Your search keyword '"Multi-layer"' showing total 989 results

1. Multi-layer Tuning CLIP for Few-Shot Image Classification

Author

Zhang, Ruihao, Geng, Jinsong, Liu, Cenyu, Zhang, Wei, Feng, Zunlei, xue, Liang, Bei, Yijun, Goos, Gerhard, Series Editor, Hartmanis, Juris, Founding Editor, Bertino, Elisa, Editorial Board Member, Gao, Wen, Editorial Board Member, Steffen, Bernhard, Editorial Board Member, Yung, Moti, Editorial Board Member, Lin, Zhouchen, editor, Cheng, Ming-Ming, editor, He, Ran, editor, Ubul, Kurban, editor, Silamu, Wushouer, editor, Zha, Hongbin, editor, Zhou, Jie, editor, and Liu, Cheng-Lin, editor

Published

2025

2. The Significance of the Citizens Theatre Paint Frames.

Author

Young, Christina and Botticelli, Michela

Subjects

*ENERGY dispersive X-ray spectroscopy, *PAINTING, *SCANNING electron microscopy, *INFRARED spectroscopy, *BRITISH art

Abstract

A paint frame is the vertical structure on which a canvas is hung to allow a scenic artist to paint over a very large area. The Citizens Theatre paint frames are one of the few original working examples in Britain. Samples taken from these frames are made up of multiple layers of paint which have accreted over 100 years as paint flicked off brushes, rollers, and latterly spray guns while the cloths were being painted. Cross-section microscopy, micro-Fourier transform infrared spectroscopy (μ-FTIR) mapping and scanning electron microscopy with energy dispersive X-ray spectroscopy (SEM-EDX) were used to characterise these layers. Using the results in combination with archival research into scenic art suppliers/manufacturers, newspaper reviews of theatrical performances, and oral histories of scenic artists it has been possible for the first time to relate change in pigments and media within the paint layers with trends in scenic painting practice. This is one aim of ongoing research into the history of British scenic art (https://powertotransform.gla.ac.uk/) connecting the material history of the paint frame, theatrical cloths, and the lives of the scenic painters. [ABSTRACT FROM AUTHOR]

Published

2024

3. Multilayer textile-based concept for non-invasive biosensor platform.

Author

Soekoco, Asril Senoaji, Septiani, Ni Luh Wulan, Iqbal, Muhammad, Irzaman, Nugroho, Widagdo Sri, Rusydi, Febdian, Nugraha, and Yuliarto, Brian

Subjects

CARBON electrodes, LINEAR equations, TIME measurements, SURFACE area, INTERVAL measurement

Abstract

The surface area of the working electrode plays a crucial role in determining the sensor's performance, especially in enzymatic sensors. Increasing the surface area of the working electrode has a significant impact on the sensor's functionality. This research focused on developing textile-based sensors using a multi-layer concept, employing the direct coating method. Two different sensors which are multilayer textile-based sensor (MTBS) and single-layer textile-based sensor (STBS) were prepared, while commercial screen-printed carbon electrode (SPCE) was also used as a comparison. The measurements were carried out using potassium ferricyanide solutions with concentrations of 0.01 M, 0.02 M, 0.03 M, 0.04 M, and 0.05 M at a voltage of 1 V, with a maximum duration up to the end of the measurement and a time interval of 0.5 s. According to the research findings, the fluid spreading speed of the SPCE is the lowest when compared to the spreading speeds of the MTBS and STBS. Specifically, the fluid spreading speed of the SPCE is 4.3 times slower than that of the STBS and 51 times slower than that of the MTBS. Utilizing a multi-layer concept with specific coatings can lead to better-performing sensors in terms of stability and sensitivity. The MTBS exhibits the greatest sensitivity, as indicated by its linear equation slope of 717.230 µA µM−1 cm−2. [ABSTRACT FROM AUTHOR]

Published

2024

4. Multi-layer structured AlN/Er2O3 coating: Enhanced thermal stability and hydrogen isotope permeation resistance.

Author

Wang, Feiyue, Wang, Jing, Lu, Wei, Li, Wenguang, Chu, Delin, and Wang, Weihua

Subjects

*HYDROGEN isotopes, *HYDROGEN as fuel, *SPIN coating, *NUCLEAR reactors, *TRITIUM, *DEUTERIUM

Abstract

AlN/Er 2 O 3 multi-layer coatings, as a novel hydrogen isotope permeation barrier for nuclear reactor and hydrogen energy field, were prepared by magnetron sputtering coupled with metal-organic decomposition on the surface of reduced activation ferrite/martensitic steel. The thickness of the Er 2 O 3 layers was adjusted by spin coating several times, the adhesion of the layers was tested with a micron scratch tester, and the microstructure and surface composition of the layers were analyzed by TEM and XPS. The results indicate the absence of evident crack holes on the coating surface, uniform distribution of elements without segregation, and satisfactory densification. In comparison with the individual Er 2 O 3 coating, the multi-layer coating incorporating AlN as the interlayer exhibits enhanced adhesion strength, which could effectively mitigate the thermal mismatch phenomenon of Er 2 O 3 under high temperature conditions. Electrochemical hydrogen permeation and high temperature gas pressure driven deuterium permeation tests demonstrated that the permeability resistance of the AlN/Er 2 O 3 coating does not linearly increase with its thickness. The hydrogen permeation reduced factor of the coating reaches its maximum value when the thickness of the Er 2 O 3 coating is 1500 nm. [ABSTRACT FROM AUTHOR]

Published

2024

5. Theoretical and experimental research on static stiffness, performance, and lift-off characteristics of multi-layer gas foil thrust bearings.

Author

Hu, Yang, Ding, Pengjing, Wu, Fangling, Wang, Xiaojing, Liang, Bo, and Meng, Yonggang

Subjects

THRUST bearings, TORQUE, NEW business enterprises, SPEED, GASES

Abstract

In this study, a new comprehensive fully coupled elastic-hydrodynamic model is developed for a multi-layer gas foil thrust bearing (GFTB). The interaction effects among the top foil, back board, middle foil, and bottom foil, as well as the Coulomb friction effect, are considered. The stiffness and static characteristics obtained by the experimental and theoretical approaches are in good agreement, which verifies the accuracy of the model. The contribution of each foil layer to the overall stiffness and the load-carrying mechanism are analyzed. Interaction effects of the load, preload, and rotational speed on the static performance are investigated comprehensively. Furthermore, start-stop tests are performed to achieve the lift-off speed, start-up torque, and shut-down torque under various operating conditions. [ABSTRACT FROM AUTHOR]

Published

2024

6. Multi-Scale and Multi-Layer Lattice Transformer for Underwater Image Enhancement.

Author

Hsu, Wei-Yen and Hsu, Yu-Yu

Subjects

LIGHT absorption, IMAGE reconstruction, IMAGE intensifiers, LIGHT scattering, WAVELENGTHS

Abstract

Underwater images are often subject to color deviation and a loss of detail due to the absorption and scattering of light. The challenge of enhancing underwater images is compounded by variations in wavelength and distance attenuation, as well as color deviation that exist across different scales and layers, resulting in different degrees of color deviation, attenuation, and blurring. To address these issues, we propose a novel multi-scale and multi-layer lattice transformer (MMLattFormer) to effectively eliminate artifacts and color deviation, prevent over-enhancement, and preserve details across various scales and layers, thereby achieving more accurate and natural results in underwater image enhancement. The proposed MMLattFormer model integrates the advantage of LattFormer to enhance global perception with the advantage of "multi-scale and multi-layer" configuration to leverages the differences and complementarities between features of various scales and layers to boost local perception. The proposed MMLattFormer model is comprised of multi-scale and multi-layer LattFormers. Each LattFormer primarily encompasses two modules: Multi-head Transposed-attention Residual Network (MTRN) and Gated-attention Residual Network (GRN). The MTRN module enables cross-pixel interaction and pixel-level aggregation in an efficient manner to extract more significant and distinguishable features, whereas the GRN module can effectively suppress under-informed or redundant features and retain only useful information, enabling excellent image restoration exploiting the local and global structures of the images. Moreover, to better capture local details, we introduce depthwise convolution in these two modules before generating global attention maps and decomposing images into different features to better capture the local context in image features. The qualitative and quantitative results indicate that the proposed method outperforms state-of-the-art approaches in delivering more natural results. This is evident in its superior detail preservation, effective prevention of over-enhancement, and successful removal of artifacts and color deviation on several public datasets. [ABSTRACT FROM AUTHOR]

Published

2024

7. Broadband multi‐layered stepped cone shaped metamaterial absorber for energy harvesting and stealth applications.

Author

Bağmancı, Mehmet, Wang, Lulu, Sabah, Cumali, Karaaslan, Muharrem, Paul, Liton Chandra, Rani, Tithi, and Unal, Emin

Subjects

ENERGY levels (Quantum mechanics), ENERGY harvesting, ELECTRICAL energy, UNIT cell, METAMATERIALS

Abstract

In this study, a broadband polarization and angle‐independent metamaterial absorber (MA) is investigated in the microwave range. It is made up of a periodic array of multi‐layered metal‐dielectric stepped cones. Since the dimensions of the layers forming the unit cell are different, each layer resonates at different frequencies with overlapping bands. The overall response of the structure, with its extremely wide bandwidth, can be obtained by summing all the overlapping frequency responses corresponding to each layer. In numerical simulation, it is observed that the absorption at normal incidence is above 90% in the frequency range between 9.68 and 17.45 GHz and 95% in the frequency range between 9.91 and 14.86 GHz. The energy harvesting ratios of the structure are also evaluated in a wide spectral band. A power ratio of around 90% is obtained in the same frequency range in accordance with absorption response. A noticeable harvesting efficiency of up to 82% is observed, which represents the energy level converted into electrical energy on resistors. [ABSTRACT FROM AUTHOR]

Published

2024

8. Multilayer textile-based concept for non-invasive biosensor platform

Author

Asril Senoaji Soekoco, Ni Luh Wulan Septiani, Muhammad Iqbal, Irzaman, Widagdo Sri Nugroho, Febdian Rusydi, Nugraha, and Brian Yuliarto

Subjects

Biosensor, Diabetes, Textile-based sensor, Multi-layer, Non-invasive biosensor, Textile bleaching, dyeing, printing, etc., TP890-933, Social Sciences

Abstract

Abstract The surface area of the working electrode plays a crucial role in determining the sensor’s performance, especially in enzymatic sensors. Increasing the surface area of the working electrode has a significant impact on the sensor’s functionality. This research focused on developing textile-based sensors using a multi-layer concept, employing the direct coating method. Two different sensors which are multilayer textile-based sensor (MTBS) and single-layer textile-based sensor (STBS) were prepared, while commercial screen-printed carbon electrode (SPCE) was also used as a comparison. The measurements were carried out using potassium ferricyanide solutions with concentrations of 0.01 M, 0.02 M, 0.03 M, 0.04 M, and 0.05 M at a voltage of 1 V, with a maximum duration up to the end of the measurement and a time interval of 0.5 s. According to the research findings, the fluid spreading speed of the SPCE is the lowest when compared to the spreading speeds of the MTBS and STBS. Specifically, the fluid spreading speed of the SPCE is 4.3 times slower than that of the STBS and 51 times slower than that of the MTBS. Utilizing a multi-layer concept with specific coatings can lead to better-performing sensors in terms of stability and sensitivity. The MTBS exhibits the greatest sensitivity, as indicated by its linear equation slope of 717.230 µA µM−1 cm−2.

Published

2024

9. Assemble of porous heterostructure thin film through CuS passivation for efficient electron transport in dye-sensitized solar cells

Author

Mojeed A. Agoro, Edson L. Meyer, and Olufemi I. Olayiwola

Subjects

Nanoparticles, Multi-layer, Heterostructure, Photo-conversions, DSSCs, Materials of engineering and construction. Mechanics of materials, TA401-492

Abstract

Abstract Three different modified solar cells have been passivated with copper sulfide (CuS) on a TiO2 electrode and manganese sulfide (γ‐MnS) hexagonal as photon absorbers. The MnS were prepared using (a-c) bis(N‐Piperl‐N‐p‐anisildithiocarbamato)Manganese(II) Complexes Mn[N-Piper‐N‐p‐Anisdtc] as (MnS_1), N‐p-anisidinyldithiocarbamato Mn[N‐p-anisdtc] as (MnS_2) and N‐piperidinyldithiocarbamato Mn[N‐piperdtc] as (MnS_3). The corresponding passivated films were denoted as CM-1, CM-2, and CM-3. The influence of passivation on the structural, optical, morphological, and photochemical properties of the prepared devices has been investigated. Raman spectra show that the combination of this heterostructure is triggered by the variation in particle size and surface effect, thus resulting in good electronic conductivity. The narrow band gaps could be attributed to good interaction between the passivative materials on the TiO2 surface. CM-2 cells, stability studies show that the cell is polarized and current flows due to electron migration across the electrolyte and interfaces at this steady state. The cyclic voltammetry (CV) curve for the CM-3 with the highest current density promotes the electrocatalytic activity of the assembled solar cell. The catalytic reactions are further confirmed by the interfacial electron lifetimes in the Bode plots and the impedance spectra. The current–voltage (J–V) analysis suggests that the electrons in the conduction band of TiO2/CuS recombine with the semiconductor quantum dots (QDs) and the iodolyte HI-30 electrolyte, resulting in 5.20–6.85% photo-conversions.

Published

2024

10. Multi‐layer structure design, fabrication and numerical simulations of 3D woven spacer fabric composites with improved mechanical properties.

Author

Huang, Ying, Zhao, Xingzu, Zhao, Jun, Ouyang, Yiwei, Xu, Weilin, and Liu, Yang

Subjects

*FRACTURE strength, *DAMAGE models, *STRESS concentration, *COMPUTER simulation, *TEXTILES

Abstract

Highlights The 3D woven spacer fabric lightweight composites (WSFC) show promising applications in construction, transportation and aerospace. In this study, the 3D WSFC with different structural variations (e.g., layer thicknesses, stacking and face layer thickening) were designed and fabricated. The fracture strengths of single‐layer WSFC in the weft direction with layer thicknesses of 5, 10 and 15 mm were 54.4, 14.3, and 5.4 MPa. In the weft direction, the fracture strengths of double‐ and triple‐stacked 3D WSFCs were 30.6 and 21.7 MPa, which improved 1.1 times and 3.0 times as compared with those of original single‐layer 3D WSFCs, respectively. The double‐ and triple‐stacked WSFC also had large flexural deformation. The 3D WSFC with double‐layer misaligned stacking had the similar flexural strengths in both directions, which obviously reduced the performance differentiation of 3D WSFC in different directions. With the addition of face layer fabric, the mechanical performances of 3D WSFC were notably enhanced, and the damage modes were changed from brittle failure to ductile failure. Furthermore, a multi‐scale model of 3D WSFC with different structural variations was developed for numerical simulation to analyze the stress distribution and damage mechanism. Stacking design obviously improves mechanical properties of 3D WSFC. WSFC with misaligned stacking has similar flexural strengths. A multi‐scale elastic–plastic damage model for 3D WSFC is established. Damage modes of WSFC are changed with the stacking method. [ABSTRACT FROM AUTHOR]

Published

2024

11. Miniaturized Multiband Substrate-Integrated Waveguide Bandpass Filters with Multi-Layer Configuration and High In-Band Isolation.

Author

Zhan, Yu, Wu, Yi, Ma, Kaixue, and Yeo, Kiat Seng

Subjects

BANDPASS filters, WAVEGUIDE filters, RESONATORS, TOPOLOGY, DESIGN

Abstract

This article presents a multiband bandpass filter structure with an in-line topology based on substrate-integrated waveguide (SIW) technology. A multi-layer configuration is employed to achieve circuit miniaturization. By constructing the coupling matrix, the coupling relationships among all resonators are quantitatively characterized, enabling the extraction of the theoretical frequency response and guiding circuit modeling and optimization. We designed and fabricated a third-order tri-band SIW filter and a third-order quad-band SIW filter, achieving a return loss of nearly 20 dB across all passbands. The close agreement between simulated and measured results validates the proposed design model. Additionally, the high in-band isolation of over 40 dB is demonstrated between all adjacent bands, highlighting the potential applicability of this technology in multiband scenarios. [ABSTRACT FROM AUTHOR]

Published

2024

12. Stimulation Behavior of Fracture Networks in the Second Hydrate Trial Production Area of China Considering the Presence of Multiple Layers.

Author

Chen, Chen, Li, Xitong, and Zhong, Xiuping

Subjects

*GAS hydrates, *MIXING height (Atmospheric chemistry)

Abstract

The fracture network's stimulation of China's second hydrate trial production area was investigated. First, the stimulation potential of the fracture network and the influence of well arrangement on hydrate development were explored. Second, the fracture distributions' influence on development behavior was investigated. Results showed that the fracture network could cause the trial production reservoir to reach the commercial production rate. The average CH4 production rate of unit horizontal well length using the depressurization method and depressurization combined with thermal stimulation (combined method) were 61.3 and 151.5 m3/d with the fracture network and 23.7 and 14.3 m3/d without the fracture network. In addition, without the fracture network, the development behavior of wells arranged in the mixed layer was better than that of wells arranged in the hydrate layer. However, with the fracture network, the result was reversed. With the depressurization method, the best production behavior was obtained by fracturing in the hydrate layer; however, for the combined method, the best production behavior was obtained by fracturing in the hydrate and mixed layer, while fracturing in the free gas layer was useless. This study provides a valuable reference for the hydrate development of China's trial production reservoir. [ABSTRACT FROM AUTHOR]

Published

2024

13. Investigation of thermal conductivity and mechanical properties in multi-layer of graphene and graphene oxide: a molecular dynamics study.

Author

Salehi, Arman, Ghaderiazar, Nima, and Rash-Ahmadi, Samrand

Subjects

*GRAPHENE oxide, *TENSILE strength, *YOUNG'S modulus, *THERMAL conductivity, *THERMAL properties

Abstract

Multi-layered graphene and graphene oxide have been used as reinforcements in nanodevices and nanocomposites due to their extraordinary mechanical and thermal properties. However, compared to graphene, graphene oxide has a lower Young's modulus and lower thermal conductivity. Nanodevices and nanocomposites based on multi-layered graphene and graphene oxide require different mechanical properties and thermal conductivity. This study employed molecular dynamics simulation to investigate 10 models of multi-layered graphene and graphene oxide (in the form of different layer arrangements) in single, double, and triple layers. The results showed that an increase in the number of graphene oxide layers leads to irregularities in the nanosheets, resulting in decreased thermal conductivity (by 64.4%) of the nanosheets decreases. Furthermore, the greater number of graphene layers in multi-layer nanosheets resulted in an increase in Young's modulus (by 79.3%) and tensile strength (by 73.7%). Moreover, the arrangement of graphene and graphene oxide is a crucial factor that can significantly impact the mechanical properties and thermal conductivity of the models. Moreover, an increase in temperature can lead to a decrease in Young's modulus of multilayered nanosheets. Increasing the number and size of graphene layers enhances both the ultimate tensile strength and the critical energy release rate. [ABSTRACT FROM AUTHOR]

Published

2024

14. Sound absorption properties and mechanism of multi‐layer micro‐perforated nanofiber membrane.

Author

Shao, Xiaofei and Yan, Xiong

Subjects

ACOUSTICAL engineering, ACOUSTICAL materials, POLYVINYL butyral, ABSORPTION coefficients, STRUCTURAL optimization, ABSORPTION of sound

Abstract

Aiming at achieving low‐frequency and broadband sound absorption under the premise of light and thin layers, in this paper, polyvinyl butyral (PVB) nanofiber membranes were micro‐perforated and then combined sequentially to prepare multi‐layer micro‐perforated nanofiber membrane (MPNM) for acoustic noise reduction. It was demonstrated that the multi‐layer MPNM exhibited a high absorption (constantly over 50%) in the frequency of 480–2500 Hz. In addition, the established theoretical model of the sound absorbing coefficient can accurately predict the sound absorption performance of the structure with different layers, which can provide a theoretical foundation for the design of the structure of the nanofibrous membrane acoustic absorber. Based on the proposed acoustic model, the relationships between the absorption properties and the parameters were investigated, and it was found that the effective acoustic absorption frequency range and acoustic absorption coefficient curve of the multi‐layer MPNM were closely related to the size and arrangement of hole diameter, perforation rate, fiber membrane thickness, and cavity depth. Optimization of the structural parameters utilizing algorithms can achieve superior sound absorption performance, with an average absorption coefficient of 0.81 in the frequency of 100–2500 Hz. This study provides a theoretical and experimental basis for the development of low‐frequency sound‐absorbing materials and is of great significance for optimizing the acoustic performance of nanofiber membranes and expanding their applications in various acoustic engineering applications. [ABSTRACT FROM AUTHOR]

Published

2024

15. Metamaterial Broadband Absorber Induced by Synergistic Regulation of Temperature and Electric Field and Its Optical Switching Application.

Author

Yang, Rundong, Liu, Yun, and Wang, Xiangfu

Subjects

*OPTICAL switching, *SILVER sulfide, *BREWSTER'S angle, *FINITE element method, *TEMPERATURE control, *TERAHERTZ materials

Abstract

Nowadays, metamaterial absorbers still suffer from limited bandwidth, poor bandwidth scalability, and insufficient modulation depth. In order to solve this series of problems, we propose a metamaterial absorber based on graphene, VO2, gallium silver sulfide, and gold-silver alloy composites with dual-control modulation of temperature and electric field. Then we further investigate the optical switching performance of this absorber in this work. Our proposed metamaterial absorber has the advantages of broad absorption bandwidth, sufficient modulation depth, and good bandwidth scalability all together. Unlike the single inspired layer of previous designs, we innovatively adopted a multi-layer excitation structure, which can realize the purpose of absorption and bandwidth width regulation by a variety of means. Combined with the finite element analysis method, our proposed metamaterial absorber has excellent bandwidth scalability, which can be tuned from 2.7 THz bandwidth to 12.1 THz bandwidth by external electrothermal excitation. Meanwhile, the metamaterial absorber can also dynamically modulate the absorption from 3.8% to 99.8% at a wide incidence angle over the entire range of polarization angles, suggesting important potential applications in the field of optical switching in the terahertz range. [ABSTRACT FROM AUTHOR]

Published

2024

16. Assemble of porous heterostructure thin film through CuS passivation for efficient electron transport in dye-sensitized solar cells.

Author

Agoro, Mojeed A., Meyer, Edson L., and Olayiwola, Olufemi I.

Subjects

DYE-sensitized solar cells, BAND gaps, CONDUCTION electrons, ELECTRON transport, CONDUCTION bands

Abstract

Three different modified solar cells have been passivated with copper sulfide (CuS) on a TiO2 electrode and manganese sulfide (γ‐MnS) hexagonal as photon absorbers. The MnS were prepared using (a-c) bis(N‐Piperl‐N‐p‐anisildithiocarbamato)Manganese(II) Complexes Mn[N-Piper‐N‐p‐Anisdtc] as (MnS_1), N‐p-anisidinyldithiocarbamato Mn[N‐p-anisdtc] as (MnS_2) and N‐piperidinyldithiocarbamato Mn[N‐piperdtc] as (MnS_3). The corresponding passivated films were denoted as CM-1, CM-2, and CM-3. The influence of passivation on the structural, optical, morphological, and photochemical properties of the prepared devices has been investigated. Raman spectra show that the combination of this heterostructure is triggered by the variation in particle size and surface effect, thus resulting in good electronic conductivity. The narrow band gaps could be attributed to good interaction between the passivative materials on the TiO2 surface. CM-2 cells, stability studies show that the cell is polarized and current flows due to electron migration across the electrolyte and interfaces at this steady state. The cyclic voltammetry (CV) curve for the CM-3 with the highest current density promotes the electrocatalytic activity of the assembled solar cell. The catalytic reactions are further confirmed by the interfacial electron lifetimes in the Bode plots and the impedance spectra. The current–voltage (J–V) analysis suggests that the electrons in the conduction band of TiO2/CuS recombine with the semiconductor quantum dots (QDs) and the iodolyte HI-30 electrolyte, resulting in 5.20–6.85% photo-conversions. [ABSTRACT FROM AUTHOR]

Published

2024

17. Broadband multi‐layered stepped cone shaped metamaterial absorber for energy harvesting and stealth applications

Author

Mehmet Bağmancı, Lulu Wang, Cumali Sabah, Muharrem Karaaslan, Liton Chandra Paul, Tithi Rani, and Emin Unal

Subjects

broadband metamaterial absorber, cone‐shape, energy harvesting, multi‐layer, stealth applications, Engineering (General). Civil engineering (General), TA1-2040, Electronic computers. Computer science, QA75.5-76.95

Abstract

Abstract In this study, a broadband polarization and angle‐independent metamaterial absorber (MA) is investigated in the microwave range. It is made up of a periodic array of multi‐layered metal‐dielectric stepped cones. Since the dimensions of the layers forming the unit cell are different, each layer resonates at different frequencies with overlapping bands. The overall response of the structure, with its extremely wide bandwidth, can be obtained by summing all the overlapping frequency responses corresponding to each layer. In numerical simulation, it is observed that the absorption at normal incidence is above 90% in the frequency range between 9.68 and 17.45 GHz and 95% in the frequency range between 9.91 and 14.86 GHz. The energy harvesting ratios of the structure are also evaluated in a wide spectral band. A power ratio of around 90% is obtained in the same frequency range in accordance with absorption response. A noticeable harvesting efficiency of up to 82% is observed, which represents the energy level converted into electrical energy on resistors.

Published

2024

18. Enhanced Color‐Preserving Radiative Coolers for Versatile Architectural Applications.

Author

Kim, June Tae, Jeon, Seung Kyu, Kim, Min Seong, Yeo, Dong Hun, Nahm, Sahn, Kim, Yeong Jae, and Lee, Gil Ju

Subjects

*CLEAN energy, *CLIMATE change, *SOLAR heating, *SOLAR technology, *COOLING, *REFLECTANCE, *PIGMENTS

Abstract

Global climate crises are the most significant challenges to be solved these days. As one of the technological endeavors to tackle the issue, radiative cooling is amongst the most attractive approaches for sustainable heat energy regulation, which involves maximizing solar heat reflection and thermal heat emission. These green technologies inevitably require architectural applicability, considering that building facades take a large proportion of the heat‐radiating surfaces. For mass‐production suitability and durability, radiative coolers (RCs) fabricated in a fully ceramic context are recently suggested, featuring scalable, thermally insulative, and non‐shrinking advantages. However, the visual effects are also imperative for architectural instances but are seldom accounted for. In this context, this article suggests the enhanced color‐preserving radiative cooling (ECRC) structure for practical architectural applications of glass‐infiltrated ceramic RCs. By simply blending ceramic pigment into the uppermost porous alumina layer, the ECRC structure can maintain the physical, and thermal features of all‐ceramic RC, while exhibiting color by visible reflectance adjustment. ECRCs exhibit an additional cooling performance of up to ≈17.3 °C depending on their color, compared to their conventional counterparts. With additional chromatic features, ECRC can further enhance the availability of radiative cooling technology for practically realizing the energy‐saving structures in real‐world architectural circumstances. [ABSTRACT FROM AUTHOR]

Published

2024

19. Development and Fabrication of a Multi-Layer Planar Solar Light Absorber Achieving High Absorptivity and Ultra-Wideband Response from Visible Light to Infrared.

Author

Yang, Cheng-Fu, Wang, Chih-Hsuan, Ke, Pei-Xiu, Meen, Teen-Hang, and Lai, Kuei-Kuei

Subjects

*VISIBLE spectra, *INFRARED absorption, *SOLAR spectra, *TRANSMISSION electron microscopy, *IMPEDANCE matching, *ELECTROMAGNETIC wave absorption, *ABSORPTION spectra, *INFRARED radiation

Abstract

The objective of this study is to create a planar solar light absorber that exhibits exceptional absorption characteristics spanning from visible light to infrared across an ultra-wide spectral range. The eight layered structures of the absorber, from top to bottom, consisted of Al2O3, Ti, Al2O3, Ti, Al2O3, Ni, Al2O3, and Al. The COMSOL Multiphysics® simulation software (version 6.0) was utilized to construct the absorber model and perform simulation analyses. The first significant finding of this study is that as compared to absorbers featuring seven-layered structures (excluding the top Al2O3 layer) or using TiO2 or SiO2 layers as substituted for Al2O3 layer, the presence of the top Al2O3 layer demonstrated superior anti-reflection properties. Another noteworthy finding was that the top Al2O3 layer provided better impedance matching compared to scenarios where it was absent or replaced with TiO2 or SiO2 layers, enhancing the absorber's overall efficiency. Consequently, across the ultra-wideband spectrum spanning 350 to 1970 nm, the average absorptivity reached an impressive 96.76%. One significant novelty of this study was the utilization of various top-layer materials to assess the absorption and reflection spectra, along with the optical-impedance-matching properties of the designed absorber. Another notable contribution was the successful implementation of evaporation techniques for depositing and manufacturing this optimized absorber. A further innovation involved the use of transmission electron microscopy to observe the thickness of each deposition layer. Subsequently, the simulated and calculated absorption spectra of solar energy across the AM1.5 spectrum for both the designed and fabricated absorbers were compared, demonstrating a match between the measured and simulated results. [ABSTRACT FROM AUTHOR]

Published

2024

20. Additive Manufacturing of Electrically Conductive Multi-Layered Nanocopper in an Air Environment.

Author

Pervan, David, Bastola, Anil, Worsley, Robyn, Wildman, Ricky, Hague, Richard, Lester, Edward, and Tuck, Christopher

Subjects

*ELECTRON beam furnaces, *LASER deposition, *COPPER, *AUTOMOTIVE electronics, *LASER sintering, *ELECTRIC conductivity

Abstract

The additive manufacturing (AM) of functional copper (Cu) parts is a major goal for many industries, from aerospace to automotive to electronics, because Cu has a high thermal and electrical conductivity as well as being ~10× cheaper than silver. Previous studies on AM of Cu have concentrated mainly on high-energy manufacturing processes such as Laser Powder Bed Fusion, Electron Beam Melting, and Binder Jetting. These processes all require high-temperature heat treatment in an oxygen-free environment. This paper shows an AM route to multi-layered microparts from novel nanoparticle (NP) Cu feedstocks, performed in an air environment, employing a low-power (<10 W) laser sintering process. Cu NP ink was deposited using two mechanisms, inkjet printing, and bar coating, followed by low-power laser exposure to induce particle consolidation. Initial parts were manufactured to a height of approximately 100 µm, which was achieved by multi-layer printing of 15 (bar-coated) to 300 (inkjetted) layers. There was no evidence of oxidised copper in the sintered material, but they were found to be low-density, porous structures. Nonetheless, electrical resistivity of ~28 × 10−8 Ω m was achieved. Overall, the aim of this study is to offer foundational knowledge for upscaling the process to additively manufacture Cu 3D parts of significant size via sequential nanometal ink deposition and low-power laser processing. [ABSTRACT FROM AUTHOR]

Published

2024

21. A systematic multi-layer cognitive model for intelligent machine tool

Author

Jiang, Tengyuan, Zhou, Jingtao, Luo, Xiang, Wang, Mingwei, and Zhang, Shusheng

Published

2024

22. Layer multiplication co‐extrusion of cross‐linked polymer microsphere‐filled systems.

Author

Steinmetz, Erik and Maia, João

Subjects

CROSSLINKED polymers, MECHANICAL drawing, MULTIPLICATION, POLYMER structure, POLYMETHYLMETHACRYLATE, MICROSPHERES

Abstract

Layer multiplication co‐extrusion allows for creation of advance structures with highly tunable properties, with relative ease. Multi‐layer co‐extrusion using the layer multiplication technique was used to create 33‐layered structures of polymer microsphere‐filled layers alternating with unfilled layers. Cross‐linked polyurethane (PU) microspheres (of two different rigidities) and ultra‐highly cross‐linked polymethylmethacrylate (PMMA) microspheres were used to examine the effect of particle rigidity in confinement on overall mechanical properties. Layer structures were successfully created with particle‐filled layers; once layer size approaches the particle size, the particles deform the unfilled counter‐layer. In certain conditions, impingement of the counter‐layer occurs, decreasing the mechanical properties. High‐density polyethylene‐grafted‐maleic anhydride (HDPE‐g‐MA) was subsequently utilized as a compatibilizer to improve the interface between the particles and the matrix. The HDPE‐g‐MA was effective in increasing the mechanical performance of the co‐extruded product made with the PU microspheres but inefficient in improving the product made with the PMMA microspheres. [ABSTRACT FROM AUTHOR]

Published

2024

23. A flexible ultra-broadband multi-layered absorber working at 2 GHz–40 GHz printed by resistive ink.

Author

Wang, Tao, Yan, Yu-Lun, Chen, Gong-Hua, Li, Ying, Hu, Jun, and Mao, Jian-Bo

Subjects

*FREQUENCY selective surfaces, *PRINTING ink, *CONDUCTIVE ink, *REFLECTANCE, *CURRENT distribution

Abstract

A flexible extra broadband metamaterial absorber (MMA) stacked with five layers working at 2 GHz–40 GHz is investigated. Each layer is composed of polyvinyl chloride (PVC), polyimide (PI), and a frequency selective surface (FSS), which is printed on PI using conductive ink. To investigate this absorber, both one-dimensional analogous circuit analysis and three-dimensional full-wave simulation based on a physical model are provided. Various crucial electromagnetic properties, such as absorption, effective impedance, complex permittivity and permeability, electric current distribution and magnetic field distribution at resonant peak points, are studied in detail. Analysis shows that the working frequency of this absorber covers entire S, C, X, Ku, K and Ka bands with a minimum thickness of 0.098 λ max (λ max is the maximum wavelength in the absorption band), and the fractional bandwidth (FBW) reaches 181.1%. Moreover, the reflection coefficient is less than −10 dB at 1.998 GHz–40.056 GHz at normal incidence, and the absorptivity of the plane wave is greater than 80% when the incident angle is smaller than 50°. Furthermore, the proposed absorber is experimentally validated, and the experimental results show good agreement with the simulation results, which demonstrates the potential applicability of this absorber at 2 GHz–40 GHz. [ABSTRACT FROM AUTHOR]

Published

2024

24. An intelligent auto-response short message service categorization model using semantic index.

Author

Padmaja, Budi, Bala, Myneni Madhu, Rao Patro, Epili Krishna, Srikruthi, Adiraju Chaya, Avinash, Vytla, and Sudheshna, Chenumalla

Abstract

Short message service (SMS) is one of the quickest and easiest ways used for communication, used by businesses, government organizations, and banks to send short messages to large groups of people. Categorization of SMS under different message types in their inboxes will provide a concise view for receivers. Former studies on the said problem are at the binary level as ham or spam which triggered the masking of specific messages that were useful to the end user but were treated as spam. Further, it is extended with multi labels such as ham, spam, and others which is not sufficient to meet all the necessities of end users. Hence, a multi-class SMS categorization is needed based on the semantics (information) embedded in it. This paper introduces an intelligent auto-response model using a semantic index for categorizing SMS messages into 5 categories: ham, spam, info, transactions, and one time password's, using the multi-layer perceptron (MLP) algorithm. In this approach, each SMS is classified into one of the predefined categories. This experiment was conducted on the "multi-class SMS dataset" with 7,398 messages, which are differentiated into 5 classes. The accuracy obtained from the experiment was 97%. [ABSTRACT FROM AUTHOR]

Published

2024

25. Design of the Miniaturized and Thin Sliced-Type Beam Switching-Controlled Horn Antenna for D-Band

Author

Ming-An Chung, Chia-Wei Lin, and Ing-Peng Meiy

Subjects

Horn, antenna, D-band, beam switching, multi-layer, Electrical engineering. Electronics. Nuclear engineering, TK1-9971

Abstract

This paper proposes a design of a multilayer controlled beam horn antenna for the D-band. The multilayer design can achieve easy to control, low cost, and compact structure. The designed structure achieves the effect of a conventional horn antenna by stacking multiple layers and realizes the effect of beam switching by modifying the multi-layer plate structure. The widest bandwidth can be obtained when stacking 4 layers of boards, covering 24.7% (110-141GHz) of the bandwidth with a simulation gain of approximately 13.5dBi. By replacing the third plate structure, beam switching of ±30 degrees can be achieved, and the gain after beam switching can also reach 11.5 dBi.

Published

2024

26. Metamaterial Broadband Absorber Induced by Synergistic Regulation of Temperature and Electric Field and Its Optical Switching Application

Author

Rundong Yang, Yun Liu, and Xiangfu Wang

Subjects

broadband, bandwidth scalability, multi-layer, dual control, Chemical technology, TP1-1185

Abstract

Nowadays, metamaterial absorbers still suffer from limited bandwidth, poor bandwidth scalability, and insufficient modulation depth. In order to solve this series of problems, we propose a metamaterial absorber based on graphene, VO2, gallium silver sulfide, and gold-silver alloy composites with dual-control modulation of temperature and electric field. Then we further investigate the optical switching performance of this absorber in this work. Our proposed metamaterial absorber has the advantages of broad absorption bandwidth, sufficient modulation depth, and good bandwidth scalability all together. Unlike the single inspired layer of previous designs, we innovatively adopted a multi-layer excitation structure, which can realize the purpose of absorption and bandwidth width regulation by a variety of means. Combined with the finite element analysis method, our proposed metamaterial absorber has excellent bandwidth scalability, which can be tuned from 2.7 THz bandwidth to 12.1 THz bandwidth by external electrothermal excitation. Meanwhile, the metamaterial absorber can also dynamically modulate the absorption from 3.8% to 99.8% at a wide incidence angle over the entire range of polarization angles, suggesting important potential applications in the field of optical switching in the terahertz range.

Published

2024

27. Modulus and stiffness of laterally loaded single free headed pile in stratified soil

Author

S.V. SIVAPRIYA, M. MUTTHARAM, and R. SIVARAJ

Subjects

lateral-load, single-pile, multi-layer, modulus, stiffness ratio, Structural engineering (General), TA630-695

Abstract

Laterally loaded piles gained its attention when structures like transform towers, offshore structures etc., met huge horizontal loads. Initially, to study the behaviour of laterally loaded piles, homogeneous soil is assumed; whereas in reality the soil stratum would be stratified/ multi-layer soil with various consistency and relative density. Considering this real field situation, an 1g experimental investigation is carried out on a single pile embedded in layered soil by varying the number of layers with respect to the length of the pile. With a sand layer on top and in-between, it increases the lateral capacity of the pile. The main soil-structure interaction parameters are modulus and stiffness factor, the modulus of the homogenous sand layer is very high when compared to the clay layer sandwiched between the sand layer.

Published

2023

28. Multi-stable metastructure with multi-layer and multi-degree of freedom: A numerical and experimental investigation

Author

Shuangfeng Tan, Diankun Pan, and Zhangming Wu

Subjects

Multi-stable, Metastructure, Multi-layer, Preshaped Beam, Materials of engineering and construction. Mechanics of materials, TA401-492

Abstract

This paper proposes a family of multi-stable metastructures with multiple layers, which possess the capability of multi-degree of freedom deformations. In its single layer, four preshaped beams connecting two frames are employed as the main component for the design of multi-stable metastructures. Compared with the traditional flat state obtained by axial compression when all beams snap through, four inclined stable states are easy to trigger by lateral compression at a local position when two adjacent beams snap through. The transitions between these states are studied by both experiments and numerical simulation. The transition to inclined states requires less energy than the transition to the flat state. Different trends of load–displacement responses are associated with loading positions and transitions. A parametric analysis is performed to illustrate the relationship between the stability of inclined states and critical parameters, such as span, apex height, and thickness. Two types of hourglass double-layer units are designed and studied through experiments. The continuous transitions in two steps or three steps are observed, and the load–displacement response is the accumulation of responses from each single layer. At last, two multi-layer structures with multi-stability have been developed to demonstrate their deformation capability in multiple directions through multiple steps.

Published

2024

29. A High-gain Low-sidelobe Dual-polarized Broadband Array Antenna.

Author

Qi-Lei Zhou, Bo-Wen Zhang, Neng-Wu Liu, and Guang Fu

Subjects

*ANTENNA arrays, *BROADBAND antennas, *DIRECTIONAL couplers, *ANTENNAS (Electronics), *MICROSTRIP antennas, *STANDING waves

Abstract

In this paper, we present a dual-polarized broadband low side lobe array designed for operation in the Ku-band. The antenna array operates within the frequency range of 14.0 GHz to 15.2 GHz, covering a bandwidth of over 8%. To realize this wide operational frequency, we have selected broadband microstrip antenna elements as the units of the array. In order to fulfill the demanding criteria of broadband performance and low sidelobe characteristics, we introduce a broadband low-sidelobe feeding network based on a directional coupler design. This feeding network ensures connectivity with the antenna units, resulting in a voltage standing wave ratio (VSWR) < 2 within the 14.0 GHz to 15.2 GHz frequency range. Furthermore, our antenna array achieves an array gain exceeding 21 dBi and keeps array sidelobes below -20 dB across the entire operating frequency band. Our research breakthrough addresses the critical design challenge of creating large-scale array antennas that combine broadband capabilities with high gain and minimal sidelobe interference. [ABSTRACT FROM AUTHOR]

Published

2024

30. 3D progressive damage analysis of a unidirectional multi-layered composite for mechanical joints.

Author

Kabiri Ataabadi, Abdulreza, Mesripour, Sattar, Moshref-Javadi, Mehrshad, and Ahmadi Jeyed, Ghadir

Subjects

*COMPOSITE plates, *FAILURE mode & effects analysis, *COMPOSITE structures, *BEHAVIORAL assessment

Abstract

Due to the presence of holes in composite mechanical joints, stresses around the holes are increased, and they may cause failure in the composites. Analysis of the composite behaviour after damage initiation around the holes is important, complex, and mostly three-dimensional. In order to achieve accurate results about the composite failure modes, damage analysis using a modern criterion is needed. In this research, to investigate the damage behaviour of a unidirectional multi-layered composite plate of a mechanical joint under pure tension, three codes are prepared in the USDFLD, VUSDFLD and VUMAT subroutines based on the Hashin criterion and implemented in ABAQUS software. These codes, using the methods of suddenly and gradually degradation in composite properties, progressively simulate the three-dimensional damage behaviour of the composite plate after damage initiation. The results show that, when a mechanical joint is under pure tension, the adequate distance from the edge of a hole to the edge of a composite plate is about two times the hole diameter. Furthermore, it is found that to rapidly investigate and analyse a mechanical joint in the composite structures, the USDFLD subroutine, which uses suddenly decreased material properties after damage initiation, is reasonable and more efficient. [ABSTRACT FROM AUTHOR]

Published

2023

31. Guided Wave Characteristic Research and Probabilistic Crack Evaluation in Complex Multi-Layer Stringer Splice Joint Structure.

Author

Chen, Jian, Xu, Yusen, Yuan, Shenfang, and Qin, Zhen

Subjects

*STANDARD deviations, *STRUCTURAL health monitoring, *THEORY of wave motion, *GAUSSIAN processes

Abstract

Multi-layer and multi-rivet connection structures are critical components in the structural integrity of a commercial aircraft, in which elements like skin, splice plate, strengthen patch, and stringer are fastened together layer by layer with multiple rows of rivets for assembling the fuselage and wings. Their non-detachability and inaccessibility pose significant challenges for assessing their health states. Guided wave-based structural health monitoring (SHM) has shown great potential for on-line damage monitoring in hidden structural elements. However, the multi-layer and multi-rivet features introduce complex boundary conditions for guided wave propagation and sensor layouts. Few studies have discussed the guided wave characteristic and damage diagnosis in multi-layer and multi-rivet connection structures. This paper comprehensively researches guided wave propagation characteristics in the multi-layer stringer splice joint (MLSSJ) structure through experiments and numerical simulations for the first time, consequently developing sensor layout rules for such complex structures. Moreover, a Gaussian process (GP)-based probabilistic mining diagnosis method with path-wave band features is proposed. Experiments on a batch of MLSSJ specimens are performed for validation, in which increasing crack lengths are set in each specimen. The results indicate the effectiveness of the proposed probabilistic evaluation method. The maximum root mean squared error of the GP quantitative diagnosis is 1.5 mm. [ABSTRACT FROM AUTHOR]

Published

2023

32. Design and Finite Element Analysis of a 6/4 Pole Multi-Layer Fully Pitched Switched Reluctance Motor to Reduce Torque Ripple.

Author

Sahin, Cihan and Basaran, Sinan

Subjects

*RELUCTANCE motors, *SWITCHED reluctance motors, *ELECTRIC torque motors, *SUBMERSIBLE pumps, *FINITE element method, *AMPERES

Abstract

—In this study, the design and analysis of multi-layer fully pitched winding switched reluctance motor (MFP-SRM) for general use (submersible pump, electric vehicles, etc.) have been performed. It is seen that the multi-layer switched reluctance motor (SRM) has higher output power when compared to the single-layer SRM. In multi-layer SRM, the motors in the layers are electromagnetically independent of each other although they are identically the same motors with the same characteristics in terms of performance and geometry. Each layer of the MFP-SRM which is designed in this study consists of a 6/4 pole fully pitched SRM (FP-SRM) and these motors are magnetically independent of each other. In the MFP-SRM, which is designed as a double layer, there is a 15° phase difference between the rotor position angles and torque profile curves of each layer. With the phase difference that changes depending on the number of layers, each layer contributes to the total torque production of the profile, ensuring a smooth profile. According to the results of the 3D FEM analysis, it is seen that the proposed multi-layer motor structure has high starting torque and low torque ripple properties. In the analysis carried out in the range of 3–15 Amperes, the torque ripple of the traditional FP-SRM varies between 31.99% and 38.19%, while the torque ripple of the proposed MFP-SRM only varies between 3.23% and 7.11%. [ABSTRACT FROM AUTHOR]

Published

2023

33. Numerical investigation on the process of obstructing granular flow by multi-layer rigid netting barriers.

Author

Fan, Yunyun, Su, Siqi, Zhang, Fang, and Wu, Fengyuan

Subjects

*GRANULAR flow, *DISCRETE element method, *NUMERICAL calculations, *IMPACT loads

Abstract

Multi-layer rigid netting barriers (RNBs) can obstruct the granular flow layer by layer, and all the layers of the structures share the impact load, which has better reliability than single-layer structure. However, the granular flow obstructed by multi-layer RNBs is complicated. The grains between the layers of RNBs may make the forces acting on all structures related to each other. Under the limited testing conditions, it is difficult to obtain several important information such as the obstruction efficiency of structural barriers and the impact forces acting on the RNBs at all layers. In this study, the discrete element method is used to numerically simulate a typical granular flow experiment. Based on the numerical verification, the method was used to study the mechanical characteristics of the RNBs at all layers and the typical process of granular flow under different settings. The results show that the numerical calculation can not only simulate the rebound, run-up, splash, passing-through and other movements of grains during the obstruction process, but also obtain the mechanical characteristics of the RNBs at all layers that are related to each other caused by the grains between the RNBs, and the final deposition of grains in front of the RNBs. The mesh and position settings of the protective structures have a significant influence on the forces acting on the RNBs at all layers, so adjusting the RNB settings through numerical optimization can make the forces on RNBs more reasonable and optimize the design of the protective structures. At the same time, the grain segregation characteristics in front of the RNBs obtained by the numerical simulation can provide a basis for further research on the physical and mechanical characteristics and the stability of the deposition. [ABSTRACT FROM AUTHOR]

Published

2023

34. Spectral- and spatial-based multi-focus image fusion method towards multi-layer nonwovens.

Author

Zhu, Mengqiu, Yu, Lingjie, Sun, Runjun, Ke, Zhenxia, Zhou, Youyong, Wang, Shuai, and Zhi, Chao

Subjects

IMAGE fusion, CONVOLUTIONAL neural networks, VISUAL perception, NONWOVEN textiles

Abstract

In the microscopic imaging scenario where the object thickness exceeds the depth of field of the microscope, multi-focus image fusion (MFF) is an effective method to generate an all-in-focus image. However, for nonwoven fabric for which the captured image number is up to 100 or more, the existing methods often underperform in areas near the fiber edges, owing to image ghosting and noise accumulation caused by the platform moving. To address the above problem, this paper presents a method designed to fuse multi-layer micro-images based on the combination of spectral and spatial features of the images. Firstly, the spectral domain-based map is generated by decomposition and reconstruction of the high-frequency and low-frequency components of the images, aimed at obtaining the edge information. Simultaneously, the spatial domain-based fuse map is built through sharpness measurement, referring to visual perception. Finally, the two methods are combined via an optimized weight to obtain an all-in-focus fused image. Four groups of real-world data consisting of 100 multi-focus nonwoven images are utilized to verify the superiority of this method. The experimental results demonstrate that the proposed method can obtain satisfactory performance in terms of both human visual evaluation and objective evaluation compared with the image fusion framework based on the convolutional neural network, MFF, region-based image fusion algorithm and convolutional neural network state-of-the-art fusion methods. [ABSTRACT FROM AUTHOR]

Published

2023

35. A Multi-layer Optimization Scheduling Model for Active Distribution Network Based on Consistency Constraint

Author

Liu, Yang, Zhang, Shidong, Li, Lisheng, Wang, Shaorui, Lu, Tianguang, Yu, Haidong, Liu, Wenbin, Angrisani, Leopoldo, Series Editor, Arteaga, Marco, Series Editor, Panigrahi, Bijaya Ketan, Series Editor, Chakraborty, Samarjit, Series Editor, Chen, Jiming, Series Editor, Chen, Shanben, Series Editor, Chen, Tan Kay, Series Editor, Dillmann, Rüdiger, Series Editor, Ferrari, Gianluigi, Series Editor, Duan, Haibin, Series Editor, Ferre, Manuel, Series Editor, Hirche, Sandra, Series Editor, Jabbari, Faryar, Series Editor, Jia, Limin, Series Editor, Kacprzyk, Janusz, Series Editor, Khamis, Alaa, Series Editor, Kroeger, Torsten, Series Editor, Li, Yong, Series Editor, Liang, Qilian, Series Editor, Martín, Ferran, Series Editor, Ming, Tan Cher, Series Editor, Minker, Wolfgang, Series Editor, Misra, Pradeep, Series Editor, Möller, Sebastian, Series Editor, Mukhopadhyay, Subhas, Series Editor, Ning, Cun-Zheng, Series Editor, Nishida, Toyoaki, Series Editor, Oneto, Luca, Series Editor, Pascucci, Federica, Series Editor, Qin, Yong, Series Editor, Seng, Gan Woon, Series Editor, Speidel, Joachim, Series Editor, Veiga, Germano, Series Editor, Wu, Haitao, Series Editor, Zamboni, Walter, Series Editor, Zhang, Junjie James, Series Editor, Cao, Wenping, editor, Hu, Cungang, editor, and Chen, Xiangping, editor

Published

2023

36. Impact of varying lactate concentration in sweat on thermo-physiological comfort of multi-layered ensembles

Author

Preet, Agya, Mukhopadhyay, Arunangshu, and Midha, Vinay Kumar

Published

2023

37. Development and Fabrication of a Multi-Layer Planar Solar Light Absorber Achieving High Absorptivity and Ultra-Wideband Response from Visible Light to Infrared

Author

Cheng-Fu Yang, Chih-Hsuan Wang, Pei-Xiu Ke, Teen-Hang Meen, and Kuei-Kuei Lai

Subjects

multi-layer, planar, solar light, absorber, evaporation technique, focused ion beam (FIB), Chemistry, QD1-999

Abstract

The objective of this study is to create a planar solar light absorber that exhibits exceptional absorption characteristics spanning from visible light to infrared across an ultra-wide spectral range. The eight layered structures of the absorber, from top to bottom, consisted of Al2O3, Ti, Al2O3, Ti, Al2O3, Ni, Al2O3, and Al. The COMSOL Multiphysics® simulation software (version 6.0) was utilized to construct the absorber model and perform simulation analyses. The first significant finding of this study is that as compared to absorbers featuring seven-layered structures (excluding the top Al2O3 layer) or using TiO2 or SiO2 layers as substituted for Al2O3 layer, the presence of the top Al2O3 layer demonstrated superior anti-reflection properties. Another noteworthy finding was that the top Al2O3 layer provided better impedance matching compared to scenarios where it was absent or replaced with TiO2 or SiO2 layers, enhancing the absorber’s overall efficiency. Consequently, across the ultra-wideband spectrum spanning 350 to 1970 nm, the average absorptivity reached an impressive 96.76%. One significant novelty of this study was the utilization of various top-layer materials to assess the absorption and reflection spectra, along with the optical-impedance-matching properties of the designed absorber. Another notable contribution was the successful implementation of evaporation techniques for depositing and manufacturing this optimized absorber. A further innovation involved the use of transmission electron microscopy to observe the thickness of each deposition layer. Subsequently, the simulated and calculated absorption spectra of solar energy across the AM1.5 spectrum for both the designed and fabricated absorbers were compared, demonstrating a match between the measured and simulated results.

Published

2024

38. Uncovering the peel strength performance of multi-layer ultrasonic weld seams in PVC-coated hybrid textiles for weather protection

Author

Muktar Seid Hussen, Yordan Kyosev, Kathrin Pietsch, Tilo Pilling, Jessica Boll, and Abera Kechi Kabish

Subjects

Ultrasonic welding, Process parameter, Multi-layer, Peel strength, Numerical optimization, Analytical model, Materials of engineering and construction. Mechanics of materials, TA401-492

Abstract

Ultrasonic welding is a fast and efficient solid-state welding process widely used in various industries. This study focuses on optimizing seam quality and peel strength in multi-layered hybrid textile materials using continuous ultrasonic welding. The influence of welding process parameters (pressure force, power, and speed) on multi-layered peel strength is examined. Three-by-three experimental designs for two and three-layer weld seams with 6 and 12 mm welding widths were developed and applied using superimposed seam type. The impact of varied factors on multi-layered peel strength was analyzed statistically and explored their corresponding tendencies in the relationships. Numerical optimization and analytical models were used to determine parametric levels for achieving desired peel strength. The results show that peel strength is affected by welding parameters, with variations observed based on layer, width, and speed. Increasing speed reduces peel strength, while higher power and pressure force enhance peel strength up to a certain point. However, excessive power and pressure forces can cause material deformation and reduce peel strength. The study also found a strong correlation between power and peel strength, emphasizing the importance of energy input during welding. Power and speed are identified as significant determinants of peel strength, with their combined influence playing a crucial role. The optimal peel strength (34.86 N/12 mm) is achieved at a welding speed of 2.11 m/min, power of 118.18 W, and pressure force of 343.94 N for a three-layer weld seam with a 12 mm welding width. Nonlinear quadratic analytical models are developed to predict multi-layered peel strength, and their results align closely with the actual points. Overall, this research provides valuable insights into optimizing seam quality and peel strength for multi-layered hybrid textile materials, benefiting weather protection applications and advancing bonding techniques in ultrasonic welding.

Published

2023

39. The optimization of thermal insulation-related properties of polysaccharide-based aerogel by the multi-layer combination method.

Author

Wu, Kao, Wang, Ru, Ye, Zijian, Tao, Yuxuan, Wu, Huaxin, Sun, Weiwei, Cheng, Junjie, Kuang, Ying, Jiang, Fatang, and Chen, Sheng

Abstract

The development of polysaccharide-based biodegradable thermal insulation aerogels benefited environmental protection. The thermal conductivity of polysaccharide-based aerogels prepared by the freeze-drying method was difficult to reduce to less than 0.3 W/(m·k), as the pore size was relatively large. Therefore, rather than reducing pore size, this study aimed to reduce the airflow/heat convection inside the aerogels by introducing aerogels with different air permeability as outer layers to combine dual-layer/triple-layer aerogels with lower thermal conductivity. Results showed that the triple-layer method had a more significant impact on reducing the thermal conductivity than the dual-layer method, due to the greater impact on reducing the airflow. Additionally, a thinner thickness of outer aerogel layers was preferred, and the thermal conductivity was significantly reduced to 0.0279 W/(m·k) from 0.0335 W/(m·k) by the triple-layer aerogel method. The thermal insulation stability of this triple-layer aerogel was also relatively high, and the hardness and resistance to relative humidity were both improved compared to the original aerogel. Considering the above, this triple-layer aerogel method could be used to improve the thermal insulation-related property of the polysaccharide-based aerogels by the freeze-drying method or with relatively large pore sizes. [ABSTRACT FROM AUTHOR]

Published

2023

40. Scalable, Patternable Glass‐Infiltrated Ceramic Radiative Coolers for Energy‐Saving Architectural Applications.

Author

Jeon, Seung Kyu, Kim, June Tae, Kim, Min Seong, Kim, In Soo, Park, Sung Jin, Jeong, Hyeondeok, Lee, Gil Ju, and Kim, Yeong Jae

Subjects

*THERMAL insulation, *WINDOW shades, *CERAMICS, *ENERGY shortages, *HIGH temperatures, *COOLING, *THICK films, *CO-combustion

Abstract

A huge concern on global climate/energy crises has triggered intense development of radiative coolers (RCs), which are promising green‐cooling technologies. The continuous efforts on RCs have fast‐tracked notable energy‐savings by minimizing solar absorption and maximizing thermal emission. Recently, in addition to spectral optimization, ceramic‐based thermally insulative RCs are reported to improve thermoregulation by suppressing heat gain from the surroundings. However, a high temperature co‐firing process of ceramic‐based thick film inevitably results in a large mismatch of structural parameters between designed and fabricated components, thereby breaking spectral optimization. Here, this article proposes a scalable, non‐shrinkable, patternable, and thermally insulative ceramic RC (SNPT‐RC) using a roll‐to‐roll process, which can fill a vital niche in the field of radiative cooling. A stand‐alone SNPT‐RC exhibits excellent thermal insulation (≈0.251 W m−1 K−1) with flame‐resistivity and high solar reflectance/long‐wave emissivity (≈96% and 92%, respectively). Alternate stacks of intermediate porous alumina/borosilicate (Al2O3‐BS) layers not only result in outstanding thermal and spectral characteristics, causing excellent sub‐ambient cooling (i.e., 7.05 °C cooling), but also non‐shrinkable feature. Moreover, a perforated SNPT‐RC demonstrates its versatility as a breathable radiative cooling shade and as a semi‐transparent window, making it a highly promising technology for practical deployment in energy‐saving architecture. [ABSTRACT FROM AUTHOR]

Published

2023

41. Compact Substrate Integrated Waveguide Wideband Bandpass Filter With Post-Manufacturing Tuning Capabilities

Author

El Mehdi Messaoudi, Jorge Daniel Martinez Perez, and Vicente E. Boria

Subjects

Substrate integrated waveguide (SIW), miniaturization, multi-layer, wideband, transmission zero, mixed coupling, Electrical engineering. Electronics. Nuclear engineering, TK1-9971

Abstract

In this paper, a miniaturized wideband bandpass filter in coaxial substrate integrated waveguide (SIW) technology is presented. To improve the response selectivity and coupling control, a multi-layer structure has been implemented, introducing both strong magnetic and electric couplings. To reduce the physical size of the device, surfaced-mounted device (SMD) capacitors have been integrated on the top layer. These allow both resonant frequency and capacitive coupling level control. Thus, a 4-th order Chebyshev filter with an absolute bandwidth (BW) of 2.9 GHz centered at 5.35 GHz has been designed, fabricated and measured. An extremely small filter size of $7 \times 7$ ,mm2 has been obtained. A study of manufacturing tolerances are also presented in this paper, together with a post-manufacturing response correction allowed by the SMD elements. As it is shown in the paper, the filter’s out-of-band rejection can be easily enhanced by introducing additional transmission zeros (TZs).

Published

2023

42. Three-dimensionally reconfigurable focusing of laser by mechanically tunable metalens doublet with built-in holograms for alignment

Author

Jung Joonkyo, Kim Hyeonhee, and Shin Jonghwa

Subjects

alignment, hologram, metalens, multi-layer, varifocal, Physics, QC1-999

Abstract

Metalenses have potential to replace various bulky conventional optical elements with ultrathin nanostructure arrays. In particular, active metalenses with reconfigurable focusing capability have attracted considerable interest from the academic and industrial communities. However, their tuning range is currently restricted by limited material properties and fabrication difficulties. Here, a hybrid optical system capable of three-dimensional relocation of a focal spot is proposed and experimentally demonstrated. The system comprises a mechanically actuated passive metalens doublet that can be easily fabricated with commonly available materials and processes. An incident laser can be focused to a desired point in three-dimensional space simply by rotating two metalenses or changing their separation. In addition, exploiting the polarization-multiplexing capability of metasurfaces, a hologram is incorporated to the metalenses to guide rotational and positional alignment of two metasurfaces. The ease of fabrication and alignment provided by this approach could widen its application to many practical fields.

Published

2023

43. Introduced the ITGB1-DT as a novel biomarker associated with five potential drugs using bioinformatics analysis of breast cancer proteomics data and RT-PCR

Author

Zahra Yousefian naeini, Negin Esfandiari, Mehrdad Hashemi, Kiavash Hushmandi, Sedighe Arbabian, and Maliheh Entezari

Subjects

Proteomics, Breast cancer, Systems biology, Multi-layer, ITGB1-DT, Firategrast, Biology (General), QH301-705.5, Medicine

Abstract

Background: Breast cancer (BC) has been identified as a significant contributor to the rising number of female cancer deaths. As, it has become clear that breast cancer development depends on the interplay of several biological factors against a single molecule. This research aimed to use proteomics to gain a regulatory and metabolic understanding of BC pathophysiology. Method: For the study, a breast cancer proteomics dataset was downloaded from ProteomeXchange and then analyzed by employing MaxQuant and Perseus. Functional enrichment analysis through Metascape and Cytoscape software showed DEPs related biomedical phenomena with potential abruption. The expression of selected lncRNA in terms of the highest connectivity parameters was then quantitatively assessed through RT-PCR in 30 tumor tissues of breast cancer patients, as compared to the adjacent healthy ones. Result: The results indicated that among the 3048 identified proteins, 1149 were differentially expressed, which could be mainly enriched in several key terms. Furthermore, the obtained findings revealed that ITGB1-DT was significantly overexpressed in tumor tissues. Moreover, we found five potential compounds that could be attributed to ITGB1-DT targets (ATN-161, Firategrast, SB-683698, dabigatran-etexilate, and tranexamic-acid). Conclusion: These analyses proposed that ITGB1-DT could be employed as a differentiated factor to identify breast tumor tissues in healthy samples. Besides this, Firategrast could be introduced as a potential remedial agent for breast cancer patients. Overall, from the analysis of a proteomics dataset, an integrative map was generated, and a novel biomarker that may have been implicated in the early detection of BC was introduced.

Published

2023

44. Tunable Drug Release Rate Using Modular Oral Dosage Forms.

Author

Cano-Vega, Mario A., Arango-Salazar, Laura M., and Pinal, Rodolfo

Subjects

*DOSAGE forms of drugs, *PROGESTERONE antagonists, *DRUG solubility, *DRUG bioavailability

Abstract

Oral dosage forms with adjustable drug release profiles were prepared using progesterone (PGR) as a poorly-soluble model drug. The dosage forms were made as stack assemblies of functional modules. The modules were made as PGR-carrying HPMC films cut into wafer-like circular pieces. Two types of modules were used in the study; one exhibited comparatively fast drug release and the other slow release. The fast vs. slow release of each type of film utilized resulted from the grade of HPMC used in each case. Drug loading in the assembly was controlled through the total number of modules. By adjusting the proportions of the two types of modules, it is possible to fine-tune the drug release rate of the multi-layer assemblies to a wide range of profiles, bracketed between a high and low end, corresponding to the inherently fastest or slowest release obtainable with the specific materials and procedures employed. This procedure is suitable for adjusting the spring-and-parachute parameters for enhancing/optimizing the bioavailability of poorly-soluble drugs, and for developing patient-centric formulations. [ABSTRACT FROM AUTHOR]

Published

2023

45. A multi-layer network security system to enhance autonomous mobile carrier in smart manufacturing system.

Author

Syue, Jia-Hong and Chen, Shang-Liang

Abstract

Nowadays, wireless communication technology is widely used and accepted by industry to improve the flexibility and efficiency of smart factories. The Wi-Fi 6 high-speed communication technology is integrated into the autonomous mobile carrier (AMC) in this research to make it possible for interacting with many other machines at the same time with high transmission speed, high reliability, and low packet loss ratio. The indoor positioning accuracy of autonomous mobile carrier is enhanced by Ultra-wideband (UWB) technology, so that it can then move and complete multi-station automation processing tasks more smoothly. Finally, a multi-layer network system with security function to protect all the equipment in the manufacturing environment is proposed and developed in this research. The threats that may come with the use of wireless network technology can then be avoided. In this research, an overall system framework with multi-layer network security mechanism is developed and introduced into the autonomous mobile carrier, and the enhanced autonomous mobile carrier is applied into a manufacturing field for performance test. The results show that the enhanced autonomous mobile carrier can maintain positioning accuracy within ±100 mm, wireless network packet transmission latency rate less than 5 ms, and wireless network packet transmission loss rate less than 1%. It shows that this autonomous mobile carrier system benefits from UWB and Wi-fi 6 communication technology and has a very high potential for realizing smart manufacturing applications. [ABSTRACT FROM AUTHOR]

Published

2023

46. Multi-Layered Bipolar Ionic Diode Working in Broad Range Ion Concentration.

Author

Kim, Jaehyun, Wang, Cong, and Park, Jungyul

Subjects

DIODES, SOFT lithography, HYSTERESIS loop, MEMRISTORS, OSMOTIC pressure, IONS, SOFT X rays

Abstract

Ion current rectification (ICR) is the ratio of ion current by forward bias to backward bias and is a critical indicator of diode performance. In previous studies, there have been many attempts to improve the performance of this ICR, but there is the intrinsic problem for geometric changes that induce ionic rectification due to fabrication problems. Additionally, the high ICR could be achieved in the narrow salt concentration range only. Here, we propose a multi-layered bipolar ionic diode based on an asymmetric nanochannel network membrane (NCNM), which is realized by soft lithography and self-assembly of homogenous-sized nanoparticles. Owing to the freely changeable geometry based on soft lithography, the ICR performance can be explored according to the variation of microchannel shape. The presented diode with multi-layered configuration shows strong ICR performance, and in a broad range of salt concentrations (0.1 mM~100 mM), steady ICR performance. It is interesting to note that when each anion-selective (AS) and cation-selective (CS) NCNM volume was similar to each optimized volume in a single-layered device, the maximum ICR was obtained. Multi-physics simulation, which reveals greater ionic concentration at the bipolar diode junction under forward bias and less depletion under backward in comparison to the single-layer scenario, supports this tendency as well. Additionally, under different frequencies and salt concentrations, a large-area hysteresis loop emerges, which indicates fascinating potential for electroosmotic pumps, memristors, biosensors, etc. [ABSTRACT FROM AUTHOR]

Published

2023

47. Resistive Multi-Gas Sensor for Simultaneously Measuring the Oxygen Stoichiometry (λ) and the NO x Concentration in Exhausts: Engine Tests under Dynamic Conditions.

Author

Steiner, Carsten, Wöhrl, Thomas, Steiner, Monika, Kita, Jaroslaw, Müller, Andreas, Eisazadeh, Hessam, Moos, Ralf, and Hagen, Gunter

Subjects

*OXYGEN detectors, *ENGINE testing, *DIESEL motor exhaust gas, *DYNAMIC testing, *WASTE gases, *STOICHIOMETRY, *OXYGEN

Abstract

Due to increasingly stringent limits for NOx emissions, there is now more interest than ever in cost-effective, precise, and durable exhaust gas sensor technology for combustion processes. This study presents a novel multi-gas sensor with resistive sensing principles for the determination of oxygen stoichiometry and NOx concentration in the exhaust gas of a diesel engine (OM 651). A screen-printed porous KMnO4/La-Al2O3 film is used as the NOx sensitive film, while a dense ceramic BFAT (BaFe0.74Ta0.25Al0.01O3–δ) film prepared by the PAD method is used for λ-measurement in real exhaust gas. The latter is also used to correct the O2 cross-sensitivity of the NOx sensitive film. This study presents results under dynamic conditions during an NEDC (new European driving cycle) based on a prior characterization of the sensor films in an isolated sensor chamber with static engine operation. The low-cost sensor is analyzed in a wide operation field and its potential for real exhaust gas applications is evaluated. The results are promising and, all in all, comparable with established, but usually more expensive, exhaust gas sensors. [ABSTRACT FROM AUTHOR]

Published

2023

48. Mechanical Properties of Multi-Layer Woven E-Glass/Epoxy in Variable Fiber-Mat Directions.

Author

H., Saif Aldeen Ghafel, Namer, Nasri Salh M., and Ali, Abdul Jabbar H.

Subjects

EPOXY resins, MULTILAYERS, COMPOSITE materials, YOUNG'S modulus, HARDNESS testing

Abstract

In this research, the epoxy resin was reinforced by (16 layers) of E-glass fiber woven mat (0^°/90^°) with 50% weight fraction and total thickness (3mm). Using 16 layers was due to the absence of any previous study that used this number of layers at this thickness. It is considered a modern study of this style because of the rapid development in modern engineering industries that required lightweight composite materials with high strength and small thickness, which are used in the aerospace industry aviation and other precision engineering industries. The composite material was cut into angles (0^°,5^°,15^°,30^°,45^°) by using CNC water jet culling machine. The tensile test was used to determine the strength of a material ratio to the fiber's direction and by using Vickers hardness to determine the hardness of composite and pure epoxy. The result of pure epoxy (matrix) has the lowest value in tensile strength (σ_UTS), Yong's modulus (E), 0.2% proof yield stress (σ_(0.2%)), modulus of toughness and toughness when compared with a composite material with adding 16 layers of "E-glass fibers". The direction of the fibers with (5^°) of composite has the highest strength, Young's modulus, and 0.2% proof yield stress when compared with (0^°,15^°,30^°,45^°) and pure epoxy. The improvement strength (10.8, 11.8, 9.8, 8.5, 8.3 times) at (0^°,5^°,15^°,30^°,45^°) respectively when compared with pure epoxy. The hardness of composite material improved (220%) relative to pure epoxy. The results show that the best improvement of composite material with fiber's angle (5^°) has the highest results compared with pure epoxy. [ABSTRACT FROM AUTHOR]

Published

2023

49. An optimized and area-efficient QCA-based subtractor with easy access to input and output: design and cost estimation.

Author

Hu, Shengqiang

Abstract

Quantum-dot Cellular Automata (QCA) is a novel computational paradigm in nanotechnology with some benefits, such as low energy usage, rapid speed, and high density. Several logical circuits have been examined in this nanotechnology, but subtractors with easy access to inputs and outputs cells are not explored thoroughly. Due to the lack of easy access to inputs and outputs, the previous designs are less expandable and cannot be easily used in other circuits. Subtractors are often executed within a binary adder when using the traditional two's complement notation at just a small computational cost by providing an addition/subtraction selector to the carry-in and inverting the second operand. The same methodology as for adder's circuit can be used to create a subtractor, a digital circuit in nanoelectronics that performs numerical subtraction. Consequently, it is necessary to construct this circuit so that the inlets and outlets are simple to access. Therefore, a new QCA-based subtractor design is suggested in the present investigation. The scheme is then assessed and compared to state-of-the-art designs. This design offers a solution to the problem of access to input and output for data exchange in QCA. The suggested plan uses the least amount of space, the fewest number of cells, and delay three-layer crossing approaches as compared to the existing QCA design. The suggested subtractor needs 25 cells and takes up 0.01 µm2. The QCADesigner tool provides this circuit's simulation results and confirms the suggested circuit's exactification. The suggested circuit is among the best regarding the area, cell counts, and quantum costs. [ABSTRACT FROM AUTHOR]

Published

2023

50. Development of a multi-layer cylindrical rotating electret generator with increased power densit.

Author

Yongling Lu, Zhen Wang, Xueqiong Zhu, Ziquan Liu, Hai Xue, and Ziyang Zhang

Subjects

*ELECTROSTATIC accelerators, *POWER density

Abstract

Electrostatic electret generator has attracted a lot of attention in recent years, but their low power density cannot be ignored. Based on the existing research, this paper increases its power density from two aspects, including in-plane and in-space aspects. In the plane aspect, through simulation analysis, we can draw a conclusion that the output power can be increased effectively by using the bipolar charging method. From the perspective of space, the power density can be increased several times by connecting the output ends of the multi-layer generation structure. By integrating the method into the electrostatic electret generator, the power output can be effectively increased, which is suitable to the application of higher energy requirements in the specific field and a certain application prospect. [ABSTRACT FROM AUTHOR]

Published

2023