Your search keyword '"Modulus"' showing total 49,919 results

1. Approach to Assess As-Built Moduli of Compacted Foundation Layers Using Intelligent Compaction

Author

Zuniga, Isaac Esteban, Tirado, Cesar, Nazarian, Soheil, Chang, George K., di Prisco, Marco, Series Editor, Chen, Sheng-Hong, Series Editor, Vayas, Ioannis, Series Editor, Kumar Shukla, Sanjay, Series Editor, Sharma, Anuj, Series Editor, Kumar, Nagesh, Series Editor, Wang, Chien Ming, Series Editor, Cui, Zhen-Dong, Series Editor, Lu, Xinzheng, Series Editor, Rujikiatkamjorn, Cholachat, editor, Xue, Jianfeng, editor, and Indraratna, Buddhima, editor

Published

2025

2. Evaluating Mechanical Properties of Lightweight Cellular Concrete Backfill with Dynamic Cone Penetration Tests.

Author

Ye, Yu-Qiu, Han, Jie, Dolton, Brad, Liu, Hao, and Parsons, Robert L.

Subjects

*AIR-entrained concrete, *CONE penetration tests, *LIGHTWEIGHT concrete, *CONSTRUCTION projects, *COMPRESSIVE strength

Abstract

Dynamic cone penetrometer (DCP) has been commonly used for the evaluation and quality control/assurance of soils before, during, and after construction in civil engineering projects. This test equipment has been increasingly used for geotechnical engineering applications but not yet been used to evaluate lightweight cellular concrete (LCC) as a backfill material. This technical note reports laboratory and field DCP tests to evaluate the properties of LCC. To establish the relationship between DCP data and other material properties, unconfined compressive strength and California bearing ratio (CBR) tests were conducted on this material. The test results showed that the measured unconfined compressive strength and CBR of LCC increased as its density increased. The DCP indices (DCPI) for the LCC specimens at different densities were almost constant with the penetration depth. This technical note proposes the correlations between the DCPI and the unconfined compressive strength and CBR, which may be used for future applications. [ABSTRACT FROM AUTHOR]

Published

2024

3. Existence and Uniqueness of Limits at Infinity for Bounded Variation Functions.

Author

Lahti, Panu and Nguyen, Khanh

Abstract

In this paper, we study the existence of limits at infinity along almost every infinite curve for the upper and lower approximate limits of bounded variation functions on complete unbounded metric measure spaces. We prove that if the measure is doubling and supports a 1-Poincaré inequality, then for every bounded variation function f and for 1-a.e. infinite curve γ , for both the upper approximate limit f ∨ and the lower approximate limit f ∧ we have that lim t → + ∞ f ∨ (γ (t)) and lim t → + ∞ f ∧ (γ (t)) exist and are equal to the same finite value. We give examples showing that the conditions of the doubling property of the measure and a 1-Poincaré inequality are needed for the existence of limits. Furthermore, we establish a characterization for strictly positive 1-modulus of the family of all infinite curves in terms of bounded variation functions. These generalize results for Sobolev functions given in Koskela and Nguyen (J Funct Anal 285(11):110154, 2023). [ABSTRACT FROM AUTHOR]

Published

2024

4. Electrical conductivity and relaxation mechanisms of nanocrystalline Ba0.75Ca0.2Cs0.05TiO3.

Author

Hellara, J., Amara, Manel, Dhahri, A., and Dhahri, J.

Subjects

*RANDOM access memory, *ELECTRIC conductivity, *BARIUM titanate, *LEAD-free ceramics, *ELECTRONIC equipment

Abstract

Ca and Cs doped barium titanate lead-free ceramic with the formula Ba 0.75 Ca 0.2 Cs 0.05 TiO 3 has been prepared by the solid-state reaction method. X-ray diffraction (XRD) confirms the crystallization of the sample in a tetragonal structure with a P 4 mm space group. The phase purity and grain morphology were evaluated using X-ray diffraction and scanning electron microscopy (SEM). The material exhibits a primary phase of Ba0.75Ca0.2Cs0.05TiO3 with a minor secondary phase of BaO 2 , and the average grain size is determined to be 1.66 μm. Using non-destructive complex impedance spectroscopy (CIS), we extensively studied the electrical behavior, including complex impedance (Z*), complex modulus (M*), electrical conductivity, and relaxation mechanisms, of Ba 0.75 Ca 0.2 Cs 0.05 TiO 3 over a wide temperature (85 K–290 K) and frequency range. The ac conductivity analysis reveals that the dominant conduction mechanism is the non-overlapping small polaron tunneling (NSPT) model. The impedance analysis indicates a single semi-circle in the real and imaginary parts, suggesting a single relaxation mechanism. Additionally, the activation energy was calculated to be approximately 0.0489 eV. These findings contribute to the understanding of the structural and electrical properties of Ba 0.75 Ca 0.2 Cs 0.05 TiO 3 , highlighting its potential applications in electronic devices such as capacitors, thermistors, and ferroelectric random access memories (FRAMs). [ABSTRACT FROM AUTHOR]

Published

2024

5. Polaron hopping conduction at near morphotropic phase boundary by dilute magnetic ions in ferroelectric materials.

Author

Rao, T. Lakshmana, Dash, S., and Ramakrishna, P. V.

Subjects

*MORPHOTROPIC phase boundaries, *BAND gaps, *ELECTRIC impedance, *MAGNETIC ions, *JUMP processes

Abstract

Ferroelectric (FE) materials and their advancements have piqued the scientific community's interest greatly since they provide numerous fascinating processes in addition to being used in devices. Among them, we have studied Mn and Sn co-doped PZT and Pb (Zr0.52Ti0.48) O3 as PZT, an extremely intriguing FE. The structure and phase purity of all the samples are determined by x-ray diffraction techniques. All the samples show a very good microstructures and the average grain size is found to be decreased with ion incorporation. The UV-Vis spectra show how doping reduces optical band gaps. Parallel resistance (R)-capacitance (C) circuits have been used to analyze the relationship between microstructure and electrical characteristics. The microscopic processes in various PZT samples with dilute magnetic cations at A-sites, B-sites, and/or both sites at the morphotopic phase boundary are established from the detail impedance, modulus, and ac conductivity of the samples as a function of temperature (300 –500 °C) and over a range of frequency (100 Hz to 1 MHz). Additionally, the framework of the Jump relaxation model and the Jonscher power law are used to study the ac-conductivity data. [ABSTRACT FROM AUTHOR]

Published

2024

6. Effect of Coagulation Conditions on the Radial Moduli of Polyacrylonitrile Nascent Fibers.

Author

Liu, Yutao, Deng, Zhuoyin, Xu, Lianghua, Zhang, Ke, and Li, Changqing

Abstract

Polyacrylonitrile (PAN) nascent fibers were spun in a mixture of dimethyl sulfoxide (DMSO) and water. As the DMSO mass fraction (WDMSO) or temperature (TS) of the solution increased, the crystallinity and the modulus of PAN fibers first increased and then decreased. At WDMSO < 75% or TS < 45 °C, increases in the WDMSO and TS resulted in the formation of ordered crystal structures, and the crystallinity and the modulus of the PAN fibers improved. At WDMSO > 75% or TS > 45 °C, increases in the WDMSO and TS facilitated formation of a chaotic internal structure. Furthermore, the crystallinity and modulus of the nascent fiber decreased because the aqueous DMSO solution dissolved PAN. The moduli of the PAN fibers depended strongly on the crystallinity. The fiber outer layer was the first part of the fiber to encounter the DMSO aqueous solution, and material exchange between DMSO in the fiber and water in the DMSO aqueous solution occurred more readily than in the core. This resulted in a higher degree of coagulation and a larger modulus. When WDMSO was 75% and TS was 45 °C, the PAN fibers had the highest crystallinity (61%), highest modulus (28.5 GPa), and smallest modulus difference (5 GPa) between the PAN fiber outer layer and core. [ABSTRACT FROM AUTHOR]

Published

2024

7. Photocurable Hypervalent Fluorinated Sulfur Containing Thin Films with Remarkable Hardness and Modulus.

Author

Bonetti, Kelly A., Rende, Deniz, Murphy, Michael, and Welch, John T.

Subjects

*YOUNG'S modulus, *POLYMER films, *THIN films, *SILICON surfaces, *ISOMERS

Abstract

Novel tetrafluoro-λ6-sulfanyl-containing oligomers prepared by visible light-promoted addition of 1,4-(bis-chlorotetrafluoro-λ6-sulfanyl) benzene or 1,3-(bis-chlorotetrafluoro-λ6-sulfanyl) benzene to either 1,4-diethynyl benzene or the 1,3-diethynyl isomers form hard, stress resistant thin films on spin casting. The isomeric oligomers were utilized to establish a structure-function relationship for the mechanical properties of films prepared from the oligomers. The Young's moduli of 145-nm-thick cured films could reach 60 GPa. The measured hardnesses, between 1.57 and 2.77 GPa, were more than double those of polymethyl methacrylate (PMMA) films. Curing of the tetrafluoro-λ6-sulfanyl-containing polymer films by UV irradiation resulted in coatings that exhibited remarkable hardness and modulus with good surface adhesion to silicon. [ABSTRACT FROM AUTHOR]

Published

2024

8. CNED sets: countably negligible for extremal distances.

Author

Ntalampekos, Dimitrios

Subjects

*AUTHORS

Abstract

The author has recently introduced the class of CNED sets in Euclidean space, generalizing the classical notion of NED sets, and shown that they are quasiconformally removable. A set E is CNED if the conformal modulus of a curve family is not affected when one restricts to the subfamily intersecting E at countably many points. We prove that several classes of sets that were known to be removable are also CNED , including sets of σ -finite Hausdorff (n - 1) -measure and boundaries of domains with n-integrable quasihyperbolic distance. Thus, this work puts in common framework many known results on the problem of quasiconformal removability and suggests that the CNED condition should also be necessary for removability. We give a new necessary and sufficient criterion for closed sets to be (C)NED. Applying this criterion, we show that countable unions of closed (C)NED sets are (C)NED. Therefore we enlarge significantly the known classes of quasiconformally removable sets. [ABSTRACT FROM AUTHOR]

Published

2024

9. Complex impedance and electric modulus of flexible ferroelectric polymer PVDF-ZnO hybrid nanocomposite thin films.

Author

Arshad, A. H., Dani, Santhoshkumar, Khanam, Bibi Raza, Meena, Ramcharan, Angadi, V. Jagadeesha, and Khadke, Udaykumar V.

Subjects

*ELECTRIC conductivity, *ELECTRIC impedance, *DIELECTRIC relaxation, *PERMITTIVITY, *DIELECTRIC properties, *FERROELECTRIC polymers

Abstract

Ferroelectric polymer-based separators, known for their flexibility, ease of synthesis, and modifiability through dopants, are currently under extensive study due its potential applications in electronic devices. PVDF nanocomposites, which combine the strengths of their constituents, currently lead in emerging technologies. This research employs Zinc oxide nanoparticles (ZnO NPs) as fillers in the PVDF matrix and investigates their structural, optical, thermal and electrical properties. ZnO NPs synthesized via the combustion method, are being incorporated with varying concentrations (2, 4, 6, 8, and 10 wt%), into PVDF nanocomposite (PNC) thin films through a solution casting process. The PNC thin films are characterized using XRD, FTIR, UV–Vis spectroscopy and thermogravimetric analysis (TGA). Dielectric properties are being explored across a frequency range from 20 to 2 MHz at room temperature, revealing enhanced dielectric constants at lower frequencies, decreasing with frequency due to Maxwell–Wagner interfacial polarization. With increasing frequency, AC conductivity and electric modulus exhibit enhancement. Complex impedance analysis via the Cole–Cole plot indicates a non-Debye type of dielectric relaxation with heightened conductivity. TGA demonstrates improved thermal stability in PNC thin films. These findings suggest the potential application of the prepared PNC thin films as separators in energy storage devices. [ABSTRACT FROM AUTHOR]

Published

2024

10. Plasticized PVC composites comprising MWCNT‐RGO hybrid filler–the synergetic effect of hybrids on the dielectric and mechanical properties.

Author

Akhina, H., Reghunadhan, Arunima, Nair, M. R. Gopinathan, and Thomas, Sabu

Subjects

HYBRID materials, MULTIWALLED carbon nanotubes, POLYMERIC nanocomposites, DIELECTRIC strength, DIELECTRIC properties

Abstract

Modification of polymers with hybrid fillers has sought much attention in the past few years. The addition of hybrid fillers will lead to a synergistic effect in reinforcing and is advantageous in polymer nanocomposites. One such attempt is presented here that explores the effect of incorporation of hybrid derived from reduced graphene oxide (RGO) and multiwalled carbon nanotubes (MWCNT) on the dielectric and mechanical properties of plasticized polyvinyl chloride (PPVC). This system of hybrid composite incorporating RGO‐CNT and PPVC has not been prepared and reported yet. Melt mixing techniques were effectively used for the fabrication of PPVC nanocomposites containing the hybrid filler in different ratios. The prepared composites showed enhanced dielectric strength in the lower frequency region up to 450 and high AC conductivity. The mutual stacking and penetration of the 1D‐2D nanomaterials lead to effective dispersion and enhancement in the electronic conduction. Among the hybrids, the R1C5 (with the filler ration RGO 1 wt% and CNT 5%) was having the optimum properties. The tensile modulus showed a cumulative variation with the addition of CNT. Even though the tensile strength decreased slightly because of the immobilization of the PPVC chains by the hybrid effect, the modulus value showed a marked increase of over 90% from the virgin polymer. The PPVC composite with R1C5 hybrid filler exhibited an EMI shielding efficiency of ⁓23 dB and it was frequency independent. The results suggest the composite R1C5 should be used as a cost‐effective material for applications in the L‐band and S‐band regions. [ABSTRACT FROM AUTHOR]

Published

2024

11. A Digital Project Management Framework for Transnational Prefabricated Housing Projects.

Author

Luo, Liwei, Ding, Zhikun, Niu, Jindi, Zhang, Liang, and Liao, Longhui

Subjects

BUILDING information modeling, COST control, LABOR costs, WASTE recycling, INFORMATION resources management

Abstract

Compared with an ordinary prefabricated housing project (PHP), a transnational PHP tends to involve more uncertainties, with major stakeholders residing in different countries. This study proposes a novel digital project management framework that integrates building information modeling to enhance information utilization. This framework also incorporates innovative design concepts of modulor, modulus, module, model, durability, and recyclability for enhanced user comfort, housing industrialization, and extended lifespan. It was demonstrated how planning, design, manufacture, and transportation processes can be streamlined in transnational PHP delivery. A case study was performed in a typical transnational PHP between the Kingdom of Saudi Arabia and China for validation. By applying the framework, this PHP could install a single house within 24 h, improve precast level by about 20%, and reduce project cost per square meter by 5.2%, because of integrated design concept, reduced labor cost, effective material cost control, and enhanced information management. [ABSTRACT FROM AUTHOR]

Published

2024

12. Short-Term Hydrolytic Degradation of Mechanical Properties of Absorbable Surgical Sutures: A Comparative Study.

Author

Szabelski, Jakub and Karpiński, Robert

Subjects

PHYSIOLOGIC salines, TENSILE strength, INDIVIDUAL differences, SUTURES, SUTURING

Abstract

Surgical sutures play a crucial role in wound closure, facilitating the tissue-healing process across various fields of medicine. The objective of this study was to analyse the impact of seasoning time during the initial days/weeks of seasoning in Ringer's solution on the mechanical properties of five commercial absorbable sutures: SafilQuick+®, Novosyn®, MonosynQuick®, Monosyn® and Monoplus®, each with different absorption periods. The results demonstrated that the SafilQuick+ and MonosynQuick sutures lost strength within 9–12 days, as evidenced by statistically significant changes in tensile strength. In contrast, the Novosyn and Monoplus sutures did not exhibit significant changes in strength during the study period. Statistical analysis confirmed significant differences in the behaviour of the individual sutures, highlighting the importance of selecting appropriate suture material in the context of the specific medical procedure. [ABSTRACT FROM AUTHOR]

Published

2024

13. Measurement of maize stalk shear moduli

Author

Joseph Carter, Joshua Hoffman, Braxton Fjeldsted, Grant Ogilvie, and Douglas D. Cook

Subjects

Biomechanics, Modeling, Torsion, Modulus, Shear, Plant culture, SB1-1110, Biology (General), QH301-705.5

Abstract

Abstract Maize is the most grown feed crop in the United States. Due to wind storms and other factors, 5% of maize falls over annually. The longitudinal shear modulus of maize stalk tissues is currently unreported and may have a significant influence on stalk failure. To better understand the causes of this phenomenon, maize stalk material properties need to be measured so that they can be used as material constants in computational models that provide detailed analysis of maize stalk failure. This study reports longitudinal shear modulus of maize stalk tissue through repeated torsion testing of dry and fully mature maize stalks. Measurements were focused on the two tissues found in maize stalks: the hard outer rind and the soft inner pith. Uncertainty analysis and comparison of multiple methodologies indicated that all measurements are subject to low error and bias. The results of this study will allow researchers to better understand maize stalk failure modes through computational modeling. This will allow researchers to prevent annual maize loss through later studies. This study also provides a methodology that could be used or adapted in the measurement of tissues from other plants such as sorghum, sugarcane, etc.

Published

2024

14. Modelling rapid non-destructive test using light weight deflectometer on granular soils across different degrees of saturation

Author

Javad Ghorbani, Arooran Sounthararajah, Troyee Tanu Dutta, and Jayantha Kodikara

Subjects

Granular soils, Plasticity, Finite element analysis, Contact mechanics, Modulus, Degree of saturation, Engineering geology. Rock mechanics. Soil mechanics. Underground construction, TA703-712

Abstract

This study introduces an advanced finite element model for the light weight deflectometer (LWD), which integrates contact mechanics with fully coupled models. By simulating LWD tests on granular soils at various saturation levels, the model accurately reflects the dependence of the LWD modulus on dry density, water content, and effective stress. This model addresses and overcomes the limitations of previous finite element models for this specific problem. Simultaneously, this research presents the first experimentally validated fully coupled contact impact model. Furthermore, the research provides a comparative assessment of elastoplastic and nonlinear elastic models and contrasts an enriched node-to-segment method (developed in this study) with the more precise mortar technique for contact mechanics. These comparisons reveal unique advantages and challenges for each method. Moreover, the study underscores the importance of careful application of the LWD modulus, emphasising the need for sophisticated tools to interpret soil behaviour accurately.

Published

2024

15. Correlation between Dental Composite Filler Percentage and Strength, Modulus, Shrinkage Stress, Translucency, Depth of Cure and Radiopacity.

Author

Lopez, Carolina, Nizami, Bushra, Robles, Augusto, Gummadi, Snigdha, and Lawson, Nathaniel C.

Subjects

*PEARSON correlation (Statistics), *FLEXURAL strength, *FLEXURAL modulus, *IMAGE analysis, *BENDING strength, *RADIOPACITY, *DENTAL materials

Abstract

Filler content in dental composites is credited for affecting its physical and mechanical properties. This study evaluated the correlation between the filler percentage and strength, modulus, shrinkage stress, depth of cure, translucency and radiopacity of commercially available high- and low-viscosity dental composites. Filler weight percentage (wt%) was determined through the burned ash technique (800 °C for 15 min). Three-point bend flexural strength and modulus were measured according to ISO 4049 with 2 mm × 2 mm × 25 mm bars. Shrinkage stress was evaluated using a universal testing machine in which composite was polymerized through two transparent acrylic rods 2 mm apart. Shrinkage was measured from the maximum force following 500 s. The translucency parameter (TP) was measured as the difference in color (ΔE00) of 1 mm thick specimens against white and black tiles. The depth of cure was measured according to ISO 4049 in a cylindrical metal mold (4 mm diameter) with a 10 s cure. Radiopacity was measured by taking a digital X-ray (70 kVp for 0.32 s at 400 mm distance) of 1 mm thick specimens and comparing the radiopacity to an aluminum step wedge using image analysis software. The correlation between the filler wt% and properties was measured by Pearson's correlation coefficient using SPSS. There was a positive linear correlation between the filler wt% and modulus (r = 0.78, p < 0.01), flexural strength (r = 0.46, p < 0.01) and radiopacity (r = 0.36, p < 0.01) and negative correlation with translucency (r = −0.29, p < 0.01). Filler wt% best predicts the modulus and strength and, to a lesser extent, the radiopacity and translucency. All but two of the high- and low-viscosity composites from the same manufacturer had statistically equivalent strengths as each other; however, the high-viscosity materials almost always had a statistically higher modulus. For two of the flowable composites measured from the same manufacturer (3M and Dentsply), there was a lower shrinkage stress in the bulk-fill version of the material but not for the other two manufacturers (Ivoclar and Tokuyama). All flowable bulk-fill composites achieved a deeper depth of cure than the flowable composite from the same manufacturer other than Omnichroma Flow Bulk. [ABSTRACT FROM AUTHOR]

Published

2024

16. High performance foams and their nanocomposites generated via liquid state frontal polymerization.

Author

Daguerre‐Bradford, John A., Lepcio, Petr, Camarda, Daniel S., Lesser, Alan J., Cristadoro, Anna M., Linnenbrink, Martin, and Schütte, Markus

Subjects

*BLOWING agents, *ADDITION polymerization, *ENERGY consumption, *HIGH temperatures, *ANISOTROPY, *FOAM

Abstract

Anisotropy in naturally occurring or synthetic microcellular structures is an important feature for the development of materials with high specific stiffness and strength, in addition to creating materials with unique physical properties. Polymeric foams constitute a broad class of materials that are widely used for their advantages of low density, high specific mechanical properties and high insulative properties. Traditional synthetic routes are slow, energy demanding processes that employ the use of high temperature ovens, freezers, or high‐pressure equipment. Herein we present a convenient and energy efficient method to produce anisotropic high performance polymeric foams via rapid radically induced cationic frontal polymerization coupled with chemical blowing agents. The degree of pore orientation and degree of anisotropy are a result of the propagating front working in concert with the foam volume expansion. This paper presents results into FP foam formation to illustrate how changes in boundary conditions and front initiation position affect both the microcellular structure and their resulting physical and mechanical properties. Additionally, results are presented to show how changes in resin formulation, such as the addition of nanoparticles affect both properties as well as the microcellular structure and anisotropy. [ABSTRACT FROM AUTHOR]

Published

2024

17. Dynamic tensile viscoelastic properties of porcine periodontal ligament.

Author

Yang, Song and Zhao, Qiuxu

Subjects

*MATERIALS testing, *SWINE, *ORTHODONTICS, *IN vitro studies, *BIOMECHANICS, *RESEARCH funding, *ELASTICITY, *TENSILE strength, *ANIMAL experimentation, *MASTICATION, *PERIODONTAL ligament

Abstract

The periodontal ligament plays a significant role in orthodontic and masticatory processes. To explicitly investigate the effects of dynamic force amplitude and frequency on the dynamic tensile properties of the periodontal ligament, in vitro tensile experiments were conducted using a dynamic mechanical analysis at various dynamic force amplitudes across a wide frequency range. Storage modulus, loss modulus, and loss factor values were measured. A Maxwell constitutive model based on modulus was established to describe the dynamic mechanical properties of the periodontal ligament. The results showed that the storage modulus ranged from 29.53 MPa to 158.24 MPa, the loss modulus ranged from 3.26 MPa to 76.16 MPa, and the loss factor values all increased with higher frequencies and higher dynamic force amplitudes. Based on the parameters obtained from the fitting results, it is evident that the short‐term response has a more pronounced impact on the elastic response of the periodontal ligament than the long‐term response. Increasing the dynamic force amplitude and its frequency amplified the viscous effects of the periodontal ligament and enhanced energy dissipation. The proposed constitutive model further demonstrated that the periodontal ligament acts as a viscoelastic biomaterial. These findings have implications for future research on the periodontal ligament. [ABSTRACT FROM AUTHOR]

Published

2024

18. A Momentum Map for the Heisenberg Group.

Author

Cushman, Richard

Subjects

*ORBITS (Astronomy)

Abstract

We look at a momentum map associated with the Heisenberg group. We show that the cocycle associated with its momentum mapping is the value of a modulus of an associated coadjoint orbit. [ABSTRACT FROM AUTHOR]

Published

2024

19. Uncovering the impact of BaO on electrical properties of bismuth boro vanadate glasses: V2O5-B2O3-Bi2O3-BaO.

Author

Rani, Asha, Parmar, Rajesh, and Kundu, R. S.

Subjects

*ELECTRIC conductivity, *ENERGY storage, *IMPEDANCE spectroscopy, *ACTIVATION energy, *POLARONS

Abstract

This work investigates the AC conductivity, impedance spectroscopy, and modulus formulation of varied compositions of glass samples within the modified borovanadate glassy system, synthesized using the melt-quenching technique. Up to 10 mol% of BaO, the AC conductivity shows a rising trend as BaO content rises; however, for x = 15&20 mol%, there is a drop. The Almond West model fits the experimental data of ac conductivity and parameters such as crossover frequency, frequency exponent (s), and direct current conductivity are retrieved. All samples feature a CBH conduction mechanism at varying frequencies, except for VBa1, which has a small polaron quantum mechanical mechanism. There is good agreement in the activation energy derived from conductivity (0.565–0.742 eV), electric modulus (0.526–0.616 eV), and impedance research (0.530–0.743 eV). Dielectric studies reveal non-Debye-type behavior. According to impedance formalism, electric conduction occurs through Ba2+ ions and electron/polarons. This characteristic renders the glasses well-suited for energy storage devices. [ABSTRACT FROM AUTHOR]

Published

2024

20. Electrical and dielectric properties of Si5P6O25: Experimental study and simulation of oxygen pathways migration.

Author

Borni, Moufida, Hajji, Mounir, Smida, Youssef Ben, and Triki, Mohamed

Subjects

*DIELECTRIC properties, *IONIC conductivity, *PERMITTIVITY, *RIETVELD refinement, *DIELECTRIC materials

Abstract

Silicophosphate, prepared from Tunisian siliceous sand, has been investigated as a potential oxide ion conductor. XRD and Rietveld refinement analyses confirm the formation of pure single-phase Si5P6O25 that crystallizes in the trigonal system with R-3 space group. The electrical conductivities and dielectric properties of this material have been studied using complex impedance spectroscopy from 10 to 106 Hz at a temperature range from 600 to 680 °C. The results show that the ionic conductivity σdc increases from 5.43 × 10− 5 S.cm− 1 at 600 °C to 0.23 × 10− 3 S.cm− 1 at 680 °C with an activation energy of 1.33 eV. The frequency dependence of AC conductivity could be explained by Jonscher's power law. The dielectric constant's decrease with frequency indicates a region of dispersion resulting from a polarization process' relaxation. The simulation of the oxygen conduction using the Bond Valence Site Energy (BVSE) model shows the presence of four interstitial sites used with equilibrium sites to form a zigzag isosurface of oxygen migration. The calculated activation energy is about 1.43 eV. [ABSTRACT FROM AUTHOR]

Published

2024

21. Design and Development of New Lead-Free Complex Perovskite: (1-x) BiFeO3 -x(Bi-K) (Ti/Mn) O3, (x = 0.05, 0.1)

Author

Sourav, S. K., Choudhary, R. N. P., and Prasad, Umakant

Abstract

The complex lead-free perovskite ceramics, (1-x) BiFeO3-X(B/K) Ti/MnO3, where X = 0.05, 0.10 were fabricated by using a solid-state chemical reactions technology. The X-ray diffraction analysis exhibits the formation of the sample in rhombohedral crystal symmetry (#R3c). The average crystallite size for BKTM with 5% content and BKTM with 10% content was determined utilizing the Scherrer formula, resulting in sizes of 21.83 nm and 27.81 nm, respectively. Fourier-transformed infrared spectroscopy spectrum analysis also supports the formation of compounds based on the characteristics peak corresponding to Bi-O and Ti-O bonds. Scanning electron microscope (SEM) shows the distribution of grain and surface morphology. The surface morphology indicates dense grain development with no fractures. The mean grain size for BKTM with 5% content is approximately 2.73 μm, whereas for BKTM with 10% content, it is about 0.49 μm. This discovery could help with grain and grain border resistive and capacitive properties. The impedance study reveals the electrical behavior of the sample. The semicircular arc of the complex impedance and electrical modulus spectrum plots reveal the substance’s semiconducting properties. [ABSTRACT FROM AUTHOR]

Published

2024

22. Thermal aging behavior and heat resistance mechanism of ultraviolet crosslinked ultra‐high molecular weight polyethylene fiber.

Author

Dong, Tianhong, Niu, Fangfang, Qiang, Zhe, Wang, Xinpeng, Guo, Jungu, Wang, Yimin, and He, Yong

Subjects

POLYETHYLENE fibers, ULTRAHIGH molecular weight polyethylene, POLYETHYLENE, MOLECULAR weights

Abstract

As advances in heat resistant ultrahigh molecular weight polyethylene (UHMWPE) fiber via ultraviolet (UV) crosslinking, it is worth paying attention to its thermal aging behavior and heat resistance mechanism. UHMWPE fibers in different forms, the fully drawn yarn (FDY) and the UV crosslinked FDY (UVFDY), are subjected to isothermal aging at 135°C. The effects of thermal aging on their surface morphology and mechanical properties are studied and compared initially. The results demonstrate that UVFDY is a kind of a heat‐resistant fiber. Subsequently, to reveal the heat resistance mechanism of UVFDY, its crystalline and orientation structure evolution during thermal aging are further studied. It is indicated that the formation of dense‐packing crystals and disorientation behavior lead to fiber shrink, so that a number of grooves appear on the fiber surface. Since the crosslinked stucture of UVFDY hinders its molecules movement, the crystallization and disorientation behavior of UVFDY are weaker than those of FDY, resulting in UVFDY possesses slighter thermal shrinkage (Ts), fewer grooves and better mechanical properties than those of FDY. Therefore, the heat resistance of the fiber improves effectively after UV crosslinking. This work provides insights into the structure–property relationship of UVFDY during thermal aging, and offers basis data for its application in specific conditions. [ABSTRACT FROM AUTHOR]

Published

2024

23. A comprehensive study of dielectric, modulus, impedance, and conductivity of SrCeO3 synthesized by the combustion method.

Author

Verma, Harish, Tripathi, Arpita, and Upadhyay, Shail

Subjects

*DIELECTRICS, *DIELECTRIC relaxation, *COMBUSTION, *DIELECTRIC properties, *IONIC conductivity, *RIETVELD refinement, *X-ray diffraction, *SOLID state proton conductors

Abstract

In this work, perovskite oxide SrCeO3 was synthesized using the solution combustion method (SCM). Synthesized samples have been characterized using X‐ray diffraction (XRD), Raman, ultra violet (UV)–visible spectroscopy, and scanning electron microscopy (SEM) techniques. The XRD and Rietveld refinement has confirmed the orthorhombic structure with space group Pnma. The average grain size of this ceramic sample is 1.2 µm. The dielectric constant, dissipation factor, modulus, impedance, and alternating current (AC) and direct current (DC) conductivities were analyzed in the temperature range RT to 600°C and frequency range 20 Hz–2 MHz. Further, it was observed that the role of grain boundaries in dielectric and electrical properties is significant, at low temperatures. The origin of the dielectric relaxation and conduction process is the same. The activation energy for DC conduction (Edc) was found to be.79 eV. Electrical conduction/relaxation is assigned to the diffusion of doubly ionized oxygen (Vo··). The value of DC conductivity (1.2 × 10−3 Ω−1 cm−1 at 600°C) and activation energy of.79 eV is very close to the values reported for doped CeO2‐based oxide ion conductors for SOFCs. This study has demonstrated that SrCeO3 can be an alternative candidate for the oxide ion conductor electrolyte application and the potential to be used as a thermally stable capacitor application for microwave dielectric applications. [ABSTRACT FROM AUTHOR]

Published

2024

24. Synthesis and characterization of BaBiLaNbVO9 for temperature-based sensor application.

Author

Kumar, Nitin, Hota, Sudhansu Sekhar, Panda, Debasish, Choudhary, R.N.P., and Prasad, Umakant

Subjects

*TEMPERATURE coefficient of electric resistance, *X-ray crystallography, *ENERGY bands, *SPACE groups, *OPTOELECTRONIC devices, *BAND gaps, *DETECTORS

Abstract

BaBiLaNbVO9 is a lead-free compound and has been synthesized by solid-state technique. The formation of the compound was confirmed by X-ray diffraction and is found to be crystallized in the monoclinic (space group P 21) crystal system (a = 13.7464± 0.0015 Å, b = 4.0156± 0.0012 Å, c = 12.4946 ± 0.0018 Å, β = 93.48 ± 0.01o). The crystallite size was found to be 52.91 nm. SEM and EDX studies analyzed the morphology, composition, and elemental distribution in the specimen. The average grain size is about 1.0651 μm. Several properties, such as frequency and temperature response resistivity, conductivity, and dielectric behaviours of the compound, have been analyzed. The overlapping large polaron tunnelling (OLPT) and correlated barrier hopping (CBH) models are appropriate for electrical conduction in the compound. The energy band gap (Eg) of the material was 2.40 eV, suitable for optoelectronic devices. Ferroelectric behaviour may be deduced from symmetric and well-shaped P-E hysteresis loops. The impedance study satisfies the negative temperature coefficient of resistance (NTCR) behaviour, which is suitable for thermistor devices and its correlated application. [ABSTRACT FROM AUTHOR]

Published

2024

25. Developing Bio-Nano Composites Using Cellulose-Nanofiber-Reinforced Epoxy.

Author

Mehdinia, Meysam, Farajollah Pour, Mohammad, Yousefi, Hossein, Dorieh, Ali, Lamanna, Anthony J., and Fini, Elham

Subjects

CRYSTALLINE interfaces, FLEXURAL modulus, DIFFRACTION patterns, SCANNING electron microscopy, EPOXY resins

Abstract

This study introduces the development of a novel bio-nano composite via the dispersion of cellulose nanofibers (CNF) in epoxy. The surface of cellulose nanofibers was functionalized using a two-step chemical treatment to enhance dispersion. The interfacial characteristics of CNF were improved using alcohol/acetone treatments. The modified CNF (M-CNF) demonstrated enhanced compatibility and improved dispersion in the epoxy matrix as evidenced by scanning electron microscopy. Based on the analysis of X-ray diffraction patterns, M-CNF did not disturb the crystalline phases at the interface. The results of mechanical testing showed that M-CNF worked as a reinforcing agent in the bio-nano composite. The flexural modulus increased from 1.4 to 3.7 GPa when M-CNF was introduced. A similar trend was observed for tensile strength and impact resistance. The optimum performance characteristics were observed at M-CNF of 0.6%. At higher dosages, some agglomeration was observed, which weakened the interfacial properties. This study promotes sustainability and resource conservation while offering CNF as a sustainable reinforcing agent to develop bio-nano composites. [ABSTRACT FROM AUTHOR]

Published

2024

26. Structural, electrical properties of bismuth and niobium-doped LaNiO3 perovskite obtained by sol–gel route for future electronic device applications.

Author

Nassar, Kais Iben, Benamara, M., Kechiche, L., Teixeira, S. Soreto, and Graça, M. P. F.

Abstract

This paper discusses the structural, microstructure and electrical properties of perovskite oxide lanthanum nickel LaNiO3, synthesized by the sol–gel reaction technique that was investigated. The prepared material was doped with bismuth and niobium and studied their properties. The Rietveld refinement of the X-ray diffraction pattern suggests that the compound has a monoclinic phase at room temperature with a P21/n space group. Scanning electron microscopy surface morphology analysis of the sample showed closed packing of grains with good density and very little porosity. The frequency-dependent modulus of the material is investigated in the temperature range from 200 K to 360 K and in range frequency between 1 kHz and 1 MHz. The Cole–Cole model is used to analyze the dielectric relaxation phenomenon. The complex impedance data are analyzed by an electrical equivalent circuit consisting of a resistance and a constant phase element, where the ideal capacitance part is replaced by a constant phase element. The frequency-dependent conductivity spectra follow the Jonscher power law. Nevertheless, the Arrhenius-type conduction mechanism was found to be active in the sample with activation energy of 0.168 eV. The electrical property of the sample was found to be independent of temperatures, making it a potential candidate for thermally stable capacitor application. [ABSTRACT FROM AUTHOR]

Published

2024

27. Revealing the Correlation Between Lyapunov Exponent and Modulus of an n-Dimensional Nondegenerate Hyperchaotic Map.

Author

Cao, Yafei and Liu, Hongjun

Subjects

*INVERSE functions, *EXPONENTIATION, *LYAPUNOV exponents, *CRYPTOGRAPHY

Abstract

For their good randomness and long iteration periods, chaotic maps have been widely used in cryptography. Recently, we have revealed the correlation between Lyapunov exponent and sequence randomness of multidimensional chaotic maps based on modular operation. Since the modular operation can realize the boundedness of chaotic state points, it is important to further reveal the deterministic correlation between Lyapunov exponent and modulus. First, we constructed an n -dimensional nondegenerate hyperchaotic map model with the desired Lyapunov exponents. Then, we gave the existence and uniqueness proof of quadrature rectangle decomposition theorem and revealed the correlation between Lyapunov exponent and modulus. The novelty lies in that (1) in order to realize the irreversibility of the iterative processes of chaotic maps, we constructed a chaotic map based on modular exponentiation, and its inverse function is the discrete logarithm problem; and (2) we reveal for the first time the correlation between Lyapunov exponent and modulus, and give the lower bound of the modulus of the nondegenerate chaotic map. In addition, to verify the effectiveness of the scheme, we constructed four-dimensional and five-dimensional chaotic maps, respectively, and analyzed their dynamical behaviors, and the results revealed that there exist linear or nonlinear correlation between Lyapunov exponent and modulus. [ABSTRACT FROM AUTHOR]

Published

2024

28. Dynamic mechanical properties of sugar palm fiber-reinforced polymer composites: a review.

Author

Mulla, Mohammed Huzaifa, Norizan, Mohd Nurazzi, Abdullah, Che Ku, Rawi, Nurul Fazita Mohammad, Kassim, Mohamad Haafiz Mohamad, Salleh, Kushairi Mohd, Abdullah, Norli, and Norrrahim, Mohd Nor Faiz

Subjects

*FIBER-reinforced plastics, *SYNTHETIC fibers, *FIBROUS composites, *NATURAL fibers, *HYBRID materials, *DYNAMIC mechanical analysis, *THERMOPLASTIC composites

Abstract

The incorporation of sugar palm fiber (SPF) into polymer composites presents an environmentally conscious and promising alternative to synthetic reinforcement materials. These composites exhibit impressive mechanical stiffness, strength, elongation, and thermal stability. Extensive research has centered on characterizing the thermal, mechanical, and physical behaviors of SPF-reinforced polymer composites under varying conditions. Despite their exceptional qualities, these composites have mainly been utilized in traditional applications such as brooms, brushes, and ropes. This study conducts a comprehensive exploration of their properties, employing dynamic mechanical analysis (DMA) to assess the thermal stability of SPF-reinforced polymer composites in both thermoplastic and thermoset matrices. The investigation focuses on critical parameters including storage modulus (E′), loss modulus (E′′), complex modulus (E), and damping factor (tan δ), with particular attention to temperature-sensitive interfacial bonds between fibers and diverse polymer matrices. Factors such as matrix type, filler type, processing and post-processing conditions, frequency, temperature, fiber length, loading, volume fraction, orientation, and treatment significantly influence the DMA properties of natural fibers. This review synthesizes the latest literature of the past decade, offering an in-depth overview of SPF polymer composites, including hybrid composites, and exploring their diverse applications. Furthermore, the study evaluates the effects of integrating synthetic fibers and employing chemical treatments on the DMA properties, impact resistance, and post-impact performance of SPF-reinforced polymer composites. By advancing knowledge in this domain, this comprehensive review provides valuable insights into designing and optimizing these composites for a wide range of engineering applications. [ABSTRACT FROM AUTHOR]

Published

2024

29. Synthesis and characterization of foams generated via gel state frontal polymerization.

Author

Daguerre‐Bradford, John, Camarda, Daniel S., Lesser, Alan J., Cristadoro, Anna M., Linnenbrink, Martin, and Schütte, Markus

Subjects

FOAM, GLASS transition temperature, BLOWING agents, ADDITION polymerization, POLYMERIZATION

Abstract

In conventional foams, anisotropy within the microcellular structure can only be achieved through confinement in one or more directions during the foaming process. Herein, we present a novel, versatile, and energy efficient method to create unique high‐performance foams where the anisotropy of the microcellular and the microcellular structure itself is not dictated by external confinement during the foaming process. To generate such foams, an initial crosslinked gel is first created where the crosslink density of the gel can be tuned by UV intensity and cure time. Next, the gel can be foamed while simultaneously creating a second network via radically induced cationic frontal polymerization (RICFP). In this case, the anisotropy in the foam is dictated by propagation front during the RICFP and the microcellular morphology and cell surface area are dictated by the crosslink density of the gel. These two unique qualities lead to rigid foams that can be generated from a gel without the need for confinement where the microcellular size and shape can be tuned by the crosslink density of the gel precursor. A one‐pot liquid system composed of miscible epoxies, acrylates, and chemical blowing agents (CBAs), allows for control over the foam physical, mechanical, and thermal properties with glass transition temperatures ranging from 74.7 to 125.8°C. Additionally, by patterning the crosslink density of the initial gel through controlled exposure of UV, complex microcellular structures can be formed that are not possible in conventional foaming processes. This positions gel frontal polymerization and foaming as an advanced technique to produce high performing anisotropic foams with a wide array of tunable physical, mechanical, and thermal properties. [ABSTRACT FROM AUTHOR]

Published

2024

30. Fabrication of a Capacitive 3D Spacer Fabric Pressure Sensor with a Dielectric Constant Change for High Sensitivity.

Author

Lee, Ji-Eun, Kim, Sang-Un, and Kim, Joo-Yong

Subjects

*PRESSURE sensors, *PERMITTIVITY, *CARBON nanotubes, *NONLINEAR regression, *INTELLIGENT sensors, *BIOLOGICAL monitoring

Abstract

Smart wearable sensors are increasingly integrated into everyday life, interfacing with the human body to enable real-time monitoring of biological signals. This study focuses on creating high-sensitivity capacitive-type sensors by impregnating polyester-based 3D spacer fabric with a Carbon Nanotube (CNT) dispersion. The unique properties of conductive particles lead to nonlinear variations in the dielectric constant when pressure is applied, consequently affecting the gauge factor. The results reveal that while the fabric without CNT particles had a gauge factor of 1.967, the inclusion of 0.04 wt% CNT increased it significantly to 5.210. As sensor sensitivity requirements vary according to the application, identifying the necessary CNT wt% is crucial. Artificial intelligence, particularly the Multilayer Perception (MLP) model, enables nonlinear regression analysis for this purpose. The MLP model created and validated in this research showed a high correlation coefficient of 0.99564 between the model predictions and actual target values, indicating its effectiveness and reliability. [ABSTRACT FROM AUTHOR]

Published

2024

31. Study on the Effect of Asphalt Static Conditions on the Tensile Properties of Acidic Aggregate Hydraulic Asphalt Concrete.

Author

Bao, Lei, He, Min, Wang, Shu, and Wu, Xinshuang

Subjects

*ASPHALT, *ASPHALT concrete, *TENSILE strength, *TENSILE tests, *HYDRAULIC structures, *DIGITAL computer simulation, *ECONOMIC efficiency

Abstract

Hydraulic asphalt concrete is known for its excellent seepage control performance and strong deformation resistance. This engineering material has widespread applications in the seepage control structures of hydraulic buildings. Recent projects have investigated the use of acidic aggregates to improve economic efficiency. However, they have also highlighted the weaker adhesion between acidic aggregates and asphalt, which necessitates stringent construction process control. This study investigates the impact of resting conditions on the tensile properties of acidic aggregate hydraulic asphalt concrete. The results of the tensile testing indicate that the storage time significantly affects the performance of asphalt concrete. The tensile strength of the specimens without anti-stripping agents decreased from 1.711 MPa to 0.914 MPa after resting periods of 0, 10, 20, and 30 days. The specimens treated with anti-stripping agents also showed a decrease in tensile strength over time, similar to the trend observed in the previous specimens. Digital specimen simulations indicated a decrease in cohesion between the asphalt and the aggregate from 5.375 MPa to 2.664 MPa after 30 days, representing a reduction of 50.44%. To counteract the effect of the storage time on the bonding between acidic aggregates and asphalt, this study recommends reducing the grading index and maximum size of aggregates, decreasing the coarse aggregate content, and selecting smooth aggregate shapes. [ABSTRACT FROM AUTHOR]

Published

2024

32. Synthesis, morphological, and ionic conductivity of a lithium cerium diphosphate compound.

Author

Hamdi, Mohamed, Shuheil, Mohamed Abu, and Oueslati, Abderrazek

Abstract

This study focuses on the preparation of lithium diphosphate compound LiCeP2O7 via conventional solid-state reaction. Analysis using the Rietveld refinement of the X-ray diffraction pattern reveals that the sample adopts a monoclinic structure at room temperature. Surface morphology is further examined through SEM. Additionally, complex impedance and electrical modulus spectroscopy analyses indicate the presence of non-Debye-type relaxation behavior. The direct current (dc) conductivity exhibits Arrhenius behavior, with activation energies of 0.94 eV in region I and 1.21 eV in region II, indicating thermally activated lithium-ion conduction. The thermal behavior of the exponent parameter "s" suggests a transition in the conduction mechanism from large polaron tunneling to small polaron tunneling that occurs at 533 K. Electric modulus studies confirm that the ionic conduction relaxation process is thermally activated and exhibits a spread of relaxation time. Understanding the ionic conduction mechanism will facilitate the design of efficient ionic conductors for battery applications. [ABSTRACT FROM AUTHOR]

Published

2024

33. Modulus Characterizations of Bilipschitz Mappings.

Author

Zhou, Qingshan, Yang, Zhiqiang, Rasila, Antti, and He, Yuehui

Subjects

HOMEOMORPHISMS, SPHERES

Abstract

In this paper, we establish six necessary and sufficient conditions for a homeomorphism of R n onto itself to be strongly quasisymmetric. These conditions are quantitative in terms of conformal moduli of disjoint continua as well as the geometric modulus, which was recently introduced by Tukia and Väisälä. Note that all of them are equivalent to bilipschitz continuity with parameters depending also on two fixed points. As an application, we obtain several quantitative characterizations for a homeomorphism of the Riemann sphere R ¯ n onto itself to be strongly quasimöbius. [ABSTRACT FROM AUTHOR]

Published

2024

34. Multiscale Toughening Mechanism in Hybrid Fiber Reinforced Cement-Based Nanocomposites

Author

Danoglidis, Panagiotis A., Singh, Rohitashva K., Konsta-Gdoutos, Maria S., Mechtcherine, Viktor, editor, Signorini, Cesare, editor, and Junger, Dominik, editor

Published

2024

35. Preparation of Cu Powders with Electrical Explosion of Wires and Their Size-Dependent Mechanical Properties

Author

Wang, Chenhui, Zhang, Luojia, Wu, Bingjia, Ding, Kai, Gao, Yulai, Zhao, Bingge, and The Minerals, Metals & Materials Society

Published

2024

36. Effect of Slope, Cross-Section of Pile and Eccentricity in Calculating the Modulus of Laterally Loaded Single Pile

Author

Sivapriya, S. V., di Prisco, Marco, Series Editor, Chen, Sheng-Hong, Series Editor, Vayas, Ioannis, Series Editor, Kumar Shukla, Sanjay, Series Editor, Sharma, Anuj, Series Editor, Kumar, Nagesh, Series Editor, Wang, Chien Ming, Series Editor, Cui, Zhen-Dong, Series Editor, Gencel, Osman, editor, Balasubramanian, M., editor, and Palanisamy, T., editor

Published

2024

37. Dielectric properties of chitosan-based ZnO nanocomposites for high-frequency electronic devices

Author

Erol, Ibrahim, Tataroğlu, Adem, Artun, Hasan, Khamidov, Gofur, Dere, Ayşegül, and Yakuphanoğlu, Fahrettin

Published

2024

38. Metric Sobolev Spaces I: Equivalence of Definitions

Author

Ambrosio, Luigi, Ikonen, Toni, Lučić, Danka, and Pasqualetto, Enrico

Published

2024

39. Investigation of structural, dielectric and electrical properties of lead-free bismuth-based layered multifunctional material: CaBiGdNbVO9 for device fabrication

Author

Kumar, N., Hota, S. S., Panda, D., Samal, S. K., Choudhary, R. N. P., and Prasad, U.

Published

2024

40. Effects of Nanoparticles on the Mechanical Properties of the Composites Prepared from Biological and Chemical Gels.

Author

Osma, Büşra, Yavuz, Başar, Kaba, Tuğsan, and Akın Evingür, Gülşen

Abstract

AbstractPoly (N-isopropyl acrylamide) (PNIPAm) and polyacrylamide (PAAm) are widely used in antifouling research because of their non-harmful nature and their high water-absorbing capacity. In addition, hydrogels such as these two, should be investigated for their mechanical properties because their mechanical properties influence the antifouling paint containing them remaining on the surface of the vessels. In this research PAAm, PNIPAm, and kappa carrageenan (κC) doped with graphene oxide (GO) and multi-walled carbon nanotubes (MWCNTs) composite gels were examined for their mechanical properties for use in antifouling paints as a potential material. For increasing the mechanical properties of composites, GO and MWCNTs are often used as doping materials. In the research described here, a compressive test was used to determine the elasticity, and the modulus was calculated. The toughness was calculated from the slope of the stress-strain curve. The PAAm, PNIPAm, and κC doped with GO and MWCNT exhibited excellent swelling and deswelling behavior and good mechanical properties as composites. The results showed that the composites’ mechanical characteristics increased with an ideal loading concentration of GO and MWCNTs. This study was inspired by our belief of a shortage of research on antifouling materials that are sensitive to the environment. We wanted to create materials that were both effective against fouling and environmentally safe by integrating the beneficial characteristics of hydrogels with potential materials inside antifouling paint. This study, we suggest, is an important step toward the development of antifouling materials with high mechanical performance that are also environmentally friendly. [ABSTRACT FROM AUTHOR]

Published

2024

41. Advance effect of magnetic field on the rheological properties of manganese zinc ferrite ferrofluid.

Author

Ibiyemi, A. A., Akinrinola, O., Yusuf, G. T., Olaniyan, S., Lawal, J., Orojo, M., and Osuporu, B.

Subjects

*MANGANESE compounds, *ZINC ferrites, *MAGNETIC fluids, *TORQUE, *MAGNETIC fields, *MAGNETIZATION

Abstract

The rheological characteristics of manganese zinc (Mn-Zn) ferrite magnetic nanofluid synthesized using co-precipitation technique were examined in the absence and presence of magnetic fields. The research formulates required conditions needed for the formation of a gelly-like structure. The impact of magnetic field and temperature on the rheological properties of Mn-Zn ferrite ferrofluid is investigated. When a magnetic field was applied, higher magnetoviscoelasticity and magnetoviscosity were formed. Other rheological parameters such as damping factor which is crucial for regulating and restricting vibrations in a system was also analyzed. A stiff, gel-like structure is produced when a magnetic field is applied, and the gel-like quality grows as the magnetic field increases; when the magnetic field is removed, the gel-like and rigidity of the structure is lost. At low temperatures, the liquid phase is dominated by solid-like particles, whereas at high temperatures, the liquid-like structure is dominant. This study reveals the conditions required for the creation of high viscous effect and the viscoelastic behavior induced by the field offers important insights for optimizing the Mn-Zn ferrite ferrofluid for a range of applications. Other criterial for gel-like structure formation such as low torque and deflection angle of the ferrofluid were also established. [ABSTRACT FROM AUTHOR]

Published

2024

42. Mechanical and Thermal Properties of the Hf–Si System: First-Principles Calculations.

Author

Huang, Panxin, Han, Guifang, Liu, Huan, Zhang, Weibin, Peng, Kexue, Li, Jianzhang, Wang, Weili, and Zhang, Jingde

Subjects

THERMAL properties, THERMAL insulation, POISSON'S ratio, THERMAL conductivity, MELTING points, HIGH temperatures

Abstract

The relatively low melting point of a traditional Si bonding layer limits the upper servicing temperature of environmental barrier coatings (EBC). To explore suitable high temperature bonding layers and expedite the development of EBC, first-principles calculation was used to evaluate the mechanical properties and thermal conductivity of HfSi2, HfSi, Hf5Si4, Hf3Si2, and Hf2Si with much higher melting points than that of Si. Among them, HfSi2 has the lowest modulus capable of good modulus matching with SiC substrate. In addition, these Hf-Si compounds have much lower high temperature thermal conductivity with Hf2Si being the lowest of 0.63 W m−1 K−1, which is only half of Si, capable of improved heat insulation. [ABSTRACT FROM AUTHOR]

Published

2024

43. Structural Elucidation of Electrical and Optical Properties in Lead‐free Organic‐Inorganic Copper Bromide [(CH3)4N]2CuBr4 Single Crystals.

Author

Dinesh and Singh, Satyendra

Subjects

*SINGLE crystals, *CUPROUS bromide, *OPTOELECTRONIC devices, *ORTHORHOMBIC crystal system, *OPTICAL properties, *PHASE transitions

Abstract

Organic‐inorganic metal halide single crystals have attracted a lot of attention due to their flexible structural design and excellent optoelectronic applications. This study details the synthesis of copper‐based [(CH3)4N]2CuBr4 hybrid metal halide single crystals via a slow evaporation method. The crystal structure, crystal habit, chemical groups, intermolecular interactions, electrical properties of the sample were studied via single crystal x‐ray diffraction, scanning electron microscopy, Raman and Fourier transform infrared spectrometer, Hirshfeld surface analysis, impedance spectroscopy, and modulus spectroscopy, respectively. An orthorhombic crystal system with the non‐centrosymmetric space group Pna21 was identified at room temperature. The deformation in the tetrahedra was calculated by the bond angle and bond length deformation index. The Cole‐Cole plot displayed the existence of depressed semicircles, which indicated the predominant distribution of grains, further confirmed by the SEM image. The deformed semi‐circular arcs on the electric modulus curve undeniably prove that the bulk effect dominates the material's electrical properties. Significantly, the compound presents a phase transition at ~240 K and excellent thermal stability up to a temperature of 400 K. Therefore, our research sheds light on the temperature dependence of electrical responses in these hybrid crystals and gives inspiration for the development of single crystal‐based efficient energy devices. [ABSTRACT FROM AUTHOR]

Published

2024

44. Effects of thermal and mechanical properties of Hf and Ta-doped NiCoCrAlY bonding layer alloys on the high-temperature oxidation resistance of thermal barrier coatings.

Author

Duan, Wenhao, Qiang, Wenjiang, Huang, Bingxin, Li, Yalin, and Huang, Ziang

Subjects

*THERMAL barrier coatings, *TANTALUM, *THERMAL resistance, *THERMAL properties, *OXIDATION

Abstract

The MCrAlY bonding layer alloy was prepared by vacuum melting, and the alloy composition was NiCoCrAlY and NiCoCrAlYHfTa. The high-temperature cyclic oxidation experiment was carried out in air at 1050∘C until it failed. The results show that Hf and Ta have a significant influence on the oxidation resistance of the alloy. The doped specimens have longer oxidation lifetimes compared to the undoped samples. The study also found that the Hf would diffuse out and combine with O to form HfO2 in the thermally grown oxide (TGO) layer, which would improve the adhesion and reduce the wrinkles of the oxide layer. Ta in the doped specimens hinders the diffusion of Al and reduces the oxidation rate, while improving the thermal mismatch. Therefore, the specimens doped with both Hf and Ta have the highest oxidation lifetimes, though the oxidation lifetime was 10 times longer than that of the undoped specimens. It is indicated that the doping of Hf and Ta is an important method to improve the oxidation lifetime of thermal barrier coatings (TBCs). [ABSTRACT FROM AUTHOR]

Published

2024

45. Nanomechanical analysis of friction welded similar PEEK/aluminum nanocomposites: Effect of metal particle reinforcement.

Author

Senkathir, S., Pramanik, Sumit, and Mukherjee, Manidipto

Subjects

*FRICTION welding, *NANOCOMPOSITE materials, *GLASS transition temperature, *ALUMINUM alloys, *NANOINDENTATION tests, *JOINING processes

Abstract

Aluminum (Al), poly(etheretherketone) (PEEK) thermoplastics, and their individual composites have widely been used in many industries, including aerospace and biomedical fields. However, the joining process of those composites has not been explored much to date. In this context, the friction welding process (FWP) could be used as an alternative since it has the ability to join high-strength components with minimal distortion. Therefore, the present study aimed to develop PEEK/Al nanocomposites with varying Al concentrations of 10, 20, 30, and 40 vol% using powder metallurgical technique and further joined the similar composition composites by FWP. Then, the effect of reinforced particle concentrations on the physical, morphological, structural, thermal, and micromechanical behaviors of the joined nanocomposites has been characterized by microscopy, X-ray diffraction, differential scanning calorimetry, and nanoindentation tests. The concentrations of the reinforcement were found to have a significant effect on the crystallinity, melting temperature, glass transition temperature, and thereby micromechanical properties. The results were analyzed and correlated precisely for all the welded nanocomposites systematically. The interdiffusion mechanism was found to be involved in improving the mechanical properties of the present nanocomposites. The highest elastic modulus (13.91 GPa) or nanohardness (0.31 GPa) was obtained for the rotatory part of the PEEK/Al40 nanocomposites at 80 mN load. But, the applied load of 40 mN was the best loading condition due to the uniform change in modulus and nanohardness of all the nanocomposites. Therefore, the present alternative joining method of the PEEK/Al nanocomposites might be used for aerospace components. Highlights • Development of PEEK/aluminum with 10, 20, 30 and 40 vol% Al nanocomposites. • Friction welding of similar composite material, PEEK/Al-PEEK/Al nanocomposites. • Microstructural, thermal, and nanomechanical analyses. • Effect of metal particle reinforcement on the friction welded nanocomposites. • FW PEEK/Al40 nanocomposite is found to be the best. [ABSTRACT FROM AUTHOR]

Published

2024

46. Rheological Behaviors of Polymers with Nanoparticles Tethered at Each End.

Author

Zhang, Song-Qi, Wang, Wen-Qing, Lin, Jia-Ping, and Wang, Li-Quan

Subjects

*MOLECULAR dynamics, *POLYMERS, *NANOPARTICLES

Abstract

The polymer with nanoparticles tethered at each end is a unique model for unraveling the effect of chain ends on the polymer dynamics. We investigated the rheological behavior of this kind of polymer by using nonequilibrium molecular dynamics simulation. The effect of polymer lengths and nanoparticle radii on the complex moduli and viscosity was examined. The dependence of complex moduli on the frequency becomes less pronounced as the polymer is short or the nanoparticle is large. The shear thinning behavior was revealed for these systems, and the scaling exponent of complex viscosity with respect to the frequency was found to change from −1/2 to −3/4 as the polymer shortens or the nanoparticle enlarges. The rheological behavior was further explained by analyzing the mean square distance of nanoparticles. The simulation results were compared with the existing experimental finding, showing an agreement. The work provides information for understanding the chain end effect on polymer rheology. [ABSTRACT FROM AUTHOR]

Published

2024

47. Preparation and Mechanism Analysis of Stainless Steel AOD Slag Mixture Base Materials.

Author

Huang, Liuyun, Wei, Guogao, Lan, Zhuxin, Chen, Yuliang, and Li, Tun

Subjects

*STAINLESS steel, *STEEL analysis, *SLAG, *PORTLAND cement, *TENSILE tests, *POZZOLANIC reaction, *FLY ash

Abstract

To promote resourceful utilization of argon oxygen decarburization (AOD) slag, this research developed a new three-ash stabilized recycled aggregate with AOD slag, cement, fly ash (FA), and recycled aggregate (RA) as raw materials. The AOD slag was adopted as an equal mass replacement for fly ash. The application of this aggregate in a road base layer was investigated in terms of its mechanical properties and mechanistic analysis. First, based on a cement: FA ratio of 1:4, 20 sets of mixed proportion schemes were designed for four kinds of cement dosage and AOD slag replacement rates (R/%). Through compaction tests and the 7-day unconfined compressive strength test, it was found that a 3% cement dosage met the engineering requirements. Then, the unconfined compressive strength test, indirect tensile strength test, compressive rebound modulus test, and expansion rate test were carried out at different age thresholds. The results showed that the mixture's strength, modulus, and expansion rate increased initially and then stabilized with age, while the strength and modulus initially increased and then decreased with increasing R. Secondly, based on X-ray diffraction (XRD) and scanning electron microscopy (SEM) used to analyze the mechanism, it was found that the strength, modulus, and expansion rate of the new material can be promoted by blending AOD slag, due to its ability to fully stimulate the hydration reaction and pozzolanic reaction of the binder. Finally, based on the strength and modulus results, R = 3% was identified as the optimal ratio, which provides a reference point for the effective application of AOD slag and RA in road base materials. [ABSTRACT FROM AUTHOR]

Published

2024

48. Mechanical behavior and particle crushing of marine carbonate gravel in Xisha Islands, South China Sea.

Author

Wei, Xing

Subjects

*GRAVEL, *YOUNG'S modulus, *CARBONATES

Abstract

Carbonate gravelly soils are widely distributed in sub-tropical marine areas. During construction and engineering operations, carbonate gravel undergoes considerable particle crushing, which has remarkable effects on their engineering properties. A series of large-diameter oedometer tests, large-diameter drained and undrained triaxial shear tests were conducted on carbonate gravel specimens taken from the South China Sea. The carbonate gravel specimens exhibit significant particle crushing at common engineering pressure levels, and the particle crushing highly depends on the initial density, loading history and stress path. Three fragmentation modes, fracture, attrition, and abrasion, are notable in carbonate gravel specimens, which induces significant variations of PSD curves and greatly effects the mechanical properties. Particle crushing in carbonate gravel specimens increases the compressibility resulting in the compression index increases with the increase of surcharge pressure; decreases the pressure-hardening resulting in the initial Young's and secant moduli slightly increase with the increase of initial confining pressure; and decreases the dilatancy resulting in the peak and critical state friction angles significantly deceases with the increase of initial confining pressure. Particle crushing also shows great effect on the CSL of the carbonate gravel specimens in both p ′ - q space and e - p ′ space. [ABSTRACT FROM AUTHOR]

Published

2024

49. The modulus of a vector measure.

Author

de Pagter, Ben and Ricker, Werner J.

Subjects

RIESZ spaces, VECTOR spaces, LINEAR orderings

Abstract

It is known that if L is a Dedekind complete Riesz space and (Ω, Σ) is a measurable space, then the partially ordered linear space of all L-valued, finitely additive and order bounded vector measures m on Σ is also a Dedekind complete Riesz space (for the natural operations). In particular, the modulus |m|o of m exists in this space of measures and |m|o is given by a well known formula. Some 20 years ago L. Drewnowski and W. Wnuk asked the question (for L not Dedekind complete) if there is an m for which |m|o exists but, |m|o is not given by the usual formula? We show that such a measure m does indeed exist. [ABSTRACT FROM AUTHOR]

Published

2024

50. 南禅寺大殿尺度规律研究.

Author

肖 旻

Abstract

Copyright of South Architecture / Nanfang Jianzhu is the property of South Architecture 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

2024