY nanoparticles (NPs) by the combustion method, which exhibit excellent optical properties after being excited by the light with a wavelength in the biological window. After surface modification with PEG, the ZGSCY NPs present low cytotoxicity. Notably, due to the co-doping of Y3+ ions, the signal-to-noise ratio (SNR) of ZGSCY NPs in vivo imaging is about 1.8 times higher than that of the ZGSC NPs. Furthermore, the rechargeable in vivo imaging and passive tumor-targeted imaging are successfully achieved by activating with a light-emitting diode (LED, 659 nm) after intravenous injection of ZGSCY. Thus, this kind of NIR PLM with high excitation efficiency performance in the biological window is expected to promote its biomedical application in deep tissues.

Published

2022

6. Forest Height Inversion via RVoG Model and Its Uncertainties Analysis via Bayesian Framework—Comparisons of Different Wavelengths and Baselines

Author

Zhang, Yongxin Zhang, Han Zhao, Yongjie Ji, Tingwei Zhang, and Wangfei

Subjects

PolInSAR, forest height, RvoG model, baseline length, wavelength, uncertainties

Abstract

Accurate estimation of forest height over a large area is beneficial to reduce the uncertainty of forest carbon sink estimation, which is of great significance to the terrestrial carbon cycle, global climate change, forest resource management, and forest-related scientific research. Forest height inversion using polarimetric interferometry synthetic aperture radar (PolInSAR) data through Random volume over ground (RVoG) models has demonstrated great potential for large-area forest height mapping. However, the wavelength and baseline length used for the PolInSAR data acquisition plays an important role during the forest height estimation procedure. In this paper, X–, C–, L–, and P–band PolInSAR datasets with four different baseline lengths were simulated and applied to explore the effects of wavelength and baseline length on forest height inversion using RVoG models. Hierarchical Bayesian models developed with a likelihood function of RVoG model were developed for estimated results uncertainty quantification and decrease. Then a similar procedure was applied in the L– and P–band airborne PolInSAR datasets with three different baselines for each band. The results showed that (1) Wavelength showed obvious effects on forest height inversion results with the RVoG model. For the simulated PolInSAR datasets, the L– and P–bands performed better than the X– and C–bands. The best performance was obtained at the P–band with a baseline combination of 10 × 4 m with an absolute error of 0.05 m and an accuracy of 97%. For the airborne PolInSAR datasets, an L–band with the longest baseline of 24 m in this study showed the best performance with R2 = 0.64, RMSE = 3.32 m, and Acc. = 77.78%. (2) It is crucial to select suitable baseline lengths to obtain accurate forest height estimation results. In the four baseline combinations of simulated PolInSAR datasets, the baseline combination of 10 × 4 m both at the L– and P–bands performed best than other baseline combinations. While for the airborne PolInSAR datasets, the longest baseline in three different baselines obtained the highest accuracy at both L– and P–bands. (3) Bayesian framework is useful for estimation results uncertainty quantification and decrease. The uncertainties related to wavelength and baseline length. The uncertainties were reduced obviously at longer wavelengths and suitable baselines.

Published

2023

7. Full-field Ultrasonic Data Analysis Based on Statistical Covariance Method

Author

See Yenn Chong and Michael D. Todd

Subjects

Wavelength, Laser scanning, law, Acoustics, Range (statistics), Group velocity, Ultrasonic sensor, Covariance, Covariance method, Laser, Mathematics, law.invention

Abstract

Laser ultrasonic techniques (LUTs) are becoming widely used for damage detection based on full-field ultrasonic data. In general, LUTs provide threedimensional (3-D) ultrasonic signals from which significant informative features may be extracted about the health condition of a structure. In this paper, statistical convariance method is proposed to investigate 3-D ultrasonic features. A laser ultrasonic interrogation method based on a Q-switched laser scanning system was used to interrogate 3-D ultrasonic signals in to a 2 mm aluminum plate. The ultrasonic signals in three-dimensional (3-D) space were generated, indexed by spatial N (xdirection), spatial M (y-direction), and temporal K (t-direction) samples, respectively. Then, two sets of covariance matrices were obtained based on the vector variables in x-direction and y-direction respectively for all k time samples respectively. The covariance imaging and the corresponding variance map were obtained. The wavelength and group velocity of S0 and A0 modes were able estimated from the variance map. The wavelength of the S0 and A0 modes were estimated with the deviation error of 2.3% and 11% respectively. The group velocities of S0 and A0 modes were estimated with the deviation error of 1.8% and 0.9%. The analysis will be further performed to develop group velocity curves for a range of frequency in metal and composite plates.

Published

2023

8. Investigations on 2D photonic crystal based cross waveguide structure consisting of resonant cavity

Author

Man Mohan Gupta

Subjects

010302 applied physics, Materials science, business.industry, Finite-difference time-domain method, Physics::Optics, 02 engineering and technology, General Medicine, 021001 nanoscience & nanotechnology, 01 natural sciences, Rod, law.invention, Wavelength, Nonlinear system, Optics, Transmission (telecommunications), law, 0103 physical sciences, Point (geometry), 0210 nano-technology, business, Waveguide, Photonic crystal

Abstract

Two dimensional (2D) Photonic crystals (PhCs) based cross waveguide structure (CWs) consisting of resonant cavity is investigated in this paper. Investigations are done using Two Dimensional Finite Difference Time Domain (2DFDTD) method. Transmission characteristics have been obtained for different radii of central rod placed at crossing point of two waveguides and number of regular rods surrounding central rod. Nonlinear behavior is also studied for different operating wavelengths.

Published

2023

9. Experimental measurements for attenuation recovery in optical fiber cables under gamma and neutron irradiation

Author

Adel Zaghloul, Moteaa A. Nassar, Imbaby I. Mahmoud, Mohamed S. El_Tokhy, and Magdy M. Zaky

Subjects

Optical fiber, Materials science, business.industry, Attenuation, Fiber Cable, General Engineering, Single-mode optical fiber, Radiation, Neutron radiation, Single Mode, Engineering (General). Civil engineering (General), law.invention, Wavelength, Optics, Gamma Rays, law, Neutron, Research reactor, TA1-2040, business, Neutron Irradiation, Power Meter

Abstract

The influence of neutron and gamma radiation on single mode fiber cables is experimentally conducted. Attenuation due to incident radiation is measured. Attenuation is determined by laser source and power meter in Africa Teleco Company, besides attenuation recovery is attained. The Gamma experiment is carried out within Egypt Mega Gamma1 in National Center for Radiation Research and Technology of Egyptian Atomic Energy Authority (EAEA). In this experiment, the cable is degraded by gamma radiation of doses 5KGy, 10KGy, 15KGy and 25KGy and dose rate of 1KGy/26.4 min. However the attenuation based on neutron degradation is executed in the second Egyptian Training Research Reactor (ETRR-2), in front of neutron beam facility (NBF) in ETRR-2 which has a flux of 1.5x107(n/cm2.sec). For both experiments, the experimental measurements are done at two different spectral wavelengths of 1310 nm and 1550 nm. A comparison between obtained results is investigated.

Published

2022

10. Road Surface Recognition at mm-Wavelengths Using a Polarimetric Radar

Author

Vessen Vassilev

Subjects

Surface (mathematics), Materials science, Mechanical Engineering, Polarimetry, Computer Science Applications, law.invention, Wavelength, law, Angle of incidence (optics), Automotive Engineering, Scattering parameters, Surface roughness, Coherence (signal processing), Radar, Physics::Atmospheric and Oceanic Physics, Remote sensing

Abstract

We demonstrate detection of ice formations on a road surface using a polarimetric radar operating at 87.5-92.5 GHz. The radar measures the scattering parameters of the surface at horizontal and vertical polarizations and their cross-polarization components. We demonstrate detection of ice for radar beam directed at up to 45⁰ angle of incidence with respect to the surface which allows for road surface characterization in front of a vehicle. The method used is based on a statistical approach where the 2-port scattering parameters are measured multiple times and used to calculate an average scatter coherence matrix representing the surface. The coherence matrix is then decomposed to eigenvalues/vectors, which are used to estimate polarimetric attributes such as target entropy(degree of randomness) and polarimetric pedestal (degree of depolarization). Through measurements of dry, ice-covered and wet road surfaces, we show that both entropy and depolarization are increased with respect to dry surface when a thin ice layer is formed, while their value decrease for the case of wet surface. It is also shown that these polarimetric attributes are not sensitive to surface roughness in dry conditions, minimizing the probability of false alarm due to road surface wear.

Published

2022

11. High-Precision Tunable Single-Frequency Fiber Laser at 1.5 μm Based on Self-Injection Locking

Author

Qilai Zhao, Changsheng Yang, Zhongmin Yang, Wei Lin, Zhe Guan, Linhuan Huang, Shanhui Xu, Kaijun Zhou, and Tianyi Tan

Subjects

Materials science, business.industry, Relative intensity noise, Optical communication, Laser, Atomic and Molecular Physics, and Optics, Electronic, Optical and Magnetic Materials, Power (physics), law.invention, Wavelength, Laser linewidth, Fiber Bragg grating, law, Fiber laser, Optoelectronics, Electrical and Electronic Engineering, business

Abstract

A high-precision tunable single-frequency fiber laser (T-SFFL) at 1.5 μm based on self-injection locking is experimentally demonstrated. By virtue of an effective filtering and self-injection locking scheme, a stable single-longitudinal-mode operation of the fiber laser is obtained. The fine wavelength tunability is implemented by stretching a uniform fiber Bragg grating in the self-injection loop, and the laser wavelength is tuned from 1550.28 to 1560.40 nm with a tuning accuracy of less than 54 pm. In the whole tuning range of 10.12 nm, an output power of approximately 5 mW and an optical signal-to-noise ratio of 71 dB are synchronously obtained with this laser system. Additionally, the measured laser linewidth is less than 630 Hz and the relative intensity noise is lower than -149 dB/Hz at frequencies from 0.4 to 7.5 MHz. It is believed that this 1.5 μm high-precision T-SFFL can be a promising candidate for the optical communications system applications.

Published

2022

12. The Impact of the Wavelength and Its Transmittance on the Visual Evoked Potentials, at Baseline, and under the Effect of Six Monochromatic Filters Used for Visual Treatments

Author

Danjela Ibrahimi, Enoé Crúz-Martínez, Guillermo Valencia Luna, Josué Romero Turrubiates, and Juvenal Rodríguez-Reséndiz

Subjects

visual-evoked potentials, neural activity, monochromatic filter, wavelength, transmittance, Electrical and Electronic Engineering, Biochemistry, Instrumentation, Atomic and Molecular Physics, and Optics, Analytical Chemistry

Abstract

Purpose: This is an observational, non-invasive study which measures the VEPs of twelve individuals, at baseline, and under the effect of six monochromatic filters used in visual therapy, to understand their effect on neural activity to propose successful treatments. Methods: Monochromatic filters were chosen to represent the visible light spectrum, going from red to violet color, 440.5–731 nm, and light transmittance from 19 to 89.17%. Two of the participants presented accommodative esotropia. The impact of each filter, differences, and similarities among them, were analyzed using non-parametric statistics. Results: There was an increase on the N75 and P100 latency of both eyes and a decrease was on the VEP amplitude. The neurasthenic (violet), omega (blue), and mu (green) filter had the biggest effects on the neural activity. Changes may primarily be attributable to transmittance (%) for blue-violet colors, wavelength (nm) for yellow-red colors, and a combination of both for the green color. No significant VEPs differences were seen in accommodative strabismic patients, which reflects the good integrity and functionality of their visual pathway. Conclusions: Monochromatic filters, influenced the axonal activation and the number of fibers that get connected after stimulating the visual pathway, as well as the time needed for the stimulus to reach the visual cortex and thalamus. Consequently, modulations to the neural activity could be due to the visual and non-visual pathway. Considering the different types of strabismus and amblyopia, and their cortical-visual adaptations, the effect of these wavelengths should be explored in other categories of visual dysfunctions, to understand the neurophysiology underlying the changes on neural activity.

Published

2023

13. Can we Bring EM Enhancement to the Multi-wavelength Scale?*

Author

Stavroula Foteinopoulou

Subjects

Physics, Wavelength, Waveguide (electromagnetism), Cover (topology), Computer Science::Multimedia, Physics::Optics, Lambda, Plasmon, Beam (structure), Energy (signal processing), Intensity (heat transfer), Computational physics

Abstract

EM enhancement is typically a lensing-type of effect by which a wide input beam couples to spatially localized resonant modes as for example Mie plasmons, void plasmons or Mie modes at high refractive index particles. Accordingly, EM enhancement is inherently a subwavelength phenomenon. Here, we explore a different paradigm for EM enhancement that is based on EM energy being collected over large time intervals by means of an ultra-slow-light waveguide. With ab-initio simulations, we study the dynamic evolution of such EM enhancement. After more than 7000 wave periods we observe that an intensity enhancement of more than 50 can cover an area of more than 15 $\lambda_{free^{2}}$ with $\lambda_{free}$ being the free-space wavelength.

Published

2023

14. Application of Taguchi based gray relational analysis to optimize laser welding

Author

Marjanović, Vinko, Cukor, Goran, Bonefačić, Igor, and Iljkić, Dario

Subjects

analysis of variance, diode, CO2 laser, wavelength, gray relational analyse, frequency, pumping, Nd:YAG laser, laser welding, Laser, ruby laser, Taguchi method, optimization

Abstract

U ovom diplomskom radu odrađena je optimizacija parametara laserskog zavarivanja čelika P92, čija je primjena relativno specifična s obzirom na karakteristike kao što su velika toplinska otpornost, otpornost na oksidaciju, velika čvrstoća i tvrdoća te mu je glavna primjena u elektranama s fosilnim gorivima. U prvom dijelu rada detaljno je objašnjen rad lasera, osnovni dijelovi, princip rada i glavna podjela lasera. Također, detaljno su opisani laseri koji se najčešće koriste kao što su: Nd:YAG, CO2, rubinski, He-Ne, dušikov i drugi laseri. U drugom dijelu rada (eksperimentalnom) provedena je Taguchi temeljena siva relacijska analiza kako bi se optimirali parametri zavarivanja, određen je S/N omjer za pojedine parametre i geometrijske karakteristike te je naposljetku izvedena analiza varijance (ANOVA) ., In this work, the optimization of laser welding parameters of P92 steel was performed, which application is relatively specific considering its characteristics such as high heat resistance, oxidation resistance, high strength and hardness, and its main application is in power plants with fossil fuels. In the first part of the work, the operation of the laser, the basic parts, the principle of operation and the main division of the laser are explained in detail. Also, the most commonly used lasers are described in detail, such as: Nd:YAG, CO2, ruby, He-Ne, nitrogen and other lasers. In the second part of the work (experimental), a Taguchi gray relational analysis was performed in order to optimize the welding parameters, the S/N ratio was determined for individual parameters and geometric characteristics, and finally an analysis of variance (ANOVA) was performed.

Published

2023

15. The Effect of the Position Determination Error for Flexible Linear Array Elements on the Tomogram Focusing

Author

Dmitry A. Sednev, Alexey I. Soldatov, Andrey A. Soldatov, Maria A. Kostina, and Daria A. Koneva

Subjects

curved surface, flexible acoustic array, focusing, Strehl ratio, total focusing method, tomogram, wavelength, Electrical and Electronic Engineering, Biochemistry, Instrumentation, Atomic and Molecular Physics, and Optics, Analytical Chemistry

Abstract

In the article, the study of the quality of tomogram focusing during the inspection of objects with curved surfaces by flexible acoustic array was described. The main goal of the study was theoretically and experimentally define the acceptable deviation limits of the elements’ coordinates values. The tomogram reconstruction was performed by the total focusing method. The Strehl ratio was chosen as a criterion for assessing the quality of tomogram focusing. The ultrasonic inspection procedure were simulated and validated experimentally by means of convex and concave curved arrays. In the study, it was proven that the elements coordinates of the flexible acoustic array were determined with an error of no more than 0.18λ and the tomogram image was obtained in sharp focus.

Published

2023

16. A Machine Learning Specklegram Wavemeter (MaSWave) Based on a Short Section of Multimode Fiber as the Dispersive Element

Author

Ogbole C. Inalegwu, Rex E. Gerald II, and Jie Huang

Subjects

wavelength, multimode fiber (MMF), machine learning, convolutional neural network (CNN), specklegram, speckle patterns, charge-coupled device (CCD) camera, Electrical and Electronic Engineering, Biochemistry, Instrumentation, Atomic and Molecular Physics, and Optics, Analytical Chemistry

Abstract

Wavemeters are very important for precise and accurate measurements of both pulses and continuous-wave optical sources. Conventional wavemeters employ gratings, prisms, and other wavelength-sensitive devices in their design. Here, we report a simple and low-cost wavemeter based on a section of multimode fiber (MMF). The concept is to correlate the multimodal interference pattern (i.e., speckle patterns or specklegrams) at the end face of an MMF with the wavelength of the input light source. Through a series of experiments, specklegrams from the end face of an MMF as captured by a CCD camera (acting as a low-cost interrogation unit) were analyzed using a convolutional neural network (CNN) model. The developed machine learning specklegram wavemeter (MaSWave) can accurately map specklegrams of wavelengths up to 1 pm resolution when employing a 0.1 m long MMF. Moreover, the CNN was trained with several categories of image datasets (from 10 nm to 1 pm wavelength shifts). In addition, analysis for different step-index and graded-index MMF types was carried out. The work shows how further robustness to the effects of environmental changes (mainly vibrations and temperature changes) can be achieved at the expense of decreased wavelength shift resolution, by employing a shorter length MMF section (e.g., 0.02 m long MMF). In summary, this work demonstrates how a machine learning model can be used for the analysis of specklegrams in the design of a wavemeter.

Published

2023

17. Detection of marine aerosols using ocean colour sensors

Author

Mannil Mohan and Indrani Das

Subjects

Atmospheric Science, Near-infrared spectroscopy, Atmospheric correction, Radiation, Aerosol, symbols.namesake, Wavelength, Geophysics, Atmosphere of Earth, symbols, Radiance, Environmental science, Rayleigh scattering, Remote sensing

Abstract

Ocean colour sensors are equipped with atmospheric correction bands operating in the near infrared region of the spectrum. At these wavelengths, the ocean surface, because of high infrared absorption by water, acts as a dark background and the sensor detected radiance is due to solar radiation backscattered by the atmospheric air molecules and aerosols called Rayleigh and aerosol path radiances respectively. From the radiances in the atmospheric correction bands, after accounting for Rayleigh path radiance, it is possible to determine aerosol parameters like aerosol optical depth (AOD) and particle size distribution index. While sensors like IRS P3 MOS-B, IRS P4 OCM, NOAA-AVHRR, etc detect AOD in the total atmospheric column, IRS P3 MOS-A sensor can detect AOD in two atmospheric layers by exploiting the differential absorption property of oxygen at four narrow band channels at the O2 A band around 760nm. The method of determination from ocean colour sensors and the results from IRS P3 MOS-B, IRS P4-OCM and IRS P3 MOS-A radiance data are presented and discussed.

Published

2022

18. A comprehensive study on meltpool depth in laser-based powder bed fusion of Inconel 718

Author

Mahyar Khorasani, AmirHossein Ghasemi, Martin Leary, Laura Cordova, Elmira Sharabian, Ehsan Farabi, Ian Gibson, Milan Brandt, Bernard Rolfe, and Design Engineering

Subjects

Meltpool depth, Control and Systems Engineering, Additive manufacturing, Mechanical Engineering, Laser-based powder bed fusion, Wavelength, Laser irradiation, Industrial and Manufacturing Engineering, Software, Computer Science Applications

Abstract

One problematic task in the laser-based powder bed fusion (LB-PBF) process is the estimation of meltpool depth, which is a function of the process parameters and thermophysical properties of the materials. In this research, the effective factors that drive the meltpool depth such as optical penetration depth, angle of incidence, the ratio of laser power to scan speed, surface properties and plasma formation are discussed. The model is useful to estimate the meltpool depth for various manufacturing conditions. A proposed methodology is based on the simulation of a set of process parameters to obtain the variation of meltpool depth and temperature, followed by validation with reference to experimental test data. Numerical simulation of the LB-PBF process was performed using the computational scientific tool “Flow3D Version 11.2” to obtain the meltpool features. The simulation data was then developed into a predictive analytical model for meltpool depth and temperature based on the thermophysical powder properties and associated parameters. The novelty and contribution of this research are characterising the fundamental governing factors on meltpool depth and developing an analytical model based on process parameters and powder properties. The predictor model helps to accurately estimate the meltpool depth which is important and has to be sufficient to effectively fuse the powder to the build plate or the previously solidified layers ensuring proper bonding quality. Results showed that the developed analytical model has a high accuracy to predict the meltpool depth. The model is useful to rapidly estimate the optimal process window before setting up the manufacturing tasks and can therefore save on lead-time and cost. This methodology is generally applied to Inconel 718 processing and is generalisable for any powder of interest. The discussions identified how the effective physical factors govern the induced heat versus meltpool depth which can affect the bonding and the quality of LB-PBF components.

Published

2022

19. Si2Te3 Photodetectors for Optoelectronic Integration at Telecommunication Wavelengths

Author

Juan Villegas, Mahmoud Rasras, Bruna Paredes, Ghada Dushaq, and Srinivasa Reddy Tamalampudi

Subjects

Wavelength, Materials science, business.industry, Optoelectronics, Photodetector, Electrical and Electronic Engineering, business, Atomic and Molecular Physics, and Optics

Published

2022

20. Ultra-high negative dispersion compensating modified square shape photonic crystal fiber for optical broadband communication

Author

Bikash Kumar Paul, K.P. Sai Pradeep, M. Thillai Rani, Kawsar Ahmed, and Fahad Ahmed Al-Zahrani

Subjects

Materials science, business.industry, Photonic crystal fiber, General Engineering, Optical communication, Engineering (General). Civil engineering (General), Single mode fiber, Square (algebra), Finite element method, Wavelength, Dispersion (optics), Optoelectronics, Fiber, Ultra high negative dispersion, TA1-2040, Anisotropy, business, Nonlinearity, Optical Communication, Photonic-crystal fiber

Abstract

In this work, a modified square photonic crystal fiber (MS-PCF) architecture is exposed with ultra-high negative dispersion for communication window. The validation of the model is successfully performed by applying an efficient full-vector finite element method (FV-FEM) with anisotropic perfectly matched layers (PMLs) for precise simulation of PCFs. Additionally, waveguide dispersion engineering is accomplished by tuning the structural parameters of the MS-PCF. From the numerical investigation, negative dispersion behavior permits remarkable suppression rather than positive dispersion. It offers the high negative dispersion of −2357.54 ps/nm/km and Kerr nonlinearity (γ) of 74.68 W−1 km−1 simultaneously at the operating wavelength, λ = 1550 nm. Nevertheless, the designed fiber ensures the mono mode operation in the entire band of interest from λ = 1340 nm to λ = 1580 nm. MS-PCF with these outstanding optical performances has distinguished potency to be practiced as a dispersion compensating fiber in optical communication systems.

Published

2022

21. A fiber Bragg grating based earth and water pressures transducer with three-dimensional fused deposition modeling for soil mass

Author

Shanshan Zhang, Jiaming Yan, Dongsheng Xu, Yue Qin, and Qiankun Wang

Subjects

Wavelength, Transducer, Materials science, Fused deposition modeling, Fiber Bragg grating, law, Effective stress, Acoustics, Calibration, Geotechnical Engineering and Engineering Geology, Pressure vessel, Soil mechanics, law.invention

Abstract

A novel fiber Bragg grating (FBG) sensor with three-dimensional (3D) fused deposition modeling (FDM) approach is proposed for effective stress measurement in soil mass. The three-diaphragm structure design is developed to measure earth and water pressures simultaneously. The proposed transducer has advantages of small size, high sensitivity, low cost, immunity to electromagnetic interference and rapid prototyping. The working principle, design parameters, and manufacturing details are discussed. The proposed transducer was calibrated for earth and water pressures measurement by using weights and a specially designed pressure chamber, respectively. The calibration results showed that the wavelength of the transducer was proportional to the applied pressure. The sensitivity coefficients of the earth and water pressures were 12.633 nm/MPa and 6.282 nm/MPa, respectively. Repeated tests and error analysis demonstrated the excellent stability and accuracy of the earth and water pressure measurements. The performance of the proposed transducer was further verified by a model experimental test and numerical analysis, which indicated that the proposed transducer has great potential for practical applications. © 2021 Institute of Rock and Soil Mechanics, Chinese Academy of Sciences. Production and hosting by Elsevier B.V. This is an open access article under the CC BY-NC-ND license ( http://creativecommons.org/ licenses/by-nc-nd/4.0/).

Published

2022

22. Omnidirectional Antenna Diversity System for High-Speed Onboard Communication

Author

Zhijun Zhang, Yongjian Zhang, Yue Li, Zhenghe Feng, and Weiquan Zhang

Subjects

Physics, Environmental Engineering, General Computer Science, Materials Science (miscellaneous), General Chemical Engineering, Acoustics, Bandwidth (signal processing), General Engineering, Energy Engineering and Power Technology, 02 engineering and technology, 010402 general chemistry, 021001 nanoscience & nanotechnology, Antenna diversity, 01 natural sciences, 0104 chemical sciences, Radiation pattern, Azimuth, Wavelength, Windage, Center frequency, 0210 nano-technology, Omnidirectional antenna

Abstract

In this article, an omnidirectional dual-polarized antenna with synergetic electromagnetic and aerodynamic properties is propounded for high-speed diversity systems. The propounded antenna comprises a probe-fed cavity for horizontally polarized radiation and a microstrip-fed slot for vertical polarization. Double-layer metasurfaces are properly designed as artificial magnetic conductor boundaries with direct metal-mountable onboard installation and compact sizes. An attached wedge-shaped block is utilized for windage reduction in hydrodynamics. The propounded antenna is fabricated for design verification, and the experimental results agree well with the simulated ones. For vertical polarization, the operating bandwidth is in the range of 2.37–2.55 GHz, and the realized gain variation in the azimuthal radiation pattern is 3.67 decibels (dB). While an impedance bandwidth in the range of 2.45–2.47 GHz and a gain variation of 3.71 dB are also achieved for the horizontal polarization. A port isolation more than 33 dB is obtained in a compact volume of 0.247λ0 × 0.345λ0 × 0.074λ0, where λ0 represents the wavelength in vacuum at the center frequency, wherein the wedge-shaped block is included. The propounded diversity antenna has electromagnetic and aerodynamic merits, and exhibits an excellent potential for high-speed onboard communication.

Published

2022

23. Hydrodynamic performance of the dual-chamber oscillating water column device placed over the undulated sea bed

Author

Kshma Trivedi and Santanu Koley

Subjects

Radiation, Materials science, Oscillating Water Column, Resonance, Efficiency, Mechanics, Dual-chamber OWC-WEC, Turbine, TK1-9971, Wavelength, General Energy, Amplitude, Hull, Wavenumber, Electrical engineering. Electronics. Nuclear engineering, Seabed

Abstract

The present study analyzed the efficiency of the dual-chamber oscillating water column device placed over the undulated bottom. The efficiency of the device is studied for various shape parameters such as chamber lengths, the draft of the lip wall of the device, turbine damping coefficients, and ripples of the corrugated bottom. It is seen that the efficiency initially increases as the wavenumber increases. However, the efficiency of the device becomes lower for shorter incident wavelength. The amplitude of the resonance becomes higher for device having wider chamber. Similar higher resonance occurs when the turbine damping coefficients and the number of ripples of the corrugated bottom take higher values. An opposite pattern is formed with the variation in draft of the lip wall of the device. The draft of the outer chamber plays a dominant role in enhancing the efficiency as compared to the draft of the inner chamber of the device. Further, the efficiency becomes higher as the turbine damping coefficient takes the higher values.

Published

2022

24. Enhancement of red upconversion emission intensity of Ho3+ ions in NaLuF4:Yb3+/Ho3+/Ce3+@NaLuF4 core–shell nanoparticles

Author

Shanshan Han, Xuewen Yan, Jihong Liu, Yu Xing, Wei Gao, Lin Liu, Qingyan Han, Binhui Chen, Xiaotong Cheng, and Jun Dong

Subjects

Wavelength, Materials science, Geochemistry and Petrology, Analytical chemistry, Nanoparticle, General Chemistry, Core shell nanoparticles, Luminescence, Emission intensity, Photon upconversion, Excitation, Ion

Abstract

The red upconversion emission of Ho3+ ions, in the optical window of biological tissue, exhibits excellent prospects in biological applications. This study aims to enhance the red upconversion emission intensity of Ho3+ ions in NaLuF4:20%Yb3+/2%Ho3+/12%Ce3+ nanoparticles through building different core-shell structures with different excitation wavelengths. A significantly enhanced red upconversion emission with a higher red-to-green ratio was successfully obtained in NaLuF4:20%Yb3+/2%Ho3+/12%Ce3+@NaLuF4 core-shell nanoparticles by introducing the Yb3+ and Yb3+/Nd3+ ions into the NaLuF4 shell, with enhancement of the red emission occurring when Yb3+ and Nd3+ ions in the shell transfer more excitation energy to the Ho3+ ions. Investigation of the red emission enhancement mechanism is based on spectral characteristics and lifetimes. We examined the synergistic effect of dual-wavelength co-excitation NaLuF4:20%Yb3+/2%Ho3+/12% Ce3+@NaLuF4:10%Yb3+/15%Nd3+ core-shell nanoparticles to establish optimal excitation conditions. It is hoped that this method, using red upconversion emission core-shell nanoparticles with multi-mode excitation, can provide new ways to expand the applications of rare-earth luminescent materials in biomedicine and anti-counterfeiting.

Published

2022

25. The Design of >2000-nm, ∼100-MHz Ultrafast Tm-Doped Fiber Soliton Laser Source

Author

Yu zhi Song, Yuefeng Zhao, Tianli Feng, Tao Li, Kejian Yang, Shengzhi Zhao, Jingcheng Shang, Chun Wang, Ping Hu, Yizhou Liu, and Jiajia Mao

Subjects

Materials science, business.industry, Physics::Optics, Soliton (optics), Laser, Atomic and Molecular Physics, and Optics, Pulse (physics), law.invention, Wavelength, symbols.namesake, law, Fiber laser, symbols, Optoelectronics, Continuous wave, business, Raman spectroscopy, Ultrashort pulse

Abstract

We firstly propose a roadmap for the design of high repetition rate (~100 MHz) Tm-doped ultrafast fiber laser with an emission wavelength above 2000 nm. This roadmap is confirmed by both theoretical simulation and experimental verification. The designed Tm-doped fiber oscillator not only operates in continuous wave regime with a broad tunable wavelength range of ~ 100 nm, but also in mode-locking regime with an emission wavelength > 2000 nm (up to 2020 nm). A 470-fs laser pulse with a pulse repetition rate of ~96 MHz and the maximum average power of 50 mW are achieved at the output wavelength of 2007 nm, matching well with the theoretical prediction. In a further step, the seed laser pulse is amplified to 3.3 W, accompanied by a Raman frequency shift of the output wavelength to 2346 nm. The homogeneous intense broadband spectrum with a bandwidth of 240-nm centered at 2200 nm is also observed.

Published

2022

26. Overall Non-Mechanical Spectrally Steered LiDAR Using Chirped Amplitude-Modulated Phase-Shift Method

Author

Shinji Yamashita, Chao Zhang, Takuma Shirahata, Zheyuan Zhang, and Sze Yun Set

Subjects

Physics, Signal processing, business.industry, Ranging, Laser, Signal, Atomic and Molecular Physics, and Optics, law.invention, Wavelength, Lidar, Amplitude, Optics, Modulation, law, business

Abstract

We propose and demonstrate an overall non-mechanical spectrally steered laser rangefinder using the dispersion-tuned swept laser (DTSL) and a passive diffractive element. The DTSL has no mechanical moving parts, making it possible to achieve an inertial-free high wavelength sweeping speed. The inherent intensity-modulation characteristic of the DTSL allows the modulation phase-shift method to be applied, similar to that used for an amplitude-modulated continuous-wave (AMCW) rangefinder. Since the pulse repetition rate of the DTSL is chirped, standard signal processing techniques for AMCW are not applicable. In this paper, we propose a novel chirped amplitude-modulated phase-shift (CAMPS) method with a signal processing technique to obtain the phase-shift information from a chirped amplitude-modulated signal. As a proof of concept, we demonstrated the CAMPS LiDAR with an axial ranging resolution of ~50 m at a scanning speed of 10 kHz.

Published

2022

27. Spectral Dependence of Photovoltaic Cell Conversion Efficiency for Monochromatic Radiation

Author

M. Takesawa and T. Saito

Subjects

Physics, business.industry, Energy conversion efficiency, Photovoltaic system, Irradiance, Physics::Optics, Radiation, Photodiode, law.invention, Wavelength, Solar cell efficiency, Optics, law, Optoelectronics, business, Absorption (electromagnetic radiation)

Abstract

Theoretical limit of solar cell conversion efficiency given by Shockley and Queisser is calculated for the case that the cell is illuminated by solar radiation. If the input radiation is monochromatic, the efficiency can exceed the limit. The aim of our study is to experimentally demonstrate this theoretical prediction and to obtain the experimental results of spectral dependence of photovoltaic cell conversion efficiency. Conversion efficiencies of two types of Si photodiodes (equivalent to solar cells) are determined through the measurements of current–voltage characteristics as a function of the wavelength and the incident radiant power. As the theory predicts, it has been confirmed that the conversion efficiency is almost proportional to the wavelength and also to the logarithm of the incident radiant power. Also, it has been experimentally confirmed that the power conversion efficiency for long wavelength monochromatic radiation is higher than that for white radiation.

Published

2022

28. Optical Amplifiers for Multi–Band Optical Transmission Systems

Author

Lutz Rapp and Michael Eiselt

Subjects

Optical amplifier, Materials science, business.industry, Amplifier, Physics::Optics, Transmission system, Laser pumping, Atomic and Molecular Physics, and Optics, Wavelength, Multi band, Transmission (telecommunications), Optoelectronics, business, Diode

Abstract

Opening new wavelength bands is the most economic step for further increasing the capacity of optical transmission links. Characteristics of different amplifier technologies for signal amplification in different wavelength bands are detailed. In particular, the suitability of these technologies for short-term and mid-term implementation is considered. An important criterion is the availability of qualified components, notably the required pump laser diodes. On this basis, solutions for the near-term and the mid-term are discussed.

Published

2022

29. 320×256 Extended Wavelength InxGa1-xAs/InP Focal Plane Arrays: Dislocation Defect, Dark Signal and Noise

Author

Yu Chen, Jiaxiong Fang, Yingjie Ma, Xue Li, Zhu Xianliang, Xiumei Shao, Yage Liu, Tao Li, Yonggang Zhang, Yi Gu, Haimei Gong, Cheng Jifeng, and Deng Shuangyan

Subjects

Time delay and integration, Materials science, business.industry, Infrared, Shot noise, Signal, Atomic and Molecular Physics, and Optics, Wavelength, Optics, Electrical and Electronic Engineering, Dislocation, business, Noise (radio), Dark current

Abstract

In0.75Ga0.25As and In0.83Ga0.17As 320×256 short-wave infrared focal plane arrays (SWIR FPAs) with pixel pitches of 24 and 30 μm, extended cutoff wavelengths of 2.2 and 2.5 μm, low dark current densities of 5.2 and 21 nA/cm2, and high peak detectivities of 6×1011 and 6×1012 cmHz1/2W−1 are attained at 180 K, respectively. Lower 1/f noises and smaller knee frequencies are observed for the 2.2 μm FPA, indicates the dislocation defect-related trap states act as the major contributor for the 1/f noise. The non-uniformities of the dark signal and the dark noise are roughly the same for both FPAs at a short integration time of 1 ms (29% and 25% at 180 K, respectively) whereas are much smaller for the 2.2 μm FPA at longer integration times. Moreover, the dark current shot noise dominant integration time ranges are determined to be >20 and >2 ms for the 2.2 and 2.5 μm FPAs, respectively. Enhanced heat signature recording capability is also observed for wider SWIR spectral range while more effective suppression routes of dislocation defect must be incorporated for further improved sensitivity.

Published

2022

30. High-Speed 850 nm Photodetector for Zero-Bias Operation

Author

Baile Chen, Zhiqi Zhou, Zhiyang Xie, Linze Li, Haiming Ji, and Zhuo Deng

Subjects

Materials science, business.industry, Photodetector, Atomic and Molecular Physics, and Optics, Photodiode, law.invention, Wavelength, Quantum capacitance, law, Eye pattern, Bandwidth (computing), Optoelectronics, Quantum efficiency, Electrical and Electronic Engineering, business, Dark current

Abstract

High-speed photodetector operating at 850 nm wavelength with a large diameter and high quantum efficiency is desirable to meet the growing demands of short-reach optical links for high-performance computing systems. Zero-bias operation of the high-speed photodetectors can reduce power consumption, minimize system complexity of the optical transceivers and reduce the radiation damage in a harsh environment. Traditional p-i-n photodetectors for 850 nm applications often require a high reverse bias to accelerate the carrier transport for high-speed data transmission. In this work, we demonstrate a high-speed and low dark current modified uni-traveling-carrier photodiode based on GaAs/AlGaAs at 850 nm wavelength operating under zero bias with a quantum efficiency of 73%. The 3-dB bandwidth of the 20 μm and 40 μm diameter devices is 22.5 GHz and 13.3 GHz, respectively. A clear eye pattern is demonstrated at a 25.8 Gbit/s data rate for the device under zero-bias operation. To the best of our knowledge, this photodetector demonstrates the highest 3-dB bandwidth among all the zero-bias 850 nm photodetectors reported to date.

Published

2022

31. Surface-wave tomography for mineral exploration: a successful combination of passive and active data (Siilinjärvi phosphorus mine, Finland)

Author

Emilia Anna-Liisa Koivisto, Chiara Colombero, Tuomas Kauti, Myrto Papadopoulou, Pietari Skyttä, Mikko Savolainen, Laura Socco, and Department of Geosciences and Geography

Subjects

1171 Geosciences, Stratigraphy, Paleontology, Soil Science, Geology, Seismic noise, Classification of discontinuities, Azimuth, Mineral exploration, Wavelength, Geophysics, RESOLUTION, Surface wave, Geochemistry and Petrology, Tomography, AMBIENT-NOISE TOMOGRAPHY, Dispersion (water waves), Seismology, Earth-Surface Processes

Abstract

Surface wave (SW) methods offer promising options for an effective and sustainable development of seismic exploration, but they still remain under-exploited in hard rock sites. We present a successful application of active and passive surface wave tomography for the characterization of the southern continuation of the Siilinjärvi phosphate deposit (Finland). A semi-automatic workflow for the extraction of the path-average dispersion curves (DCs) from ambient seismic noise data is proposed, including identification of time windows with strong coherent SW signal, azimuth analysis and two-station method for DC picking. DCs retrieved from passive data are compared with active SW tomography results recently obtained at the site. Passive data are found to carry information at longer wavelengths, thus extending the investigation depth. Active and passive DCs are consequently inverted together to retrieve a deep pseudo-3D shear-wave velocity model for the site, with improved resolution. The southern continuation of the mineralization, its contacts with the host rocks and different sets of cross-cutting diabase dikes are well imaged in the final velocity model. The seismic results are compared with the latest available geological models to both validate the proposed workflow and improve the interpretation of the geometry and extent of the mineralization. Important large-scale geological boundaries and structural discontinuities are recognized from the results, demonstrating the effectiveness and advantages of the methods for mineral exploration perspectives.

Published

2022

32. Effect of Laser Wavelength on Diode Laser Ignition of Boron Potassium Nitrate

Author

Nakano, Masakatsu

Subjects

Vacuum, Wavelength, Diode Laser, B/KNO3, Laser Ignition

Published

2022

33. Multicolor luminescence of hexagonal NaYF4:Yb3+/Ho3+/Ce3+ microcrystals with tunable morphology under 940 nm excitation for temperature-responsive anti-counterfeiting

Author

Junwen Mao, Lingna Xu, Tao Pang, and Hongyan Zheng

Subjects

Materials science, Morphology (linguistics), Doping, Analytical chemistry, 02 engineering and technology, General Chemistry, Atmospheric temperature range, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, Photon upconversion, 0104 chemical sciences, Wavelength, Geochemistry and Petrology, Excited state, 0210 nano-technology, Luminescence, Excitation

Abstract

In this study, the hexagonal NaYF4:Yb3+/Ho3+/Ce3+ microcrystals were synthesized controllably, and upconversion luminescence excited at 940 nm and its application in temperature-responsive anti-counterfeiting are reported. It is clarified that the Ln3+ (Ln = Y + Yb + Ho + Ce) density ratio of bottom plane to side plane in the unit cell can be regulated by Ce3+ doping. It is also proved that the energy transfer of Yb3+ to Ho3+ is responsible for the activation of Ho3+ under 940 nm excitation, while the cross relaxation between Ho3+ and Ce3+ participates in the redistribution of electron population of 5S2/5F4 and 5F5 levels. Both theory and experiment confirm that the intensity ratio of red to green emission (IR/IG) as a function of temperature as an independent variable has good linear characteristics in the temperature range of 300–500 K. Due to the good responsiveness of multicolor luminescence to temperature, the hexagonal NaYF4:Yb3+/Ho3+/Ce3+ with tunable morphology is a promising candidate for advanced temperature-responsive upconversion anti-counterfeiting. Our results provide a new pathway for the controllable synthesis of hexagonal NaYF4 microcrystals as well as the regulation of upconversion luminescence that is excited by wavelengths other than 980 nm and its application in anti-counterfeiting.

Published

2022

34. Plasmon-Enhanced Light Absorption in Mid-Wavelength Infrared HgCdTe Detectors

Author

Giovanni Ghione, Stefan Hanna, Michele Goano, Anne Wegmann, Alberto Tibaldi, Francesco Bertazzi, H. Figgemeier, Marco Vallone, and D. Eich

Subjects

Materials science, Electromagnetics, Infrared, business.industry, HgCdTe, FDTD, Detector, Physics::Optics, focal plane arrays, plasmonics, Atomic and Molecular Physics, and Optics, infrared detectors, Wavelength, Responsivity, Planar, Optoelectronics, Electrical and Electronic Engineering, Absorption (electromagnetic radiation), business, Plasmon

Abstract

Multiphysics modeling of a planar HgCdTe-based mid-wavelength infrared (MWIR) focal plane array with $3\,\mu$ m-wide pixels enlightens the role of surface plasmon-polaritons observed in gold nanorods arranged on its illuminated face. Simulations indicate that the proposed plasmonic detector, which employs a $1\,\mu$ m-thick absorber layer, exhibits a reduction of diffusive inter-pixel crosstalk by more than one order of magnitude with respect to more conventional, non-plasmonic detectors with a $5\,\mu$ m-thick absorber layer, without penalizing responsivity and achieving increased detectivity in the whole MWIR band by taking advantage of the absorber volume reduction.

Published

2022

35. Influence of size and shape on optical properties of cesium tungsten bronze: An experimental and theoretical approach

Author

Miao Sun, Changwei Sun, Yong-Hong Ma, Luomeng Chao, Jiaxin Li, and Jia Liu

Subjects

Hexagonal prism, Materials science, Process Chemistry and Technology, Nanoparticle, chemistry.chemical_element, Tungsten, Aspect ratio (image), Nanocrystalline material, Surfaces, Coatings and Films, Electronic, Optical and Magnetic Materials, Wavelength, chemistry, Extinction (optical mineralogy), Materials Chemistry, Ceramics and Composites, Particle size, Composite material

Abstract

Although the optical properties of nanocrystalline cesium tungsten bronze have been widely studied, there is a lack of research on the effect of particle size on its optical properties. In order to further investigate size and shape effect on the NIR shielding performance, cesium tungsten bronze nanoparticles with different sizes and morphologies were prepared by two methods. The size of irregular shaped samples prepared by solvothermal method is tens of nanometers, while the size of hexagonal prism shaped samples prepared by solid state reaction method is hundreds of nanometers. The element spectrums shows that there are more oxygen vacancies in large particles than in small particles. The NIR shielding performance of large particles far lower than that of small particles, indicating that the influence of shape and size on optical properties is more obvious than that of oxygen vacancy. Theoretical calculation on hexagonal prism shaped particles exhibits that the NIR extinction of large aspect ratio is better at longer wavelength and small aspect ratio is better at shorter wavelength.

Published

2022

36. Quantum Efficiency and Crosstalk in Subwavelength HgCdTe Dual Band Infrared Detectors

Author

Giovanni Ghione, Francesco Bertazzi, H. Figgemeier, Marco Vallone, Stefan Hanna, Alberto Tibaldi, Michele Goano, Anne Wegmann, and D. Eich

Subjects

Diffraction, Infrared, Aperture, FDTD, HgCdTe, II-VI semiconductor materials, Photodetector, inter-pixel crosstalk, Optical diffraction, Optical imaging, Dot pitch, Optics, Electrical and Electronic Engineering, Crosstalk, Physics, business.industry, Cadmium compounds, Detectors, focal plane arrays, Infrared detectors, Optical crosstalk, Atomic and Molecular Physics, and Optics, Wavelength, Quantum efficiency, Multi-band device, business

Abstract

This work investigates the spectral quantum efficiency and inter-pixel crosstalk of a MWIR-LWIR dual band, HgCdTe-based focal plane array (FPA) photodetector (MWIR and LWIR stand for mid- and long-wavelength infrared bands). Pixels are $\text{10}\,\mu$ m-wide with truncated pyramid geometry and separated by deep trenches. Three-dimensional combined full-wave electromagnetic and electrical simulations in the drift-diffusion approximation allowed to describe the complex, standing-wave-like spectral features resulting from the light interference and diffraction due to the pixels and illuminating beam aperture. The inter-pixel crosstalk for the MWIR operation demonstrated to be very sensitive to the trench depth, in contrast to the LWIR electrooptical response, left almost unchanged. The present work also investigates the causes of performance worsening in the two IR bands when pixel pitch is reduced to $\text{5}\,\mu$ m, hence well below typical LWIR wavelengths and close to the diffraction limited operation.

Published

2022

37. Design and Analytical Evaluation of a High Resistance Sensitivity Bolometer Sensor Based on Plasmonic Metasurface Structure

Author

Ali Farmani, Ali Mir, and Abbas Hamouleh-Alipour

Subjects

business.industry, Bolometer, Surface plasmon polariton, Atomic and Molecular Physics, and Optics, law.invention, Wavelength, law, Optoelectronics, Figure of merit, Sensitivity (control systems), Electrical and Electronic Engineering, business, Temperature coefficient, Refractive index, Plasmon

Abstract

Bolometer sensors are prominent and excellent choice in technology because they do not need cooling. The trade-off between high sensitivity, fast response time, and strong light absorption is a key important challenge in bolometer sensors. Here, the bolometric effect for a high resistance sensitivity plasmonic sensing of total and profile infusion of radiation is studied for the proposed bolometer sensor based on plasmonic multilayer structure at 26° C. In the present study, by generating strong coupling condition between incident wave and surface plasmon polaritons (SPPs), a very narrow absorption spectra with high figure of merit (FoM) is achieved. The analytical model and numerical simulation are fulfilled based on the transfer matrix method (TMM) and 3-D finite-difference time-domain (FDTD), respectively. The narrow absorption spectra that generate by strong coupling with SPPs heats the silver thin film that leads to variation in temperature and supports TE surface mode. This temperature change rectifies the resistance of the metal thin film by the bolometric effect. So, optical characteristics of the proposed metasurface bolometer sensor, including quality factor (Q), sensitivity, and figure of merit (FoM) are calculated that Max sensitivity, FoM, and Q are 17.2 RIU-1, 530 and 434.5, respectively. Finally, we analytically simulate the temperature coefficient of resistance (TCR) in terms of wavelength and refractive index of analyte (na) that this resistance change can be monitored by an external electric model. The proposed plasmonic multilayer configuration is a very compact footprint structure that achieved high resistance sensitivity and FoM in comparison with any previous reports. This proposed thermal, optical, and electric plasmonic metasurface bolometer sensor can be used in different applications such as biophysics, biology, and environmental science.

Published

2022

38. Polarization-Maintaining Performance of Solid-Core Anti-Resonant Fiber With Nested Circular Tubes in 3 μm Wavelength

Author

Jianquan Yao, Hao Tian, Shuai Sun, Shuai Zhang, Quan Sheng, Wei Shi, and Zhongbao Yan

Subjects

Materials science, Birefringence, business.industry, Physics::Optics, Polarizer, Laser, Polarization (waves), Atomic and Molecular Physics, and Optics, law.invention, Wavelength, Optics, law, Fiber, business, Refractive index, Order of magnitude

Abstract

We present the structural design and polarization-maintaining performance of solid-core anti-resonant fiber with two nested circular tubes in 3 m wavelength for the first time, to the best of our knowledge. Numerical simulation results indicated that laser fundamental mode could be obtained by filling the specially designed fiber model with materials of different refractive indices to form the completely solid configuration. We calculated the bend loss of fiber to demonstrate the preferable birefringence performance and outstanding light-confining ability. With the structural deformations from resonant tubes, the birefringence coefficient was enhanced significantly from 210-5 to 6.9310-5, which was of great importance in the polarization sensitive systems. In particular, when nested circular tubes were moved to introduce deformations, the confined loss difference in two orthogonal polarizations was calculated more than two orders of magnitude, which was the desirable result to promote the fabrication of the linear polarizer in 3 m wavelength.

Published

2022

39. Kerr Frequency Comb Generation in Microsphere Resonators With Normal Dispersion

Author

H. Y. Fu, Maolin Dai, Qian Li, Zhenmin Chen, and Xin Tu

Subjects

Work (thermodynamics), Materials science, business.industry, Physics::Optics, Radius, Atomic and Molecular Physics, and Optics, Resonator, Wavelength, Frequency comb, Optics, Mode coupling, Dispersion point, business, Dispersion (chemistry)

Abstract

In this work, we carry out theoretical investigation of the dispersion relationship both with the radius of the microsphere cavity and wavelength for the first two radial-order mode based on the theory of microcavity dispersion. The results show that the size of the microcavity corresponding to the zero dispersion point of the higher order mode is larger than that of lower order mode at the certain wavelength. The microsphere cavities with slight deformations, which have rich modes and high Q values, have been fabricated and optical frequency comb (OFC) in them with small size is realized by means of mode coupling. We have achieved OFC in cavities as small as 105 m in diameter by assistance of the theoretical study. The total dispersions are -7.1 MHz in 1550 nm and -14.2 MHz in 1310 nm, which are both in the normal dispersion region.

Published

2022

40. Comparative Spectrophotometer Analysis of Ultraviolet-light Filtering, Blue-light Filtering, and Violet-light Filtering Intraocular Lenses

Author

Jeong Woo Park and Chul Young Choi

Subjects

Lenses, Intraocular, Ultraviolet Rays, business.industry, media_common.quotation_subject, medicine.medical_treatment, Intraocular lens, General Medicine, Retina, Spectral line, Wavelength, Optics, Intraocular lenses, Ultraviolet light, Transmittance, medicine, Humans, Contrast (vision), Scotopic vision, business, media_common

Abstract

Purpose: To compare the light transmittance property of seven currently used intraocular lens (IOL) models by spectrophotometer data.Methods: Light transmission spectra of seven IOL models were assessed with a spectrophotometer. The transmittance properties were analyzed in 1 nm units from 350 nm wavelength to 800 nm.Results: Three ultraviolet filtering IOL models (ZCB00, XC1-SP, and AT LISA 809M) showed nearly full transmittance of the light from 400 to 500 nm, while steeply attenuating light with shorter wavelengths in various degrees. Three blue-light filtering IOLs (yellow-tinted IOLs; XY1, SN60WF, and TNFT00) showed a slow-sloped increase of light transmission between 400 to 500nm. Among the three, XY1 showed different degree of inclination, showing a steeper slope than SN60WF and TNFT00. The violet-light filtering IOL (ZFR00V) showed a rapid increase of the transmission at around 435 nm wavelength, which is similar to ultraviolet filtering IOLs.Conclusions: The seven different IOLs measured showed different characteristics of light transmission depending on the properties of each material and color. Blue-light filtering IOLs tend to blocked a wide range of wavelength up to 500 nm, but rather were not effective at the range of 400 to 430 nm. Violet-light filtering IOL showed advantages in filtering the high-energy wavelength, around 430 nm, having a potential risk to retina and allowing the transmission of useful blue and green wavelength which is necessary for a better scotopic contrast sensitivity.

Published

2022

41. Low-Sidelobe-Level Circularly Polarized Short Leaky-Wave Antenna With A-Shaped Element Based on Substrate Integrated Image Guide

Author

Yong Fan, Ya Fei Wu, Yu Jian Cheng, and Yi Zhang

Subjects

Physics, Wavelength, Waveguide (electromagnetism), Optics, Amplitude, Axial ratio, business.industry, Leaky wave antenna, Feed line, Substrate (electronics), Electrical and Electronic Engineering, Antenna (radio), business

Abstract

In this paper, a low sidelobe-level (SLL) circularly-polarized (CP) leaky-wave antenna with A-shaped elements is proposed based on substrate integrated image guide (SIIG). The A-shaped CP radiating element consists of a horizontal LP structure and a vertical LP structure. The horizontal LP wave and the vertical LP wave can be excited by a pair of inclined transversal metal strip patches and a longitudinal metal strip patch respectively. Their phases are orthogonal and amplitudes can be controlled to be equal by adjusting the tilted angle of the horizontal LP structure and the length of the vertical LP structure. Moreover, the longitudinal metal strip patch is modified to the V-shaped strip patch, which can realize the field cancellation, thereby achieving the boresight radiation for such a leaky-wave antenna. Furthermore, a low SLL is realized by controlling the aperture-field distribution to obtain the desired amplitude distribution and the relatively small axial ratio (AR). In addition, because of the short waveguide wavelength of the SIIG, this feed line can be used to achieve the small interelement spacing and element size, thereby realizing the short length of the array. The measured peak gain of this antenna is 12.3 dBi and the SLL is 19.1 dB.

Published

2022

42. Novel multicolor-tunable Eu3+/Bi3+ co-doped Y2Zr2O7 transparent ceramics as potential white-light-emitting materials

Author

Yucheng Ye, Zhangyi Huang, Yutong Zhang, Lexing Liang, Jianqi Qi, Ajiao Liu, Zhe Tang, and Tiecheng Lu

Subjects

Photoluminescence, Materials science, Transparent ceramics, business.industry, Process Chemistry and Technology, Phosphor, Surfaces, Coatings and Films, Electronic, Optical and Magnetic Materials, Wavelength, visual_art, Materials Chemistry, Ceramics and Composites, visual_art.visual_art_medium, Transmittance, Optoelectronics, Ceramic, business, Luminescence, Excitation

Abstract

In this study, a multicolor-tunable Eu3+/Bi3+:Y2Zr2O7 transparent ceramic was successfully fabricated using vacuum sintering technology for the first time. The single-phase ceramic showed a pore-free structure and highest transmittance of 67% at 1200 nm. To reveal the luminescence properties of the obtained samples, photoluminescence (PL) tests were performed. Upon combining the green emission (centered at 475 nm) from Bi3+ and the red emission (centered at 629 nm) from Eu3+, bright, white light was observed in both the single-phase Eu3+/Bi3+:Y2Zr2O7 phosphors and transparent ceramics (λex = 302 nm). Furthermore, upon changing the excitation wavelengths, strong red (λex = 250 nm) and orange (λex = 365 nm) emissions were also observed at room temperature. The PL spectra and International Commission on illumination (CIE) coordinate diagram show that white light with CIE (0.3528, 0.3121) can be easily achieved. Combined with their excellent high-temperature performance and good mechanical properties, Eu3+/Bi3+:Y2Zr2O7 transparent ceramics have promising potential as white-light-emitting materials.

Published

2022

43. Optical-controlled Fast Switching of Radio Frequency Orbital Angular Momentum Beams With Different Mode and Radiation Direction

Author

Jingcan Ma, Yuchen Yao, Xinlu Gao, Xiyao Song, Zhennan Zheng, Shanguo Huang, and Yunping Bai

Subjects

Physics, Angular momentum, business.industry, Physics::Optics, Optical switch, Multiplexing, Atomic and Molecular Physics, and Optics, Antenna array, Azimuth, Wavelength, Optics, Radio frequency, business, Beam (structure)

Abstract

The wireless imaging radar need more orbital angular momentum (OAM) modes to irradiate targets alternately to obtain higher azimuth resolution. For that, this present paper investigates the fast-switching technique of radio frequency orbital angular momentum (RF-OAM) beam with the use of an optical-controlled system. Compared with the method using pure electrical device, the optical-controlled method offers conveniences in processing same-frequency radio signal, which will contribute to make the system compact. Moreover, the fast-responding speed of the optical device provide a fast speed of switching. The fast-switching system of RF-OAM beams with different mode and radiation direction is proposed and constructed, and proof-of-concept experiments are performed. The proposed system is realized by employing a program-controlled optical switch and the wavelength multiplexing technique integrated into an optical-controlled circular antenna array (CAA). In the demonstration experiments, the switching between +1-mode and -1-mode RF-OAM beams without steering control is detected within 20ms, then the system achieves the switching between a +1-mode OAM beam with radiation direction -3o and a -1-mode OAM beam with radiation direction 3o at the same rate.

Published

2022

44. A Wideband Low-Profile Microstrip MIMO Antenna for 5G Mobile Phones

Author

Bo Cheng and Zhengwei Du

Subjects

Physics, Wavelength, Acoustics, MIMO, Electrical and Electronic Engineering, Antenna (radio), Wideband, Center frequency, Electrical impedance, 5G, Microstrip

Abstract

A wideband low-profile eight-element microstrip multipleinput-multiple-output (MIMO) antenna for 5G mobile phones is proposed. The antenna is designed to be integrated on the back-cover of a mobile phone without occupying its inner space or ground clearance. The elements of the MIMO antenna can simultaneously excite the TM01, TM10, TM02, and TM11 modes, and their broad operating bands come from combining the four modes together. The proposed MIMO antenna which is a simple single-layer plane structure with the thickness of only 0.787 mm is fabricated and tested. The experimental results show that the -6 dB impedance operating band of the MIMO antenna is 4.4-5.04 GHz which can cover the 5G N79 band of 4.4-5 GHz. It achieves a broad relative bandwidth of 13.6% with a low profile of 0.01 λ0, where λ0 is the free-space wavelength of the center frequency. It has the efficiency of higher than 42%, the mutual couplings of lower than -18 dB, the envelope correlation coefficients (ECCs) of lower than 0.24, and the ratios of mean effective gains (MEGs) of lower than 1.96 dB in the operating band.

Published

2022

45. Nitrogen and sulfur co-doped carbon quantum dots as fluorescence sensor for detection of lead ion

Author

Nengqin Jia, Huali Shi, Chaohui Zhou, and Qi Zhao

Subjects

Detection limit, Wavelength, chemistry, Band gap, Doping, Analytical chemistry, chemistry.chemical_element, Fluorescence, Nitrogen, Sulfur, Analytical Chemistry, Ion

Abstract

A fluorescent carbon quantum dots(N-S CQDs) doped with nitrogen, and sulfur with tunable wavelength was successfully prepared by one-step hydrothermal reaction for sensitive detection of Pb2+. The doping of N and S narrows the band gap of the CQDs and makes the wavelength red shift, so that the carbon quantum dots displayed maximum emission peak at 540 nm under 460 nm excitation. The addition of Pb2+ quenched the fluorescence due to the specific combination of Pb2+ with the carboxyl and sulfhydryl on the surface of the CQDs formed a coordination structure. Under optimal conditions, the carbon quantum dots revealed outstanding anti-interference capability and a favorable linear relation was obtained in the scope of 0.2-12 μM and 40-200 μM with the limit of detection of 0.097 μM and 5.624 μM for Pb2+. Besides, the CQDs had been successfully used for monitoring Pb2+ in river water with well accuracy and recovery.

Published

2022

46. Ultracompact Bandpass Filter Based on Slow Wave Substrate Integrated Groove Gap Waveguide

Author

Yue Hao, Jing-Ya Deng, Lixin Guo, Xiaohua Ma, Dongquan Sun, Jia Yuan Yin, and Dan-Dan Yuan

Subjects

Radiation, Materials science, business.industry, Substrate (electronics), Condensed Matter Physics, law.invention, Wavelength, Resonator, Band-pass filter, law, Filter (video), Optoelectronics, Electrical and Electronic Engineering, business, Waveguide, Layer (electronics), Groove (music)

Abstract

This article presents an ultracompact bandpass filter (BPF) realized by slow wave substrate integrated groove gap waveguide (SW-SIGGW). The SW-SIGGW is composed of two layers of the dielectric substrate, in which periodic mushroom-type electromagnetic band-gap (EBG) unit cells are employed as packaging structures. The gap layer is realized by the upper substrate, and the via-patch mushrooms are designed on the lower substrate. Due to the slow wave structure in the form of periodical metallic via-holes designed on the lower substrate, the guided wavelength is reduced by about 52.8% compared with normal SIGGW. A dual-band resonator and a cascaded second-order BPF are designed based on SW-SIGGW. Compared with the conventional second-order SIGGW BPF, the proposed SW-SIGGW BPF achieves a 62.6% reduction in the area. By adopting vertical stacking technology, the area of the SW-SIGGW BPF is further miniaturized. The final area of the stacked SW-SIGGW BPF is only 18.7% of the conventional filter based on normal SIGGW without slow wave and stacked structure, which is very competitive for the room-limited applications. A prototype of the stacked SW-SIGGW BPF with 5.4% and 7.4% fractional bandwidths at 11.8 and 18 GHz is fabricated and measured. A good agreement between the measured and simulated results verifies the validity of the miniaturized design of SW-SIGGW BPF.

Published

2022

47. Experimental Demonstration of Trans-Skull Volumetric Passive Acoustic Mapping With the Heterogeneous Angular Spectrum Approach

Author

Costas D. Arvanitis, Scott Schoen, and Pradosh Dash

Subjects

Physics, Microbubbles, Acoustics and Ultrasonics, Point source, Aperture, Acoustics, Skull, Brain, Translation (geometry), Article, Angular spectrum method, Wavelength, Sound, Humans, Electrical and Electronic Engineering, Instrumentation, Rotation (mathematics), Energy (signal processing), Interpolation

Abstract

Real-time, three-dimensional (3D), passive acoustic mapping (PAM) of microbubble dynamics during transcranial focused ultrasound (FUS) is essential for optimal treatment outcomes. The angular spectrum approach (ASA) potentially offers a very efficient method to perform PAM, as it can reconstruct specific frequency bands pertinent to microbubble dynamics and may be extended to correct aberrations caused by the skull. Here we assesses experimentally the abilities of heterogeneous ASA (HASA) to perform trans-skull PAM. Our experimental investigations demonstrate that the 3D PAMs of a known 1 MHz source, constructed with HASA through an ex vivo human skull segment, reduced both the localization error (from 4.7±2.3 mm to 2.3±1.6 mm) and the number, size, and energy of spurious lobes caused by aberration, with modest additional computational expense. While further improvements in the localization errors are expected with arrays with denser elements and larger aperture, our analysis revealed that experimental constraints associated with the array pitch and aperture (here 1.8 mm and 2.5 cm, respectively) can be ameliorated by interpolation and peak finding techniques. Beyond the array characteristics, our analysis also indicated that errors in the registration (translation and rotation of ±5 mm and ±5°, respectively) of the skull segment to the array can led to peak localization errors of the order of a few wavelengths. Interestingly, errors in the spatially dependent speed of sound in the skull (±20 %) caused only sub-wavelength errors in the reconstructions, suggesting that registration is the most important determinant of point source localization accuracy. Collectively, our findings show that HASA can address source localization problems through the skull efficiently and accurately under realistic conditions, thereby creating unique opportunities for imaging and controlling the microbubble dynamics in the brain.

Published

2022

48. 275 nm Deep Ultraviolet AlGaN-Based Micro-LED Arrays for Ultraviolet Communication

Author

Yanan Guo, Jianguo Liu, Liang Guo, Tongbo Wei, Jianchang Yan, Jiankun Yang, and Junxi Wang

Subjects

Materials science, ultraviolet communication, Micro-LED arrays, business.industry, size dependence, QC350-467, Optics. Light, medicine.disease_cause, modulation bandwidth, Atomic and Molecular Physics, and Optics, TA1501-1820, Wavelength, Bandwidth (computing), medicine, Optoelectronics, Applied optics. Photonics, Quantum efficiency, Electrical and Electronic Engineering, business, Size dependence, Ultraviolet

Abstract

In this work, we fabricated and characterized 4 × 4 parallel flip-chip AlGaN-based micro-LED arrays with varied mesa diameters of 120 µm, 100 µm, 80 µm, and 60 µm. The reported micro-LED arrays have a maximum bandwidth of 380 MHz and a peak wavelength of ∼275 nm. It is found that the electrical and optical characteristics of AlGaN-based micro-LED arrays show strong size dependence for ultraviolet communication (UVC). The differential resistance increases from 28.8 Ω to 112 Ω, the external quantum efficiency (EQE) is increased by ∼30%, and the bandwidth doubles as the diameter of individual micro-LED decreases from 120 µm to 60 µm. Our research proves that tailoring the mesa size of parallel flip-chip AlGaN-based micro-LED arrays can further enhance its bandwidth and promote its application in UVC.

Published

2022

49. Hybrid Decoupling Structure Based on Neutralization and Partition Schemes for Compact Large-Scale Base Station Arrays

Author

Yiran Da, Xiaoming Chen, Ahmed A. Kishk, and Bo Liu

Subjects

Physics, Coupling, Antenna array, Wavelength, Base station, Acoustics, Vertical direction, Standing wave ratio, Electrical and Electronic Engineering, Antenna (radio), Decoupling (electronics)

Abstract

This letter proposes a hybrid decoupling structure consisting of a neutralization dielectric board, metal baffle, and feeding network to enhance the isolation in a compact large-scale base station array. Both the neutralization- and partition-based schemes are utilized to reduce the mutual coupling between antennas. The neutralization dielectric board provides a new signal path to cancel the original mutual coupling, and the metal baffle is employed to suppress the propagation of the space electromagnetic wave. The antenna elements in the vertical direction are excited by a feeding network. A 44 dual-polarized antenna array with a horizontal edge-to-edge distance of 0.38 free-space wavelength is designed and fabricated to demonstrate the effectiveness of the proposed structure for large-scale arrays for base station application. Simulated and measured results show that the voltage standing wave ratio is less than 1.7, and the isolation between any two ports in the array is better than 20 dB within the entire operating frequency band. Stable radiation patterns with a good front-to-back ratio and cross-polarization ratio are achieved.

Published

2022

50. GaAs-filled elliptical core-based hexagonal PCF with excellent optical properties for nonlinear optical applications

Author

Kawsar Ahmed, Noor Mohammadd, Ruhul Amin, Sobhy M. Ibrahim, Francis M. Bui, and Lway Faisal Abdulrazak

Subjects

Birefringence, Materials science, business.industry, Process Chemistry and Technology, Multiphysics, 02 engineering and technology, 021001 nanoscience & nanotechnology, Cladding (fiber optics), 01 natural sciences, Surfaces, Coatings and Films, Electronic, Optical and Magnetic Materials, Supercontinuum, Numerical aperture, 010309 optics, Core (optical fiber), Wavelength, 0103 physical sciences, Dispersion (optics), Materials Chemistry, Ceramics and Composites, Optoelectronics, 0210 nano-technology, business

Abstract

This manuscript comes up with a unique GaAs-filled elliptical core-based hexagonal cladding PCF that manifests ultra-high birefringence (Br) and non-linear coefficient (NLC). The distinct optical characteristics of the PCF are thoroughly simulated and analyzed by the finite element method (FEM) through the commonly available COMSOL Multiphysics software. The simulated findings confirm that using the high refractive index (RI) advantages of GaAs at the effective wavelength of 1.55 μ m , a high Br of 0.92 , as well as an ultra-high NLC of 2.06 × 10 6 W − 1 K m − 1 and zero-dispersion can be obtained. Besides, several primary optical properties, namely numerical aperture (NA), confinement loss (CL), power fraction (PF), dispersion, etc. are also discussed and investigated in depth in the propounded article. The zero-dispersion characteristic, as well as the high Br and ultra-high NLC of the advanced PCF model, make it a worthy candidate for extensive purposes, including biochemical detection, high nonlinear applications, supercontinuum generation, optical communication and other sensing applications.

Published

2022