Showing total 356 results

1. Enhancement Optical Characterized of Tin Oxide in Polymer Polyvinyl alcohol Colloid Prepared by Laser Ablation Method.

Author

Mohammed, Nadheer Jassim and Rasheed, Zahraa Sabah

Subjects

POLYVINYL alcohol, LASER ablation, ABSORPTION coefficients, REFRACTIVE index, PERMITTIVITY

Abstract

Copyright of Baghdad Science Journal is the property of Republic of Iraq Ministry of Higher Education & Scientific Research (MOHESR) 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

2. In situ acoustic characterization of a perforated panel on a cavity by means of PU measurement and model fitting.

Author

Briere de La Hosseraye, Baltazar, Yang, Jieun, and Hornikx, Maarten

Subjects

ARCHITECTURAL acoustics, ACOUSTIC models, SURFACE impedance, POROUS materials, ABSORPTION coefficients

Abstract

The in situ characterization of materials is a crucial challenge in room acoustics, as laboratories measurement cannot always be applied in consultancy practices. In particular, there is a lack of method to characterize in situ systems with perforated facings, which are commonly encountered systems in room acoustics. In this paper, the in situ characterization of a rigidly-backed porous material behind a rigid perforated facing by means of pressure–velocity measurements is presented. The method includes an inverse impedance model fitting based on measurement in a limited frequency range. The applicability of this method was studied by measuring a variety of perforated facings, whether in front of an air cavity or backed by a porous layer, and comparing the obtained impedance model parameters to reference values. Good agreement was observed between the retrieved parameters and the references, with the errors in all retrieved parameters moving mass, facing thickness, cavity depth, porous layer thickness and porous layer flow resistivity not exceeding 15%. [ABSTRACT FROM AUTHOR]

Published

2024

3. LIGHTWEIGHT MICROWAVE ABSORBERS WITH LOOP-LIKE SURFACE IRREGULARITIES BASED ON FOILED MATERIALS FOR ANECHOIC CHAMBERS.

Author

Boiprav, Olga V. and Bogush, Vadim A.

Subjects

ANECHOIC chambers, RADIATION absorption, ABSORPTION coefficients, MICROWAVE materials, MICROWAVES, ELECTROMAGNETIC wave absorption, ELECTROMAGNETIC radiation

Abstract

Copyright of Momento: Revista de Física is the property of Universidad Nacional de Colombia, Departamento de Fisica 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

4. Acoustic Properties of Surfaces Covered by Multipole Resonators.

Author

Kanev, Nikolay

Subjects

RESONATORS, SURFACE properties, HELMHOLTZ resonators, ACOUSTIC field, REFLECTANCE, ABSORPTION of sound

Abstract

Different types of resonators are used to create acoustic metamaterials and metasurfaces. Recent studies focused on the use of multiple resonators of the dipole, quadrupole, octupole, and even hexadecapole types. This paper considers the theory of an acoustic metasurface, which is a flat surface with a periodic arrangement of multipole resonators. The sound field reflected by the metasurface is determined. If the distance between the resonators is less than half the wavelength of the incident plane wave, the far field can be described by a reflection coefficient that depends on the angle of incidence. This allows us to characterize the acoustic properties of the metasurface by a homogenized boundary condition, which is a high-order tangential impedance boundary condition. The tangential impedance depending on the multipole order of the resonators is introduced. In addition, we analyze the sound absorption properties of these metasurfaces, which are a critical factor in determining their performance. The paper presents a theoretical model for the subwavelength case that accounts for the multipole orders of resonators and their impact on sound absorption. The maximum absorption coefficient for a diffuse sound field, as well as the optimal value for the homogenized impedance, are calculated for arbitrary multipole orders. The examples of the multipole resonators, which can be made from a set of Helmholtz resonators or membrane resonators, are discussed as well. [ABSTRACT FROM AUTHOR]

Published

2024

5. 基于光合有效吸收的水稻穗生物量遥感估测.

Author

张朝冉, 彭漪, 杨凯丽, 袁宁鸽, 黎远金, 刘小娟, and 吴慧丽

Abstract

Copyright of Journal of Henan Agricultural Sciences is the property of Editorial Board of Journal of Henan Agricultural Sciences 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

6. 温度对变压器油太赫兹光谱的影响.

Author

张梦林, 邱方程, 何运华, 李寒煜, 宋玉锋, 胡发平, and 任冠华

Abstract

Copyright of Science Technology & Engineering is the property of Chinese Society of Technology Economics 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

7. Comparison of Effect of Conventional Fuel with Newly Developed Biofuel in Operation and Emission Conditions of Piston Combustion Engine.

Author

Tulík, Juraj, Jablonický, Juraj, Kollárová, Katarína, Tkáč, Zdenko, and Kosiba, Ján

Subjects

DIESEL motor combustion, BIOMASS energy, INTERNAL combustion engines, ABSORPTION coefficients, COMBUSTION

Abstract

The present paper deals with the evaluation of the impact of newly developed biofuels together with a comparison with conventionally produced fuel, diesel, in terms of their impact on the technical and emission condition of a studied vehicle. The main energy and emission parameters of the internal combustion diesel engine were evaluated. For laboratory experiments, a discrete test method was used for comprehensive assessment, the procedure of which is described in the methodology of the paper together with a description of the measurement chain designed to achieve the determined results. The paper deals with the evaluation of the measured results of power, torque, consumption, and emissions such as CO2 and absorption coefficient. Among the technical parameters, the power and torque drop were observed for each biofuel. The decrease is attributed to lower values of calorific value, viscosity, and density. A positive effect was observed for the CO2 and absorption coefficient emission parameters, i.e., a decrease for each of the newly developed biofuels studied. [ABSTRACT FROM AUTHOR]

Published

2024

8. Polymer Nanocomposite Based on Pyrolyzed Polyacrylonitrile Doped with Carbon Nanotubes: Synthesis, Properties, and Mechanism of Formation.

Author

Zaporotskova, Irina, Kakorina, Olesya, Kozhitov, Lev, Muratov, Dmitriy, Boroznina, Natalia, Boroznin, Sergei, and Panchenko, Alexandra

Subjects

CARBON nanotubes, DOPING agents (Chemistry), NANOCOMPOSITE materials, DENSITY functionals, ABSORPTION coefficients, POLYMERS

Abstract

The paper investigates the possibility of fabricating a carbon nanotubes (CNT)-modified nanocomposite based on pyrolyzed polyacrylonitrile (PPAN). The layered structure of PPAN ensures the attachment of nanotubes (NT) to the polymer matrix, forming enhanced PPAN/CNT nanocomposites. We synthesized a PPAN/CNT polymer nanocomposite and investigated its mechanical, conductive, and electronic properties. Using the quantum chemical method density functional theory (DFT), we studied an interaction mechanism between PPAN and single-walled carbon nanotubes. We described the structural features and electron energy structure of the obtained systems. We found that the attachment of a CNT to the PPAN matrix increases tensile strength, electrical conductivity, and thermal stability in the complex. The obtained materials were exposed to electromagnetic radiation and the dielectric constant, reflection, transmission, and absorption coefficients were measured. The study demonstrates the possibility of using carbon nanotubes for reinforcing polyacrylonitrile polymer matrix, which can result in the development of an enhanced class of materials possessing the properties of both polymers and CNTs. [ABSTRACT FROM AUTHOR]

Published

2024

9. Sound absorption advancements: exploring 3D printing in the development of tetrakaidecahedron cell-based acoustic metamaterials.

Author

Shah, Saliq Shamim, Singh, Daljeet, Saini, Jaswinder Singh, and Garg, Naveen

Abstract

Purpose: This paper aims to study the design and characterization of a 3D printed tetrakaidecahedron cell-based acoustic metamaterial. At present, the mitigation of low-frequency noise involves the utilization of spatially demanding materials for the absorption of sound. These materials lack the ability for targeted frequency control adjustments. Hence, there is a requirement for an approach that can effectively manage low-frequency noise using lightweight and durable materials. Design/methodology/approach: The CAD model was created in SolidWorks and was manufactured using the Digital Light Processing (DLP) 3D printing technique. Experimental study and numerical simulations examined the metamaterial's acoustic absorption. An impedance tube with two microphones was used to determine the absorption coefficient of the metamaterial. The simulations were run in a thermoviscous module. Findings: The testing of acoustic samples highlighted the effects of geometric parameters on acoustic performance. Increment of the strut length by 0.4 mm led to a shift in response to a lower frequency by 500 Hz. Peak absorption rose from 0.461 to 0.690 as the strut diameter was increased from 0.6 to 1.0 mm. Increasing the number of cells from 8 to 20 increased the absorption coefficient and lowered the response frequency. Originality/value: DLP 3D printing technique was used to successfully manufacture tetrakaidecahedron-based acoustic metamaterial samples. A novel study on the effects of geometric parameters of tetrakaidecahedron cell-based acoustic metamaterial on the acoustic absorption coefficient was conducted, which seemed to be missing in the literature. [ABSTRACT FROM AUTHOR]

Published

2024

10. Optical parameters of healthy and tumor breast tissues in mice.

Author

Genina, Elina A., Lazareva, Ekaterina N., Surkov, Yuri I., Serebryakova, Isabella A., and Shushunova, Natalya A.

Abstract

Knowledge of the optical parameters of tumors is important for choosing the correct laser treatment parameters. In this paper, optical properties and refraction indices of breast tissue in healthy mice and a 4T1 model mimicking human breast cancer have been measured. A significant decrease in both the scattering and refractive index of tumor tissue has been observed. The change in tissue morphology has induced the change in the slope of the scattering spectrum. Thus, the light penetration depth into tumor has increased by almost 1.5–2 times in the near infrared "optical windows." Raman spectra have shown lower lipid content and higher protein content in tumor. The difference in the optical parameters of the tissues under study makes it possible to reliably differentiate them. The results may be useful for modeling the distribution of laser radiation in healthy tissues and cancers for deriving optimal irradiation conditions in photodynamic therapy. [ABSTRACT FROM AUTHOR]

Published

2024

11. Dragonfly algorithm–support vector machine approach for prediction the optical properties of blood.

Author

Omari, Faiza, Khaouane, Latifa, Laidi, Maamar, Ibrir, Abdellah, Roubehie Fissa, Mohamed, Hentabli, Mohamed, and Hanini, Salah

Subjects

OPTICAL properties, STANDARD deviations, DRAGONFLIES, ABSORPTION coefficients, SUPPORT vector machines

Abstract

Knowledge of the optical properties of blood plays important role in medical diagnostics and therapeutic applications in laser medicine. In this paper, we present a very rapid and accurate artificial intelligent approach using Dragonfly Algorithm/Support Vector Machine models to estimate the optical properties of blood, specifically the absorption coefficient, and the scattering coefficient using key parameters such as wavelength (nm), hematocrit percentage (%), and saturation of oxygen (%), in building very highly accurate Dragonfly Algorithm-Support Vector Regression models (DA-SVR). 1000 training and testing sets were selected in the wavelength range of 250-1200 nm and the hematocrit of 0-100%. The performance of the proposed method is characterized by high accuracy indicated in the correlation coefficients (R) of 0.9994 and 0.9957 for absorption and scattering coefficients, respectively. In addition, the root mean squared error values (RMSE) of 0.972 and 2.9193, as well as low mean absolute error values (MAE) of 0.2173 and 0.2423, this result showed a strong match with the experimental data. The models can be used to accurately predict the absorption and scattering coefficients of blood, and provide a reliable reference for future studies on the optical properties of human blood. [ABSTRACT FROM AUTHOR]

Published

2024

12. Investigation of sound absorption on a polymeric acoustic metamaterial using 3D printing process.

Author

Shah, Saliq Shamim, Singh, Daljeet, Saini, J. S., Garg, Naveen, and Gautam, Chitra

Subjects

THREE-dimensional printing, METAMATERIALS, ABSORPTION coefficients, ABSORPTION of sound, PRINTMAKING, NOISE control

Abstract

This paper presents the design and characterization of DENORMS (Designs for Noise‐Reducing Materials and Structures) cell‐based acoustic metamaterial developed using a 3D printing technique. The metamaterial's acoustic absorption properties were investigated through experimental testing and numerical simulations. The experimental testing of the acoustic metamaterial was conducted in an impedance tube using a two‐microphone method. The numerical simulations were carried out using a thermoviscous module. The simulations allowed for a deeper understanding of the influence of geometric parameters on the absorption coefficient, providing valuable insights for optimizing the design. It was observed that upon increasing the spherical diameter while maintaining the same cylindrical diameter and cylindrical length resulted in an increase in the absorption coefficient throughout the frequency range. It was also observed that upon increasing the cylindrical diameter, there was a significant decrement of absorption coefficient, and upon increasing the length of the cylinder, there was a shift of response toward lower frequency. The augmentation in cell count from 9 to 24 led to a rise in the absorption coefficient and a shift of the response toward lower frequencies. The findings highlight the significance of photopolymer 3D printing in tailoring complex geometries for enhanced performance of the acoustic metamaterial. Highlights: Photopolymeric resin used for DENORMS cell‐based acoustic metamaterial.High cleanability and accuracy of digital light processing 3D printing technique.Usage of thermoviscous model for simulation of sound absorption behavior.Use of two microphone impedance tube to determine sound absorption coefficient.Geometric parameters significantly affect the absorption coefficient. [ABSTRACT FROM AUTHOR]

Published

2024

13. Electronic structure, theoretical power conversion efficiency, and thermoelectric properties of bismuth-based alkaline earth antiperovskites.

Author

Rani, Upasana, Kamlesh, Peeyush Kumar, Joshi, Tarun Kumar, Singh, Rashmi, Al-Qaisi, Samah, Gupta, Rajeev, Kumar, Tanuj, and Verma, Ajay Singh

Subjects

THERMOELECTRIC materials, ELECTRONIC structure, BISMUTH, TECHNOLOGICAL innovations, ENERGY storage, THERMOELECTRIC apparatus & appliances, INFRARED absorption

Abstract

Context: This research paper investigates the properties and potential applications of antiperovskite materials. Antiperovskites are a class of materials with a unique crystal structure, where the central atom is surrounded by a cage of anions. We review recent research on antiperovskite-based materials for energy storage, photovoltaics, catalysis, and sensors. We discovered that these materials display direct band gap semiconductors, strong absorption in the visible (VIS), ultra-violet (UV), and near infrared regions (NIR) based on their fundamental features, which is the most admirable quality that may be found in many optoelectronic devices. Both mechanical and thermodynamic stability have been confirmed for these materials. We discovered that these materials exhibit high figures of merit through the calculation of transport properties, which makes them a promising candidate for thermoelectric devices. It is anticipated that the proposed material BiPMg3, which has a theoretical efficiency of 11.5%, will make a suitable photovoltaic absorber. This paper highlights the potential of these materials for future technological advancements. Methods: Herein, we have used most authentic techniques to compute fundamental physical properties of these antiperovskites. Full-potential linear augmented plane wave (FP-LAPW) method has been used to investigate electronic, magnetic, optical properties, and make antiperovskites attractive for a variety of applications. In light of its implementation, we have checked the theoretical power conversion efficiency by first principles spectroscopic screening methodology, and inspect the fundamental physical parameters of antiperovskites, focusing on their potential as functional materials for energy and information technologies. [ABSTRACT FROM AUTHOR]

Published

2023

14. Measuring the Optical Properties of Highly Diffuse Materials.

Author

Nguyen, Mathieu, Thomas, Jean-Baptiste, and Farup, Ivar

Subjects

OPTICAL properties, OPTICAL materials, ABSORPTION coefficients, REFLECTANCE measurement, MILKFAT

Abstract

Measuring the optical properties of highly diffuse materials is a challenge as it could be related to the white colour or an oversaturation of pixels in the acquisition system. We used a spatially resolved method and adapted a nonlinear trust-region algorithm to the fit Farrell diffusion theory model. We established an inversion method to estimate two optical properties of a material through a single reflectance measurement: the absorption and the reduced scattering coefficient. We demonstrate the validity of our method by comparing results obtained on milk samples, with a good fitting and a retrieval of linear correlations with the fat content, given by R 2 scores over 0.94 with low p-values. The values of absorption coefficients retrieved vary between 1 × 10 − 3 and 8 × 10 − 3 mm − 1 , whilst the values of the scattering coefficients obtained from our method are between 3 and 8 mm − 1 depending on the percentage of fat in the milk sample, and under the assumption of the anisotropy factor g > 0.8 . We also measured and analyzed the results on white paint and paper, although the paper results were difficult to relate to indicators. Thus, the method designed works for highly diffuse isotropic materials. [ABSTRACT FROM AUTHOR]

Published

2023

15. Optical and electronic properties of defect chalcopyrite ZnGa2S4.

Author

Asadullayeva, S. G., Ismayilova, N. A., Musayev, M. A., and Abbasov, I. I.

Subjects

OPTICAL properties, CRYSTAL optics, DENSITY functionals, CHALCOPYRITE, DENSITY functional theory

Abstract

In this paper, we have performed a study on the optical properties of single crystals ZnGa2S4 by method of density functional theory (DFT) and ellipsometry measurements. The calculated results for the real ε r and imaginary ε i parts of the dielectric function are compared with the measured experimental spectroscopic ellipsometry (SE) spectra in the 0.7–6.5 eV spectral region. Absorption coefficient-photon energy dependency revealed the existence of direct bandgap transitions with energy 3.5 eV. This result is very close to bandgap obtained from our theoretical calculation. [ABSTRACT FROM AUTHOR]

Published

2024

16. Experimental concept study of a small engine silencer unit based on microperforated elements.

Author

Villau, Margus, Rämmal, Hans, and Lavrentjev, Jüri

Subjects

NOISE pollution, INTERNAL combustion engines, LEAF blowers, NOISE control, THREE-dimensional printing, RAPID prototyping, LAWN mowers, FANS (Machinery)

Abstract

Copyright of Proceedings of the Estonian Academy of Sciences is the property of Teaduste Akadeemia Kirjastus 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

17. Numerical modelling of electronic and optical properties for different sizes of CdSe/ZnS quantum dots under temperature and hydrostatic pressure effects.

Author

Brahim, T., Bouazra, A., and Said, M.

Subjects

HYDROSTATIC pressure, OPTICAL properties, QUANTUM dots, FINITE difference method, OSCILLATOR strengths, ABSORPTION coefficients

Abstract

In this paper, we theoretically investigate the electronic and optical properties of CdSe/ZnS quantum dots (QDs) of varying sizes. We calculate the energy eigenvalues and wave functions dependence on QD dimensions, temperature, and pressure using a combination of coordinate transformation and the finite difference method. We analyze the oscillator strength, transition lifetime, absorption coefficients (AC), and refractive index changes (RIC) for various values of dot sizes, temperature, hydrostatic pressure, and incident photon intensity. The results obtained indicate a strong dependence of electronic and optical properties on temperature, hydrostatic pressure, and the size of the nanostructure. The oscillator strength decreased with increasing hydrostatic pressure, but increased with rising temperature. Conversely, the transition lifetime exhibits an opposite trend. Furthermore, the total AC and RIC increase as incident optical intensity decreases. Linear, nonlinear, and total AC and RIC display a red shift with increasing hydrostatic pressure and a blue shift with rising temperature. [ABSTRACT FROM AUTHOR]

Published

2024

18. Atomic force microscopy and ellipsometry investigations of rare earth oxide Dy2O3 nano-layer processed by electron beam evaporation on n-GaAs substrate.

Author

Ouerghui, W., Saghrouni, H., and Beji, L.

Subjects

ATOMIC force microscopy, GALLIUM arsenide, ELECTRON beams, OPTICAL constants, ELLIPSOMETRY, OPTICAL conductivity, RARE earth oxides

Abstract

In this paper, we show and analyse the results of morphological characterisations of Dy2O3 layer deposited on an n-type GaAs substrate using atomic force microscopy (AFM). For structural measurement, the surface morphology of the elaborated layer was revealed as a nano-conical event. The global experimental ellipsometric results Ψ and Δ versus emission wavelength of the Dy2O3/n-GaAs structure have been presented and discussed. Using these results and a Matlab code in which we assumed the structure had three layers, we have calculated several linear and nonlinear optical constants of the Dy2O3 thin layer. Dysprosium oxide has high optical conductivity and a noticeable increase in nonlinear optical parameters, making it a promising candidate for various applications. This is especially true in the field of optoelectronics. [ABSTRACT FROM AUTHOR]

Published

2024

19. Investigation of electrochemical, structural, electronic, thermodynamic, and optical properties of LiTi2O4 cathode material for Li-ion battery: an Ab Initio calculations.

Author

Erraji, A., Masrour, R., and Xu, L.

Abstract

In this research, we have conducted an in-depth investigation into the structural, electronic characteristics, and thermodynamic properties of the LiTi2O4 compound using first-principles calculations grounded in density functional theory with the generalized gradient approximation. Our findings reveal that the LiTi2O4 compound possesses a calculated lattice constant of 8.407 Å. Furthermore, we have derived critical battery-related properties, including an average voltage of 1.53 V versus Li/Li+ and an energy density of 245 Wh/kg. To deepen our understanding of LiTi2O4, we have explored its thermodynamic properties employing the quasi-harmonic Debye model. These properties encompass the Debye temperature, volume variation, compressibility modulus, specific capacity, and thermal capacity. Importantly, we have observed that the Debye stiffness of LiTi2O4 increases with rising pressure. Moreover, we have conducted measurements to assess various optical properties of the LiTi2O4 compound. These properties include the absorption coefficient, photoconductivity, and reflectivity. [ABSTRACT FROM AUTHOR]

Published

2024

20. Assessing acoustic performance of building material: A finite element model for 3D printed multilayer micro-perforated panels with compressed earth blocks.

Author

Bainamndi, Joseph Daliwa, Siryabe, Emmanuel, Ntamack, Guy-Edgar, Yamigno, Serge Doka, and Maréchal, Pierre

Subjects

FINITE element method, ABSORPTION coefficients, SOUNDPROOFING, NOISE control, BUILDING performance

Abstract

This study deals with 3D printing multilayered micro-perforated panels (M-MPPs) coupled with buildings materials as compressed earth block for noise reduction applications. The sound absorption coefficient α is utilized as a metric to assess the sound insulation capabilities across a frequency range spanning from 10 to 3000 Hz, then evaluated and validated by numerical and experimental methods. The FEM model developed makes it possible to predict the acoustic absorption of M-MPPs by tuning the frequency range and varying optimized acoustics parameters, considering hole-hole interaction and taking into account visco-thermal effects that are present in compressed earth blocks. It is shown that the shape of perforations and material properties including the porosity rate, arrangement in the design of multilayer micro-perforated structures are identified to play a significant role in the sound performance of the entire structure. In addition, the application of MPP coupled with compressed earth blocks improve the sound absorption capacity of the composite structure. The developed FEM leads to accurate prediction of performance, efficient optimization, and cost effectiveness. Finally, the present study reveals the importance of M-MPPs combined with compressed earth blocks (CEBs) as viable noise reduction materials, particularly relevant for engineering applications and development initiatives in emerging economies. [ABSTRACT FROM AUTHOR]

Published

2024

21. МАТЕМАТИЧНА МОДЕЛЬ НАДВИСОКОЧАСТОТНОГО ВИМІРЮВАЧА ВОЛОГОСТІ ЗЕРНА.

Author

Білинський, Й. Й. and Скалецька, М. О.

Abstract

The article considers methods for measuring grain moisture. The authors carried out the analysis and selected significant parameters that affect the measurement of grain moisture. Methods and ways of grain moisture control are investigated. Modern technological methods of production of agricultural products are largely related to moisture content. The excess or lack of moisture in the material affects its physico-chemical, physico-mechanical and operational properties, as well as quality indicators. Quick and accurate determination of water content in a particular material, both in the production process and during operation, is the most important task. The accuracy and measurement errors of moisture content of moisture meters significantly depend on the density of materials and the parameters of the measurement medium. The optimal method for the most accurate measurement of humidity has been determined. Growing requirements for the quality and competitiveness of domestic agricultural products put forward new requests for the devices and facilities for express moisture control in most technological processes. Modern technological processes require universal devices that control the moisture content of a wide range of agricultural materials. Having analyzed in detail and determined the significant parameters that affect the measurement of grain moisture, the paper proposes mathematical model of ultra-high-frequency measuring transformation of the moisture of grain crops, the essence of which is to measure the power of this signal at the output of the waveguide when the grain moisture changes by using a traveling wave. By means of the analysis, carried out, the authors suggested the structural diagram of ultra-high-frequency humidity meter of cereal crops which realizes the mathematical model, proposed in the paper. [ABSTRACT FROM AUTHOR]

Published

2023

22. OPTICAL ABSORPTION OF COMPOSITES WITH METALLIC NANOSIZED SPHEROIDAL PARTICLES.

Author

Pavlyshche, N. I., Korotun, A. V., and Kurbatsky, V. P.

Subjects

NANOPARTICLES, LIGHT absorption, ABSORPTION coefficients, DIELECTRIC function, VISIBLE spectra, SURFACE plasmon resonance

Abstract

The paper considers the problem of light absorption by a nanocomposite with randomly oriented metal spheroidal particles-inclusions, provided that the volume content of such inclusions is small. Expressions for the frequency dependences of the effective dielectric function and the absorption coefficient of the metal-dielectric nanocomposite are obtained within the effective medium model taking into account the axial symmetry of spheroidal inclusions. The effective relaxation rate of electrons is introduced using the kinetic approach. Numerical calculations are performed for the cases when inclusion particles have the form of prolate and oblate nanospheroids. The results of the calculations indicate the presence of two maxima of the absorption coefficient, which correspond to longitudinal and transverse surface plasmon resonance. The change in the position and magnitude of the maxima of the frequency dependences of the effective dielectric function and the absorption coefficient with varying the size and shape of the spheroidal particles-inclusions is analyzed. It is shown that the greater the difference in the lengths of the semi-axes of the spheroids, the greater the distance between the maxima of the effective dielectric function and the absorption coefficient, and the shape of the curves depends on the eccentricity of spheroidal inclusions. It has been found that the position of the maxima is significantly influenced by the choice of the material of the inclusion particles and the matrix medium, while the height of the maxima is largely influenced by the shape of the nanoparticles, as well as their volume content in the composite medium. It is proved that, dependent on the material of nanoparticles-inclusions, both maxima of the absorption coefficient can be found in the visible part of the spectrum (for Au inclusions) or in the ultraviolet (for Al inclusions). It is also possible that one maximum lies in the visible part of the spectrum, and the other in the ultraviolet, which is the case for inclusions of Pd, Pt, Cu, Ag. [ABSTRACT FROM AUTHOR]

Published

2023

23. Optical properties of two-dimensional quantum ring with diluted magnetic semiconductors structure.

Author

Babanli, Arif and Sabyrov, Vepa

Subjects

QUANTUM rings, DILUTED magnetic semiconductors, MAGNETIC structure, OPTICAL properties, ABSORPTION coefficients

Abstract

In this paper, we study the optical properties of a two-dimensional quantum ring with a diluted magnetic semiconductors structure. The Volcano model was chosen as the confinement potential of a quantum system. For interband optical transitions, the behavior of the absorption coefficient of a quantum ring as a function of the incident photon energy is numerically studied as a function of various values of such parameters as temperature, magnetic field, ring radius, and inner ring radius. In addition, the change in the threshold frequency as a function of the magnetic field and temperature for an interband optical transition is numerically studied. According to the results obtained, the considered parameters change the optical properties of the quantum ring. [ABSTRACT FROM AUTHOR]

Published

2023

24. Infrared spectra of the main optical properties of poly(methyl methacrylate) thin films.

Author

Strugariu, Maria Laura, Șerban, Sorina Gabriela, Berdie, Antonia Maria, and Jitian, Simion

Subjects

OPTICAL properties, OPTICAL spectra, INFRARED spectra, OPTICAL constants, THIN films, POLYMERS

Abstract

This study aimed to determine the infrared (IR) spectra of the main optical properties of poly(methyl methacrylate) (PMMA). This is a simple and original method for obtaining spectra of the main optical properties from the reflection–absorption spectrum. Infrared reflection spectra of the main optical properties of PMMA were obtained from the complex relative permittivity using the Drude–Lorentz model for permittivity. Classical dispersion analysis of the reflection–absorption spectrum of poly(methyl methacrylate) films cast on a metal mirror was performed. The method is based on an iterative least squares fitting process of the experimental reflection–absorption spectrum of the polymer with the corresponding theoretical spectrum obtained from the complex permittivity Drude–Lorentz model. This approach is original for obtaining the relative permittivity and subsequently obtaining the main optical properties of the polymer film: complex electric modulus, energy loss function, optical constants, absorption coefficient, penetration depth, dissipation factor, and complex optical conductivity. In addition to the findings of other articles, some optical properties of PMMA films have been presented, which may be useful for studying PMMA-based composites or copolymers. Please confirm if the author names are presented accurately and in the correct sequence Author 1 Given name: [Maria Laura ] Last name [Strugariu]. Author 2 Given name: Sorina Gabriela Last name [Șerban] Author 3 Given name: [Antonia Maria ]Last name :[Berdie] Also, kindly confirm the details in the metadata are correct.Yes [ABSTRACT FROM AUTHOR]

Published

2024

25. Quantum Theory of the Effect of IncreasingWeak ElectromagneticWave by a Strong Laser Radiation in 2D Graphene.

Author

Tran Anh Tuan, Nguyen Dinh Nam, Nguyen Thi Thanh Nhan, and Nguyen Quang Bau

Subjects

LASER beams, QUANTUM theory, GRAPHENE, ELECTROMAGNETIC radiation, PHONON scattering, ABSORPTION coefficients

Abstract

Analytic expressions for the absorption coefficient (AC) of a weak electromagnetic wave (EMW) in 2D Graphene under influence of strong laser radiation are calculated using the quantum kinetic equation (QKE) in the case of electron-optical phonon scattering in both the absence and presence of a magnetic field perpendicular to the graphene sheet. The dependence of the AC on the intensity E02 and the frequency Ω2 of a weak EMW, on the intensity E01 and the frequency Ω1 of a strong laser radiation, on the temperature T of the system is obtained. These results are investigated from low temperature to high temperature. These results are obtained from the QKE method, which broke the limit of the Boltzmann kinetic equations (only investigated in the high-temperature domain). Besides, the numerical results show that the AC of a weak EMW in 2D Graphene can have negative values. This demonstrates the possibility of increasing weak EMW by strong laser radiation in 2D Graphene. This is different from a similar problem in bulk semiconductors and the case without strong laser radiation. In the case of the presence of an external magnetic field, the numerical calculation results also show the appearance of the peak spectral lines that obey the magneto-phonon resonance conditions. The appearance of these resonance peaks provides a model illustrating the dependence of the Half-Width at Half Maximum (HWHM) on the external magnetic field. This is an important criterion for the fabrication of graphene-related electronic components and orientation for future experiments. [ABSTRACT FROM AUTHOR]

Published

2024

26. Structural and Optical Characterization of Porous NiV 2 O 6 Films Synthesized by Nebulizer Spray Pyrolysis for Photodetector Applications.

Author

Kotbi, Ahmed, El Radaf, Islam M., Alaoui, Ilham Hamdi, Cantaluppi, Anna, Zeinert, Andreas, and Lahmar, Abdelilah

Subjects

ENERGY absorption films, OPTICAL films, THIN films, BAND gaps, SURFACE roughness

Abstract

NiV2O6 thin films were grown on glass slides with varying thicknesses using nebulizer spray pyrolysis. The impact of thickness on the thin films' optical, structural, morphological, and electrical characteristics was systematically investigated. X-ray diffraction and micro-Raman analysis confirmed the formation of the triclinic NiV2O6 system. Surface morphology and roughness variations in the as-deposited NiV2O6 films were studied using scanning electron microscopy (SEM) and a profilometer. Optical properties, including optical band gap (Eg), extinction coefficient (k), absorption coefficient (α), and refractive index (n), were determined through optical reflectance and transmittance measurements. The optical energy gap of the as-deposited NiV2O6 films decreased from 2.02 eV to 1.58 eV with increased layer thickness. Furthermore, the photo-detectivity of the films demonstrated an enhancement corresponding to the prolonged spray time. The sensitivity values obtained for visible irradiation were 328, 511, and 433 for samples S1, S2, and S3, respectively. The obtained results can be imputed to the specific porous microstructure. [ABSTRACT FROM AUTHOR]

Published

2024

27. Black Carbon Concentration in the District of Ar-Ramtha, Northern Jordan, and its Sources at Seven Wavelengths.

Author

Mallak, Abdallah M., Hamasha, Khadeejeh M., and Abdallah, Manal J.

Subjects

SOOT, WAVELENGTH measurement, INTERFEROMETRY, ABSORPTION coefficients, OPTICAL constants

Abstract

Variations of black carbon concentration and its sources identification were studied in Ar-Ramtha District, north of Jordan, using the aetlalometer model AE33. Measurements at six sites showed that the black carbon concentrations almost have the same behavior due to the uniform nature of the region. The average value of the black carbon concentration in the six sites was 1778 ng/m³, 2288 ng/m³, 1605 ng/m³, 1785 ng/m³, 2267 ng/m³, and 2606 ng/m³ respectively. Analysis of the measurements and Angstrom exponents, pre-calibrated in the instrument, revealed the ability of these variations to apportion black carbon from its sources. The largest contribution of black carbon was from fossil fuels at all sites. The absorption coefficients for each wavelength were measured at all sites. For a wavelength of 370 nm, it was discovered that the absorption coefficient had a maximum value of 58. 27Mm-1 while it it was 20.25 Mm-1 at 880 nm. In all sites, the average absorption coefficients reached their highest value at a wavelength of 370 nm, demonstrating the inverse relationship between wavelength and absorption coefficient. [ABSTRACT FROM AUTHOR]

Published

2024

28. Influence of Decarbonization on Selected Parameters of ICE.

Author

Jablonický, Juraj, Tulík, Juraj, Bártová, Simona, Tkáč, Zdenko, Kosiba, Ján, Kuchar, Peter, Čorňák, Štefan, Kollárová, Katarína, Kaszkowiak, Jerzy, Tomić, Milan, and Paumer, Martin

Subjects

CARBON dioxide mitigation, ENERGY consumption, ABSORPTION coefficients, AREA measurement, INTERNAL combustion engines, TEST methods

Abstract

The paper focuses on the area of experimental measurements for monitoring the impact of decarbonization on the technical and environmental parameters of the ICE. The condition for the implementation of the measurements was the selection of an ICE that had driven more than 300,790 km. During the laboratory tests, several test methods were used to assess the technical and emission conditions of the tested ICE with the code designation ALH, which is used in VOLKSWAGEN BORA vehicles. The technical parameters of the tested ICE (corrected power PNorm and torque MMom), emission parameters (absorption coefficient k and NOx emission) and fuel consumption parameters (specific fuel consumption bsfc) were compared and evaluated in the results. The results show that the decarbonization process on the tested vehicle VOLKSVWAGEN BORA 1.9 TDi affected the emission parameters but did not affect the technical parameters and specific fuel consumption. [ABSTRACT FROM AUTHOR]

Published

2023

29. Optical absorption in concentric double quantum rings.

Author

Khajeh Salehani, Hojjatollah

Subjects

QUANTUM rings, LIGHT absorption, ABSORPTION coefficients, EXCITED states, OPTICAL properties

Abstract

In this paper, the optical properties of two-dimensional coupled concentric double quantum rings with a parabolic confinement potential are studied theoretically. The optical absorption coefficient for the transition from the ground state to the first excited state is calculated. The effects of inter-ring coupling, internal or external ring width variation, and on-center donor and acceptor impurities are investigated. The peak value of the absorption coefficient decreases when the width of the internal ring is decreased, but reducing the width of the external ring causes the absorption coefficient to first increase and then decrease. In addition, concentric double quantum rings with a wider internal (external) ring absorb the photons with higher (lower) energies. An increment of the inter-ring coupling causes the concentric double quantum rings to absorb photons with higher energies. Although the on-center impurity reduces the magnitude of the absorption coefficient, the decrement is considerable for the donor impurity rather than the acceptor impurity. It is shown that the peak value position of the absorption coefficient has an obvious blue-shift (red-shift) in the presence of donor (acceptor) impurity. [ABSTRACT FROM AUTHOR]

Published

2023

30. Temperature-Dependent Optical Properties of Bismuth Triborate Crystal in the Terahertz Range: Simulation of Terahertz Generation by Collinear Three-Wave Mixing in the Main Crystal Planes.

Author

Ezhov, Dmitry, Nikolaev, Nazar, Antsygin, Valery, Bychkova, Sofia, Andreev, Yury, and Svetlichnyi, Valery

Subjects

NONLINEAR optical techniques, OPTICAL properties, TERAHERTZ time-domain spectroscopy, BISMUTH, CRYSTALS, SUPERCONTINUUM generation

Abstract

Terahertz (THz) frequency generation via nonlinear optical techniques is of particular interest due to the immense potential of this type of radiation in various scientific fields, ranging from medicine to telecommunications. Selecting suitable nonlinear media for laser frequency down-conversion presents a challenging task. Considering an approach that uses nonlinear crystals with high radiation resistance, pumped by intense laser pulses near their damage threshold, we suggest the crystal of bismuth triborate (BiB3O6, BIBO). Compared to other borate-class crystals, BIBO exhibits relatively high coefficients of quadratic susceptibility. In this paper, we have studied the optical properties of BIBO samples in a wide spectral range from 0.1 to 2.1 THz at temperatures of 473, 383, 295, and 77 K using Terahertz Time-Domain Spectroscopy (THz-TDS). Furthermore, we simulated collinear three-wave interactions with nonzero efficiency for difference frequency generation (DFG) in the THz range. For the pump wavelengths of about 800 nm, we determined phase-matching (PM) conditions and compared the generation efficiency for different crystal cuts. The potential of utilizing BIBO crystal for terahertz frequency generation is discussed. [ABSTRACT FROM AUTHOR]

Published

2023

31. Optical properties of (GaAs/InAs)–GaAsySb1−y digital alloy superlattices in the short-wavelength infrared region calculated by an sp3d5s* tight-binding method.

Author

Kato, Takashi and Souma, Satofumi

Subjects

SUPERLATTICES, INDIUM gallium arsenide, AUDITING standards, OPTICAL properties, GALLIUM arsenide, ALLOYS, INFRARED detectors, GALLIUM alloys

Abstract

GaxIn1−xAs–GaAsySb1−y type-II superlattices (T2SLs) have recently received broad attention as an InP-based optical absorption layer in short-wavelength infrared detectors. However, the cut-off wavelength of a GaInAs–GaAsSb T2SL detector is ordinarily around 2.4 µm at room temperature. This paper proposes extending the cut-off wavelength using a GaAs/InAs digital alloy instead of a GaxIn1-xAs random alloy layer in a GaxIn1−xAs–GaAsySb1−y T2SL. The calculation result employing an empirical sp3d5s* tight-binding method has revealed that a (GaAs/InAs)–GaAsySb1−y digital alloy T2SL on an InP substrate possesses a band gap corresponding to a wavelength of 2.9 µm which is over 0.4 µm longer than that in a conventional GaInAs–GaAsSb T2SL at a temperature of 200 K. Figured optical absorption coefficient spectra of certain digital alloy T2SLs, e.g., a [(GaAs)4(InAs)4]2–(GaAs0.53Sb0.47)17 structure, present a considerable polarization-direction dependence—originating from the asymmetrical shape of the wavefunction in the quantum well. Yet, by altering the atomic layer configuration in the growth direction of the digital alloy T2SL to have such a quantum well structure with a reflection symmetry as in [(GaAs)4(InAs)4]2(GaAs)3–(GaAs0.45Sb0.55)17, the polarization dependency can be dramatically decreased due to the symmetry improvement of the wavefunction. [ABSTRACT FROM AUTHOR]

Published

2023

32. Ab Initio Study of Optical Properties of Hybrid Films Based on Bilayer Graphene and Single-Walled Carbon Nanotubes.

Author

Slepchenkov, Michael M., Barkov, Pavel V., Kolosov, Dmitry A., and Glukhova, Olga E.

Subjects

OPTICAL properties, CARBON nanotubes, GRAPHENE, SOLAR spectra, NEAR infrared radiation, NANOTUBES, SURFACE of the earth, OPTICAL conductivity, OPTOELECTRONICS

Abstract

In recent years, the possibility of combining graphene and carbon nanotubes has attracted much attention from researchers attempting to obtain new multifunctional hybrid materials with promising properties. Optoelectronics shows potential as a field of application for such hybrid structures. The variety of existing structural configurations of graphene-nanotube hybrids requires preliminary detailed studies of their optical properties by computer simulation methods. In this paper, we consider island-type graphene-nanotube hybrid films formed by AB-stacked bilayer graphene and single-walled carbon nanotubes (SWCNTs). In this case, bilayer graphene is located above the surface of the nanotube, forming areas with an increased density of carbon atoms, creating so-called "islands." To meet the conditions of a real experiment, we chose chiral SWCNTs (12,6) with a diameter of 1.2 nm, which are most often synthesized in real experiments. All constructed atomistic models of bilayer graphene-chiral SWCNT films were tested for thermodynamic stability at room temperature and proved their suitability for research. Using Kubo-Greenwood formalism, we calculated the complex optical conductivity tensor and absorbance coefficient in the wavelengths of ultraviolet, visible, and near-infrared radiations. The photocurrent spectra are calculated based on the obtained absorption spectra and solar radiation spectra on the earth's surface (AM1.5) and outside the earth's atmosphere (AM0). The results of calculations revealed regularities in the influence of structural parameters (nanotube diameter, graphene width) on the optical and optoelectronic properties of graphene-chiral SWCNT (12,6) with an island structure. [ABSTRACT FROM AUTHOR]

Published

2023

33. Theoretical and Numerical Investigations of the Energy States and Absorption Coefficients of Quantum Dots and Quantum Anti-Dots in the Presence of a Magnetic Field.

Author

Rahimi, Fatemeh and Ghaffary, Tooraj

Abstract

Present study focuses on analyzing the role of magnetic field on electronic spectra and absorption coefficients for the transitions 1 s → 2 p of G a A s / Ga 1 - x Al x A s / G a A s spherical multilayer quantum dot (MLQD) and Ga 1 - x Al x A s / G a A s / Ga 1 - x Al x A s spherical multilayer quantum anti-dot (MLQAD) with hydrogenic impurity, via a comparative view. These nano structure systems have been studied both theoretically (Perturbation Theory), and numerically (Finite Difference Method). The wave functions and energy eigenvalues have been calculated using the finite difference method. In this paper it will be shown that a new degeneracy in presence of the uniform magnetic field in the MLQAD model will be appeared. Furthermore, the effects of the magnetic field, core radius size and potential confinement on 1 s → 2 p 0 absorption coefficient and also on 1 s and 2 p energy states of these nano spherical structures have been discussed. [ABSTRACT FROM AUTHOR]

Published

2023

34. Laser Delivery and Spectral Study of a Modern Chlorine-Containing Drug for the Treatment of Onychomycosis at Laser Radiation with a Wavelength of 450 nm.

Author

Belikov, A. V., Fyodorova, Y. V., Kozlova, A. D., and Smirnov, S. N.

Subjects

LASER beams, ONYCHOMYCOSIS, LASERS, WAVELENGTHS, PHOTODYNAMIC therapy, LASER pulses

Abstract

The possibility of active laser delivery of a modern chlorine-containing photosensitizing drug Chloderm (Chloderm, Russia) under the nail plate by laser radiation with a wavelength of 450 nm for the purpose of photodynamic therapy of onychomycosis is studied. In an in vitro experiment, sequential laser microporation of the nail plate and active delivery of the drug under the nail plate by this laser radiation with an intensity of up to 200 W/cm2 were investigated. The results of studying the absorption spectra of an aqueous solution of Chloderm in the range of 400–900 nm before and after exposure to 450 nm laser radiation are presented. It is demonstrated that sequential laser microporation and active laser drug delivery under the nail plate is possible at laser radiation intensity greater than 178 W/cm2. It is shown that the maximum rate and efficiency of nail plate ablation by 450 nm laser radiation is achieved at an intensity of 200 W/cm2 and is 2750 ± 30 μm/s and 1.47 ± 0.05 μm/mJ, respectively. The delivery rate of Chloderm under the nail plate is 1.15 ± 0.1 mg/s. It is shown that exposure to 450 nm laser radiation at the intensity of 200 W/cm2 for a time sufficient to deliver the drug under the nail plate does not change the extinction coefficient of the drug at the laser wavelength and slightly changes the conformational state of Chloderm. [ABSTRACT FROM AUTHOR]

Published

2023

35. INVESTIGATION OF THE PROTECTIVE CAPABILITIES OF GLASS FROM LASER SOUNDING DEPENDING ON ITS ELEMENTAL COMPOSITION.

Author

Dzianyi, Nazarii, Dudykevych, Valeriy, Opirskyy, Ivan, Rakobovchuk, Larysa, and Haraniuk, Petro

Subjects

ELECTRONICS, LASER beams, ABSORPTION, IMMUNOMODULATORS, ALKALINE earth metals

Abstract

One of the most vulnerable issues in the technical protection of information is to obtain data via leakage through the opto-electronic channel. In this paper, studies of the protective capabilities of glass from laser sounding depending on its elemental composition were carried out using such indicators as the coefficients of reflection and absorption of the laser beam by the window glass. As a result of the work, an experimental installation based on a continuous solid-state laser was assembled. The study of the elemental composition of window glass, which is produced by modern industry, X-ray fluorescence method and the study of the coefficients of reflection and absorption of glass samples in the experimental setup showed that the studied window glass chemically belongs to quartz (silicate). All chemical elements involved in its formation can be divided into 3 groups: glass-forming, transitional, modifiers, which affects the optical properties of the studied glasses, as the elements used have different not only qualitative but also quantitative parameters. Absorption increases if the number of chemical elements that exhibit amphoteric and non-metallic properties and have (-charge) decreases, and increases if the number of chemical elements in the glass that exhibit the most alkaline, alkaline earth properties and in which the radius of cations (+ions) increases. Systematization of the elemental and quantitative composition of the studied window glass in accordance with the periods and groups of the periodic table of chemical elements, enabled the relationship between the electronic structure of chemical elements and the protective properties of glass. [ABSTRACT FROM AUTHOR]

Published

2022

36. Noise control material using jute (Corchorus olitorius): effect of bulk density and thickness.

Author

Sengupta, Surajit, Basu, Gautam, Datta, Mallika, Debnath, Sayandeep, and Nath, Devarun

Subjects

NOISE control, NATURAL fibers, AUDIO frequency, JUTE fiber, ABSORPTION of sound, OKRA, PINEAPPLE

Abstract

An attempt has been made to study the effect of thickness and compactness of natural fibre assembly in the reduction of noise. Fourteen available natural fibres i.e. banana, bhimal, roselle, coconut, cotton, wool, flax, hemp, jute, nettle, okra, pineapple, ramie, sisal and two synthetic sound absorbers i.e. rockwool, glass wool have been tested for sound absorption coefficient. Depending on availability and sound absorbency property, jute fibre (Corchorus olitorius), has been selected for detailed study. Test probe has been designed to test the fibre bundle in impedance tube principle. It is observed that there are significant absorption and transmission loss of sound energy through the jute fibre bundle either alone or covered with paper laminate. Statistical models based on second-order standard polynomial and Box and Benken factorial design, have been suggested to predict the sound transmission loss and absorption with respect to thickness and density in different frequency level of sound for stuffed fibre and paper panel stuffed with fibre. The correlation coefficients between observed and predicted values are above 0.95. Stuffed jute fibre shows maximum sound absorption with 30 mm thickness, 1.0 g/cm3 density in the application of 5000 Hz sound frequency. In case of transmission loss for below 18 mm thickness, jute fibre stuffed paper laminate panel shows increase up to 1.0 g/cm2 and then decrease. The sound loss reaches the maximum in the application of 1500 Hz frequency and then remains constant. Therefore, it can be effectively used as sound absorber or barrier protecting the environment from sound pollution, if designed properly. The knowledge from this study can help to design sound insulator or barrier from an industrial crop like jute. [ABSTRACT FROM AUTHOR]

Published

2021

37. Brownian Diffusion of Nanoparticles in a Liquid and a "Laser Mill".

Author

Fisenko, S. P.

Subjects

LASER beams, NANOPARTICLES, METAL nanoparticles, LASERS, NANOPARTICLE size

Abstract

A description is given of the operating principle of the so-called "laser mill" making it possible to obtain assemblies of virtually monodisperse spherical metal nanoparticles from a colloidal solution of nanoparticles of various size. A laser mill occurs as a result of exposure of such a solution to a powerful pulse-periodic laser radiation, with the characteristic dimension of the forming monodisperse nanoparticles being much smaller than the laser radiation wavelength. [ABSTRACT FROM AUTHOR]

Published

2024

38. 1998年—2020年渤海、黄海和东海月平均典型浮游植物色素浓度遥感数据集.

Author

孙, 德勇, 李, 正浩, 王, 胜强, 环, 宇, 张, 海龙, 齐, 琳, 刘, 建强, and 何, 宜军

Subjects

MARINE phytoplankton, REMOTE sensing, ABSORPTION coefficients, PARTICULATE matter, SPRING, CARBON cycle

Abstract

Copyright of Journal of Remote Sensing is the property of Editorial Office of Journal of Remote Sensing & Science Publishing Co. 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

39. Crystalline Structure and Optical Properties of Cobalt Nickel Oxide Thin Films Deposited with a Pulsed Hollow-Cathode Discharge in an Ar+O 2 Gas Mixture.

Author

Kapran, Anna, Hippler, Rainer, Wulff, Harm, Olejnicek, Jiri, Volfova, Lenka, Pisarikova, Aneta, Nepomniashchaia, Natalia, Cada, Martin, and Hubicka, Zdenek

Subjects

NICKEL oxide, OXIDE coating, COBALT oxides, THIN films, GLOW discharges, CRYSTAL structure

Abstract

Cobalt nickel oxide films are deposited on Si(111) or fluorine-doped tin-oxide-coated (FTO) glass substrates employing a pulsed hollow-cathode discharge. The hollow cathode is operated with argon gas flowing through the nozzle and with O2 gas admitted to the vacuum chamber. Three different cathode compositions (Co20Ni80, Co50Ni50, and Co80Ni20) are investigated. Deposited and annealed thin films are characterized by X-ray diffraction, infrared (Raman) spectroscopy, and ellipsometry. As-deposited films consist of a single mixed cobalt nickel oxide phase. Upon annealing at 600 °C, the mixed cobalt nickel oxide phase separates into two cystalline sub-phases which consist of cubic NiO and cubic Co3O4. Annealed films are investigated by spectroscopic ellipsometry and the optical bandgaps are determined. [ABSTRACT FROM AUTHOR]

Published

2024

40. ELECTROPHYSICAL PROPERTIES OF POLYMERIC NANOCOMPOSITES BASED ON TIN DIOXIDE MODIFIED WITH NICKEL FERRITE.

Author

Prokopenko, S. L., Mazurenko, R. V., Gunja, G. M., Makhno, S. M., and Gorbyk, P. P.

Subjects

NICKEL ferrite, POLYMERIC nanocomposites, ELECTROMAGNETIC wave absorption, STANNIC oxide, TRANSMISSION electron microscopes, ELECTRIC conductivity, ELECTROMAGNETIC radiation

Abstract

The creation of new nanomaterials for absorbtion of electromagnetic radiation microwave range is an important direction in consequence of electromagnetic pollution of the environment. The aim of the paper was to develop and synthesize the polymer-filled systems based on the polychlorotrifluoroethylene and tin dioxide modified by nickel ferrite in order to study their electrophysical properties as potential materials absorbing electromagnetic radiation. NiFe2O4/SnO2 nanocomposites with a volume content of nickel ferrite on the surface of tin dioxide from 0.62 to 0.8 were synthesized by co-precipitation. Size of SnO2 and NiFe2O4 nanoparticles was determined by a transmission electron microscope and its about 30–50 nm and 15–30 nm, respectively. For the NiFe2O4/SnO2 nanocomposites the values of complex permittivity and complex permeability in the microwave range, values of conductivity at low frequencies were investigated. Maximum values of complex permittivity and complex permeability were found for NiFe2O4/SnO2 nanocomposites at the volume content of nickel ferrite 0.62. An increase was observed in the complex permittivity for the NiFe2O4/SnO2–polychlorotrifluoroethylene system, 2–3 times greater than the values related to the NiFe2O4/SnO2 nanocomposites. The electrical conductivity at low frequencies (100 Hz) of polymer composites increases by an order of magnitude with a decrease of the concentration of nickel ferrite on the surface of tin dioxide. It was found that the calculated absorption coefficient of an electromagnetic wave in the frequency range 1–41 GHz for NiFe2O4/SnO2 nanocomposites is about 2 times greater than that for nickel ferrite. It is shown that the creation of nanocomposites based on a conductive component modified by a magnetic component is more efficient for the processes of absorption of electromagnetic waves in the microwave range at optimal ratios of the values of the permittivity and permeability than pure ferrite. [ABSTRACT FROM AUTHOR]

Published

2023

41. Review of Models of Black Bodies Used in Aerospace Vehicles: Part 2. Promising Models of Onboard Black Bodies.

Author

Smetyukhova, T. N.

Subjects

TECHNICAL specifications, CARBON nanotubes, PHASE transitions, INFRARED radiation, ABSORPTION coefficients

Abstract

The paper presents promising models of onboard black bodies based on phase transitions of high-purity substances or eutectic compositions and carbon nanotubes used in aerospace vehicles for the radiometric calibration measurements of the equipment to observe the Earth. Their design and technical specifications, advantages and disadvantages as well as the examples of their use and tests are described. [ABSTRACT FROM AUTHOR]

Published

2022

42. Review of Models of Black Bodies Used in Aerospace Vehicles: Part 2. Promising Models of Onboard Black Bodies.

Author

Smetyukhova, T. N.

Subjects

TECHNICAL specifications, CARBON nanotubes, PHASE transitions, INFRARED radiation, VEHICLES

Abstract

The paper presents promising models of onboard black bodies based on phase transitions of high-purity substances or eutectic compositions and carbon nanotubes used in aerospace vehicles for the radiometric calibration measurements of the equipment to observe the Earth. Their design and technical specifications, advantages and disadvantages as well as the examples of their use and tests are described. [ABSTRACT FROM AUTHOR]

Published

2022

43. 大尺寸氟化铽锂晶体生长与性能.

Author

李兴旺, 杨　宇, 芦　佳, 董　畅, 王永国, and 徐学珍

Subjects

CRYSTAL optics, RESISTANCE heating, ABSORPTION coefficients, LITHIUM fluoride, RESIDUAL stresses, MAGNETOOPTICS

Abstract

Copyright of Journal of Synthetic Crystals is the property of Journal of Synthetic Crystals Editorial Office 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

2023

44. Determination of relative solids concentration in homogeneous dual component pulp-filler suspension by multi-spectrophotometer.

Author

Niskanen, Ilpo, Forsberg, Viviane, Zakrisson, Daniel, Engberg, Birgitta A., Heikkilä, Rauno, and Thungström, Göran

Subjects

PULPING, SPECTROPHOTOMETERS, ULTRAVIOLET radiation, BEER-Lambert law, DATA analysis

Abstract

The concentration of fibers and fillers in the pulp suspension is an important parameter in the monitoring process. This paper proposes a versatile optical measurement system to estimate the concentration of a solids mixture in water. The geometry used in a multispectrophotometer (MSM) enables the controlled observation of transmission, and forward scattering light from the suspension in the UV-visible spectral range. We have developed the new fibers mixing system which gives a homogenous distribution of the fines and fillers making it possible to increase the reproducibility and accuracy of the measurement. The data analysis is based on the Beer- Lambert law and CIELAB color space equations. The results show that the proposed method is accurate for measuring the fines and filler concentrations in multicomponent suspensions.

Published

2020

45. Absorption Coefficient of Bulk III-V Semiconductor Materials: A Review on Methods, Properties and Future Prospects.

Author

Lee, Hui Jing, Gamel, Mansur Mohammed Ali, Ker, Pin Jern, Jamaludin, Md Zaini, Wong, Yew Hoong, and David, John P. R.

Subjects

SEMICONDUCTOR materials, ABSORPTION coefficients, ARTIFICIAL neural networks, BAND gaps

Abstract

Over the last few decades, research works have focused on elucidating the optical properties of semiconductor materials. Despite remarkable progress in the measurement and calculation of the absorption coefficient for semiconductor materials, there is a lack of comprehensive review on the comparative study of absorption coefficient properties for different types of bulk semiconductor materials and their methods for calculating the absorption coefficient. Hence, this paper summarizes the fundamentals of the various methods used to determine the absorption coefficient properties of bulk growth semiconductor crystals, and discusses their advantages and disadvantages. Furthermore, this review provides comprehensive results from recent studies and findings on the absorption properties of near- to mid-infrared (wavelengths from 800 to 7300 nm) group III-V semiconductor materials. In addition, the absorption coefficient of the conventional group IV semiconductors (silicon and Ge) were included for performance comparison. Critical analysis was done for the reviewed materials concerning their material properties, such as band gap structure, crystal quality, and the structural design of the device. The related studies on the methods to determine the absorption coefficients of semiconductors and to improve the likelihood of absorption performance were well highlighted. This review also provides an in-depth discussion on the knowledge of absorption coefficient based on a wide range of semiconductor materials and their potential for sensors, photodetectors, solar and photovoltaic application in the near to mid infrared region. Lastly, the future prospects for research on absorption coefficients are discussed and the advancement in the determination of absorption coefficients for new ternary and quaternary materials is proposed using artificial intelligence such as neural networks and genetic algorithm. [ABSTRACT FROM AUTHOR]

Published

2022

46. FABRIC COLOR FORMULATION USING A MODIFIED KUBELKA-MUNK THEORY CONSIDERING THERMAL EFFECT.

Author

Ling LIN and Ling ZHAO

Subjects

TEMPERATURE effect, TEXTILES, ABSORPTION coefficients, POROSITY, COLOR

Abstract

The Kubelka-Munk function is simple but it ignores the film's thickness, so its applications are greatly limited. Though the exact relationship between the Kubelka-Munk function and the thickness can be derived from a differential model, it is too complex to be practically used. Here a modification is suggested by taking the thickness effect and the temperature effect into account, and the validity is widely enlarged. The modified Kubelka-Munk theory can be used as a colormatching model for colorful fabrics. If the porosity of the film is considered, a fractal modification with two-scale fractal derivative has to be adopted. [ABSTRACT FROM AUTHOR]

Published

2023

47. Waste Durian Husk Fibers as Natural Sound Absorber: Performance and Acoustic Characterization.

Author

Putra, Azma, Othman, Muhammad Nur, Oliveira, Thaynan, Souli, M'hamed, Kassim, Dg Hafizah, Irianto, and Herawan, Safarudin

Subjects

NATURAL fibers, ACOUSTICAL materials, DURIAN, AGRICULTURAL wastes, ABSORPTION coefficients, FIBERS

Abstract

The paper presents the sound absorption coefficient of acoustic absorbers fabricated from natural durian husk fibers, which are currently still considered as agricultural wastes, especially in Malaysia. Samples were fabricated with different fiber densities and thicknesses and the sound absorption performance was measured using the impedance tube method. The results reveal that the durian husk fibers can have absorption coefficient of more than 0.5 above 1 kHz for a minimum thick sample of 20 mm and with minimum density of 160 kg/m3. The optimised macroscopic parameters for various densities were calculated using the inverse method employing the well-known Johnson-Champoux-Allard (JCA) model for porous material. [ABSTRACT FROM AUTHOR]

Published

2022

48. Strain effects on the structural, electronic, optical and thermoelectric properties of Si2SeS monolayer with puckered honeycomb structure: A first‐principles study.

Author

Ait tamerd, Mohamed, Zanouni, Mohamed, Nid‐bahami, Abdelaziz, Diani, Mustapha, and Marjaoui, Adil

Subjects

HONEYCOMB structures, MONOMOLECULAR films, OPTICAL properties, PHASE transitions, DENSITY functional theory, THERMOELECTRIC materials, ABSORPTION coefficients, BAND gaps

Abstract

In this paper, the first‐principles calculations based on the Density Functional Theory (DFT) have been used to study the effect of strain on the structural, electronic, optical and thermoelectric properties of the puckered Si2SeS monolayer. Our calculations show that the puckered Si2SeS monolayer has an indirect band gap of 1.30 eV at the equilibrium state, which can be tuned by biaxial strain and the semiconductor–metal phase transition occurs at −10%. Interestingly, a high absorption coefficient exceeds 107 cm−1 in the visible light region under compression biaxial strain was predicted. The electronic Figure of merit (ZTe) of puckered Si2SeS monolayer reaches 2.55 under the tensile biaxial strain of +6%. The presented results show the promising potential of puckered Si2SeS monolayer for optoelectronic and energy conversion applications. [ABSTRACT FROM AUTHOR]

Published

2022

49. First-Principles Study of Electronic and Optical Properties of Tri-Layered van der Waals Heterostructures Based on Blue Phosphorus and Zinc Oxide.

Author

Slepchenkov, Michael M., Kolosov, Dmitry A., and Glukhova, Olga E.

Subjects

OPTICAL properties, HETEROSTRUCTURES, ABSORPTION coefficients, THERMAL conductivity, ABSORPTION spectra

Abstract

The creation of van der Waals heterostructures with tunable properties from various combinations of modern 2D materials is one of the promising tasks of nanoelectronics, focused on improving the parameters of electronic nanodevices. In this paper, using ab initio methods, we theoretically predict the existence of new three-layer van der Waals zinc oxide/blue phosphorus/zinc oxide (ZnO/BlueP/ZnO) heterostructure with AAA, ABA, ABC layer packing types. It is found that AAA-, ABA-, and ABC-stacked ZnO/BlueP/ZnO heterostructures are semiconductors with a gap of about 0.7 eV. The dynamic conductivity and absorption spectra are calculated in the wavelength range of 200–2000 nm. It is revealed that the BlueP monolayer makes the greatest contribution to the formation of the profiles the dynamic conductivity and absorption coefficient spectrums of the ZnO/BlueP/ZnO heterostructure. This is indicated by the fact that, for the ZnO/BlueP/ZnO heterostructure, conductivity anisotropy is observed at different directions of wave polarization, as for blue phosphorus. It has been established that the absorption maximum of the heterostructure falls in the middle ultraviolet range, and, starting from a wavelength of 700 nm, there is a complete absence of absorption. The type of layer packing has practically no effect on the regularities in the formation of the spectra of dynamic conductivity and the absorption coefficient, which is important from the point of view of their application in optoelectronics. [ABSTRACT FROM AUTHOR]

Published

2022

50. Low-Frequency Sound Absorption of an Inhomogeneous Micro-Perforated Panel with J-Shaped Cavities of Different Depths.

Author

Rafique, Faisal, Wu, Jiu Hui, Liu, Chong Rui, and Ma, Fuyin

Subjects

ABSORPTION of sound, AUDIO frequency, ABSORPTION coefficients, FINITE element method, DEPTH sounding, COMPOSITE structures, CURVES

Abstract

In this paper, a micro-perforated panel (MPP) composite structure consisting of an inhomogeneous MPP (IMPP) backed with J-shaped cavities of different depths for low-frequency sound absorption is proposed. The goal is to increase the low-frequency (≤ 500 Hz) sound absorption performance of the IMPP. Sound absorption in a frequency range of 300–480 Hz was achieved with parallel-arranged IMPPs backed by J-shaped cavities, with average absorption of greater than 90%. A parametric analysis was used to optimize the structure's geometric parameters for the specified frequency range. The results show that when the length and volume of the back cavity depths increase, the low-frequency sound absorption peaks shift to a lower frequency. Similarly, the sound absorption curves are enhanced and move towards lower frequencies as the thickness of the IMPP increases. The structure was studied using an electro-acoustic equivalent circuit model (ECM) and finite element method (FEM) simulation. Model prototypes were then made using stereolithography (SLA) and verified by a square-shaped impedance tube-based experimental study to determine the normal absorption coefficient. The results revealed that the three types of curves, namely theoretical, FEM simulation, and experimental, were in good agreement. [ABSTRACT FROM AUTHOR]

Published

2022