Your search keyword '"Materials science"' showing total 6,876,963 results

1. Physical properties

Author

Charles R. Fitts

Subjects

Materials science

Published

2024

2. Nuclear Detonation

Author

William E. Dickerson, Yasser Alaska, and Abdulaziz D. Aldawas

Subjects

Materials science, Detonation, Mechanics

Published

2024

3. Rigid Lens Materials

Author

Nathan Efron

Subjects

Lens materials, Materials science, Optics, business.industry, business

Published

2024

4. Soft Lens Materials

Author

Carole Maldonado-Codina

Subjects

Lens materials, 020303 mechanical engineering & transports, Materials science, Optics, 0203 mechanical engineering, business.industry, 02 engineering and technology, 021001 nanoscience & nanotechnology, 0210 nano-technology, business

Published

2024

5. Soft Lens Design and Fitting

Author

Graeme Young

Subjects

03 medical and health sciences, 0302 clinical medicine, Materials science, Optics, business.industry, 030221 ophthalmology & optometry, Lens (geology), business, 030217 neurology & neurosurgery

Published

2024

6. Injectable Biomimetic Hydrogels Providing Prolonged Delivery of GLP-1 Analogues for Enhanced Diabetes Treatment

Author

Lu, Katie and Appel, Eric

Subjects

Diabetes, Bioengineering, Type 2 diabetes, Biology, Materials science

Abstract

In the US, there are over 130 million people living with Type 2 diabetes (T2D), who suffer from impaired regulation of hepatic glucose production, which eventually leads to β-cell failure. While insulin treatments are often recommended, they are burdensome to appropriately dose and can lead to dangerous hypoglycemic events. In contrast, glucagon- like peptide-1 receptor agonists (GLP-1 RAs), which mimic an incretin hormone secreted following carbohydrate intake, stimulate insulin and block glucagon secretion in a glucose- dependent manner, thereby eliminating the risk of hypoglycemia. These treatments lower endogenous glucose production and drive expansion of insulin-secreting β-cells to restore the native ability of patients to regulate glycemia. Unfortunately, current GLP-1 RAs must be injected either daily (Liraglutide) or weekly (Semaglutide), which results in significant patient burden and poor patient compliance. An ideal GLP-1 RA drug would provide continuous therapy for upwards of four months from a single administration during each primary care visit, which is the frequency which T2D patients visit their physician. In this work, we leverage an injectable hydrogel depot technology to develop a long-acting GLP- 1 RA drug. We show that a single injection of hydrogel-based therapies prolongs GLP-1 RA exposure and significantly improves management of blood glucose and weight in a rat model of T2D when compared with daily injections of a leading drug molecule over 42 days. Overall, we anticipate this work demonstrates the potential of a GLP-1 RA depot to dramatically reduce the frequency of therapeutic interventions, significantly increasing patient quality of life.

Published

2024

7. Soft Lens Measurement

Author

Klaus Ehrmann

Subjects

03 medical and health sciences, 020303 mechanical engineering & transports, 0302 clinical medicine, Optics, Materials science, 0203 mechanical engineering, business.industry, 030221 ophthalmology & optometry, Lens (geology), 02 engineering and technology, business

Published

2024

8. A fast and in-depth self-reconstruction of anion ligands optimized CoFe-based pre-catalysts for water oxidation

Author

Qiuyan Jin, Chengxin Wang, and Hao Cui

Subjects

Metal, Materials science, Chemical engineering, Renewable Energy, Sustainability and the Environment, Etching, visual_art, visual_art.visual_art_medium, Oxygen evolution, Electron interaction, Nanosheet, Ion, Catalysis, Amorphous solid

Abstract

The design of efficient and robust non-precious metal electrocatalysts towards oxygen evolution reaction (OER) is of great value for developing green energy technologies. The in-situ formed high-valence (oxy)hydroxides species during the reconstruction process of pre-catalysts are recognized as the real contributing sites for OER. However, pre-catalysts generally undergo a slow and inadequate self-reconstruction. Herein, we reported a PO43− optimized CoFe-based OER catalysts with amorphous structure, which enables a fast and deep reconstruction during the OER process. The amorphous structure induced by ligands PO43− is prone to evolution and further form active species for OER. The electron interaction between metal sites can be modulated by electron-rich PO43−, which promotes generation of high active CoOOH. Simultaneously, the etching of PO43− from the pre-catalysts during the catalytic process is in favor of accelerating the self-reconstruction. As a result, as-prepared pre-catalyst can generate high active CoOOH at a low potential of 1.4 V and achieve an in-depth reconstructed nanosheet structure with abundant OER active sites. Our work provides a promising design of pre-catalysts for realizing efficient catalysis of water oxidation.

Published

2023

9. Aluminum-air battery with cotton substrate: Controlling the discharge capacity by electrolyte pre-deposition

Author

Wending Pan, Yifei Wang, Holly Y.H. Kwok, and Dennis Y.C. Leung

Subjects

Battery (electricity), Materials science, Waste management, Renewable Energy, Sustainability and the Environment, 02 engineering and technology, Electrolyte, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, Battery pack, 0104 chemical sciences, Anode, Specific energy, 0210 nano-technology, Power density, Leakage (electronics), Voltage

Abstract

Conventional Al-air battery has many disadvantages for miniwatt applications, such as the complex water management, bulky electrolyte storage and potential leakage hazard. Moreover, the self-corrosion of Al anode continues even when the electrolyte flow is stopped, leading to great Al waste. To tackle these issues, an innovative cotton-based aluminum-air battery is developed in this study. Instead of flowing alkaline solution, cotton substrate pre-deposited with solid alkaline is used, together with a small water reservoir to continuously wet the cotton and dissolve the alkaline in-situ. In this manner, the battery can be mechanically recharged by replacing the cotton substrate and refilling the water reservoir, while the thick aluminum anode can be reused for tens of times until complete consumption. The cotton substrate shows excellent ability for the storage and transportation of alkaline electrolyte, leading to a high peak power density of 73 mW cm−2 and a high specific energy of 930 mW h g−1. Moreover, the battery discharge capacity is found to be linear to the loading of pre-deposited alkaline, so that it can be precisely controlled according to the mission profile to avoid Al waste. Finally, a two-cell battery pack with common water reservoir is developed, which can provide a voltage of 2.7 V and a power output of 223.8 mW. With further scaling-up and stacking, this cotton-based Al-air battery system with low cost and high energy density is very promising for recharging miniwatt electronics in the outdoor environment.

Published

2023

10. Additive Manufacturing With Strontium Hexaferrite-Photoresist Composite

Author

Aysan Rangchian, Srinivas P. M. Nagaraja, Rüştü Umut Tok, Rob N. Candler, Max Ho, Yuanxun Ethan Wang, and Pirouz Kavehpour

Subjects

010302 applied physics, Materials science, business.industry, Magnetocrystalline anisotropy, 01 natural sciences, Ferromagnetic resonance, Electronic, Optical and Magnetic Materials, law.invention, Magnetic field, Magnetization, Magnetic anisotropy, law, Magnet, 0103 physical sciences, Eddy current, Optoelectronics, Electrical and Electronic Engineering, Anisotropy, business

Abstract

Millimeter wave components, such as circulators and isolators, frequently use magnetic fields to break symmetry of the signal propagation and provide unidirectional signal transmission. While effective, these components have not seen the level of miniaturization of other millimeter wave components, primarily due to the discrete nature of the magnets used in the components. Using circulators in the 40-50 GHz range as a motivating application, requirements arise for the deposited films, namely immunity to eddy currents, sufficient magnetization to act as self-biasing magnets, and out-of-plane orientation of the self-biasing field. Based on these required properties, hexaferrite materials are selected for their strong magnetocrystalline anisotropy (MCA) and low conductance. The difficulty of integrating these components monolithically with monolithic microwave integrated circuits (MMIC) originates from the incompatibility of crystal structure with standard semiconductor materials and process conditions. Additive manufacturing using a composite of strontium hexaferrite (SrFe12O19) particles and photoresist has been chosen as a method to overcome the difficulties of integrating hexaferrite material to semiconductor substrates. Due to their large internal anisotropy field, the particles of strontium hexaferrite tend to rotate to the field direction instead of changing magnetization direction under application of an external magnetic field (less than the anisotropy field). We have developed a method for 3D printing composites of high strontium hexaferrite concentration (up to 20% by volume) in a liquid photoresist, SU8. Rotation of hexaferrite particles in polymer matrix and thus magnetic anisotropy has been demonstrated in the composite, which is subsequently cured to hold the physical position and orientation of the particles. The anisotropy of the self-biasing field provided by the films has been experimentally characterized, and a ferromagnetic resonance (FMR) frequency ~43 GHz has been observed. We have also characterized the viscosity of the particle-laden polymer at different particle concentrations. 3D printing of this composite with poling will make it possible to directly print magnetic components that require out-of-plane anisotropic magnetization.

Published

2023

11. Concept and Process Development Using Ex Situ Fabricated High-Density Interconnect Plugs for Circuit-Board Embedded Magnetic Components

Author

David Bowen, George Stackhouse, and Debtanu Basu

Subjects

Fabrication, Materials science, business.industry, Hardware_PERFORMANCEANDRELIABILITY, Ferrite core, Electronic, Optical and Magnetic Materials, law.invention, Inductance, Magnetic circuit, Printed circuit board, Magnetic core, law, Hardware_INTEGRATEDCIRCUITS, Optoelectronics, Microelectronics, Electrical and Electronic Engineering, business, Transformer

Abstract

Magnetic circuit components have long been the largest and most difficult components to miniaturize. Printed circuit board (PCB) fabrication methods cannot achieve small diameter, high aspect-ratio vias for high winding turn numbers to achieve high inductance, and microelectronics methods cannot achieve the high-quality and thick ferrite core materials. In this paper, we present an alternative breakthrough method of printed circuit fabrication to significantly reduce the effective via diameter for embedded magnetic devices, boosting the inductance per unit area. To reduce the effective via diameter, high-density via plugs are ex-situ fabricated and shaped, and then embedded into PCB substrate in the same process as standard magnetic core embedding. The structure of the plug is such that precise placement within the substrate, or alignment to the plug with the winding pattern, is not necessary. Devices presented in this paper use via plugs with an effective diameter of 40 μm and a theoretically unlimited aspect ratio, though refinements in the plug fabrication process are expected to reduce the via diameter down to 10μm. The process is experimentally demonstrated with a 14-turn racetrack shaped transformer; novel diagnostic methods using magneto-optic garnet films to image current paths are also demonstrated.

Published

2023

12. Novel in-capsule synthesis of metal–organic framework for innovative carbon dioxide capture system

Author

Guanhe Rim, Aqil Jamal, Tony G. Feric, Wei Yu, Ming Gao, Ammar Alahmed, Ah-Hyung Alissa Park, and Mark L. Rivers

Subjects

chemistry.chemical_compound, Materials science, Silicone, Sorbent, chemistry, Nanocrystal, Renewable Energy, Sustainability and the Environment, Microfluidics, Ultrafine particle, Nanotechnology, Metal-organic framework

Abstract

Metal-Organic Frameworks (MOFs) have been developed as solid sorbents for CO2 capture applications and their properties can be controlled by tuning the chemical blocks of their crystalline units. A number of MOFs (e.g., HKUST-1) have been developed but the question remains how to deploy them for gas–solid contact. Unfortunately, the direct use of MOFs as nanocrystals would lead to serious problems and risks. Here, for the first time, we report a novel MOF-based hybrid sorbent that is produced via an innovative in-situ microencapsulated synthesis. Using a custom-made double capillary microfluidic assembly, double emulsions of the MOF precursor solutions and UV-curable silicone shell fluid are produced. Subsequently, HKUST-1 MOF is successfully synthesized within the droplets enclosed in the gas permeable microcapsules. The developed MOF-bearing microcapsules uniquely allow the deployment of functional nanocrystals without the challenge of handling ultrafine particles, and further, can selectively reject undesired compounds to protect encapsulated MOFs.

Published

2023

13. Elasto-plastic constitutive modelling of compacted rockfill materials: a physically based approach

Author

Chaomin Shen, Sihong Liu, and Liujiang Wang

Subjects

Materials science, Breakage, Constitutive equation, Earth and Planetary Sciences (miscellaneous), Elasto plastic, Particle, Composite material, Geotechnical Engineering and Engineering Geology, Microstructure

Abstract

An elasto-plastic constitutive model for rockfill materials considering particle breakage is proposed. Although numerous constitutive models have been proposed for rockfill materials, most of them are mainly based on empirical results, without consideration of the physical meaning of their parameters. In the present work, a yield function is derived based on the evolution of microstructures formed by rockfill particles. The dilatancy equation is derived based on both the theory of breakage mechanics and the energy dissipation equations. The breakage-induced hardening is also formulated to account for both the volumetric and shearing hardening of rockfill materials. It is demonstrated that, without compromising the simplicity of the model, most of the parameters in the proposed constitutive model have concrete physical meanings. Comparison of the model simulation with experimental data shows that the proposed model can describe reasonably the static loading characteristics of rockfill materials within a wide range of confining stresses.

Published

2023

14. A preliminary exploration of the micro-scale behaviour of capillary barrier effect using microfluidics

Author

Bate Bate, Liangtong Zhan, Guang-Yao Li, and Yunmin Chen

Subjects

Materials science, Scale (ratio), Capillary action, Slope stability, Microfluidics, Earth and Planetary Sciences (miscellaneous), Barrier effect, Geotechnical engineering, Geotechnical Engineering and Engineering Geology

Abstract

The capillary barrier effect (CBE) is employed in a large number of geotechnical applications to decrease deep percolation or increase slope stability. However, the micro-scale behaviour of CBE is rarely investigated, and thus hampers the scientific design of capillary barrier systems. This study uses microfluidics to explore the micro-scale behaviour of CBE. Capillarity-driven water flow processes from fine to coarse porous media with different pore topologies and sizes were performed and analysed. The experimental results demonstrate that the basic physics of CBE is the preferential water movement into the fine porous media due to the larger capillarity. The effects of CBE on water flow processes can be identified as delaying the occurrence of breakthrough into the coarse porous media and increasing the water storage of the fine porous media. The CBE can impede the increase of the normalised length and decrease the normalised width of the water front, suggesting that the two normalised parameters are potential indicators to assess the performance of CBE at the micro scale. CBE can be formed in square and honeycomb networks with the ratio of coarse to fine pore throat width larger than 2·0 when gravity is neglected, and its performance can be affected by pore topology and size.

Published

2023

15. A purely green approach to low-cost mass production of zeolitic imidazolate frameworks

Author

Dapeng Cao, Hai Li, Bei Liu, Chun Deng, Mingke Yang, Chang-Yu Sun, Wan Chen, Guang-Jin Chen, and Zixuan Huang

Subjects

Filter cake, Solvent, chemistry.chemical_classification, Pilot plant, Aqueous solution, Materials science, Chemical engineering, chemistry, Renewable Energy, Sustainability and the Environment, Salt (chemistry), Environmentally friendly, Catalysis, Zeolitic imidazolate framework

Abstract

Although zeolitic imidazolate frameworks (ZIFs) have bright prospects in wide fields like gas storage/separation, catalysis and medicine, etc., their large-scale applications are bottlenecked by the absence of their low-cost commercial production technique. Here, we report an unconventional method suitable for environmentally friendly and low-cost mass-production of ZIFs. In this method, taking the synthesis of ZIF-8 as an example, ZnO was used instead of Zn(NO3)2 in traditional solvent synthesis methods and CO2 was introduced to dissolve ZnO in aqueous solution of 2-methylimidazole (HMeim) and form water soluble salt ([ZnMeim]+[MeimCOO]-) at room temperature. Then, by removing CO2 through heating or vacuuming, Meim-ions are produced and instantaneously assemble with [ZnMeim]+s to generate ZIF-8 without any by-product. Due to the absence of strong acid anions (such as NO3− and Cl− et al.) in solution, the washing of filter cake required in the conventional approaches could be omitted and the filtrate containing only water and HMeim could be reused completely. This method is really green as no waste gas or liquid generates because CO2 and water could be recycled perfectly. It overcomes almost all bottlenecks occurred in commercial production of ZIF-8 when using traditional methods. A pilot plant was established for mass-production of ZIF-8 and hundreds kilograms of ZIF-8 was produced, which indicates that the new method is not only environmentally friendly but also low cost and commercial accessibility. It is expected that the new method would open an avenue for commercial applications of ZIFs.

Published

2023

16. Accelerated prediction of Cu-based single-atom alloy catalysts for CO2 reduction by machine learning

Author

Yang Li, Chen Liang, Guangyong Chen, Pengfei Chen, Xiaolong Zou, Dashuai Wang, Shaogang Hao, and Runfeng Cao

Subjects

Materials science, Renewable Energy, Sustainability and the Environment, business.industry, Coordination number, Electronic structure, Antibonding molecular orbital, Machine learning, computer.software_genre, Catalysis, Adsorption, Oxidation state, Atom, Artificial intelligence, Valence electron, business, computer

Abstract

Various strategies, including controls of morphology, oxidation state, defect, and doping, have been developed to improve the performance of Cu-based catalysts for CO2 reduction reaction (CO2RR), generating a large amount of data. However, a unified understanding of underlying mechanism for further optimization is still lacking. In this work, combining first-principles calculations and machine learning (ML) techniques, we elucidate critical factors influencing the catalytic properties, taking Cu-based single atom alloys (SAAs) as examples. Our method relies on high-throughput calculations of 2669 CO adsorption configurations on 43 types of Cu-based SAAs with various surfaces. Extensive ML analyses reveal that low generalized coordination numbers and valence electron number are key features to determine catalytic performance. Applying our ML model with cross-group learning scheme, we demonstrate the model generalizes well between Cu-based SAAs with different alloying elements. Further, electronic structure calculations suggest surface - negative center could enhance CO adsorption by back donating electrons to antibonding orbitals of CO. Finally, several SAAs, including PCu, AgCu, GaCu, ZnCu, SnCu, GeCu, InCu, and SiCu, are identified as promising CO2RR catalysts. Our work provides a paradigm for the rational design and fast screening of SAAs for various electrocatalytic reactions.

Published

2023

17. MOF-derived Zn–Co–Ni sulfides with hollow nanosword arrays for high-efficiency overall water and urea electrolysis

Author

Yangyang Ding, Xiaoqiang Du, and Xiaoshuang Zhang

Subjects

Electrolysis, Materials science, Hydrogen, Electrolysis of water, Renewable Energy, Sustainability and the Environment, Oxygen evolution, chemistry.chemical_element, Electrochemistry, Electrocatalyst, law.invention, Catalysis, chemistry, Chemical engineering, law, Electrode

Abstract

Water electrolysis is a promising technology to produce hydrogen but it was severely restricted by the slow oxygen evolution reaction (OER). Herein, we firstly reported an advanced electrocatalyst of MOF-derived hollow Zn–Co–Ni sulfides (ZnS@Co9S8@Ni3S2-1/2, abbreviated as ZCNS-1/2) nanosword arrays (NSAs) with remarkable hydrogen evolution reaction (HER), OER and corresponding water electrolysis performance. To reach a current density of 10 mA cm−2, the cell voltage of assembled ZCNS-1/2//ZCNS-1/2 for urea electrolysis (1.314 V) is 208 mV lower than that for water electrolysis (1.522 V) and stably catalyzed for over 15 h, substantially outperforming the most reported water and urea electrolysis electrocatalysts. Density functional theory calculations and experimental result clearly reveal that the properties of large electrochemical active surface area (ECSA) caused by hollow NSAs and fast charge transfer resulted from the Co9S8@Ni3S2 heterostructure endow the ZCNS-1/2 electrode with an enhanced electrocatalytic performance.

Published

2023

18. Investigation of short fibers formation on a circular knitting machine using cotton as raw material

Author

B. Chemani, S. Chellali, and R. Halfaoui

Subjects

Materials science, cotton , knitting, tension, yarn, Tension (physics), visual_art, visual_art.visual_art_medium, General Medicine, Fiber, Yarn, Raw material, Yarn tension, Composite material

Abstract

When providing care, to protect a part of the human body against resins and plas ters for certain time, it is necessary to use a circular knitted band in cotton as a raw material. The generating of Cotton fiber fly throughout the knitting process is due to interactions of frictional surfaces with the hairiness of ring spun yarn. During the manufacture short fibers are formed in the machine device, this problem is more important with the use of cotton yarns. In this research paper, the short fibers formation on circular knitting machines from spun yarns such as cotton is investigated The knitting conditions consist of; yarn tension, yarn feeding speed and the angle contact of the yarn with guides and needles. The results obtained illustrate the effect of yarn tension on the short fibers deposit caused by the combination of yarn friction with the knitting elements.

Published

2023

19. ESTIMASI TEMPERATUR CONDENSOR REFLUX (136 H09) PADA REGENERATION UNIT UNTUK PENGHEMATAN KONSUMSI TEG

Author

Tessa Audia Linarta, Christyfani Sindhuwati, and Hardjono Hardjono

Subjects

Absorption of water, Materials science, business.industry, Reboiler, medicine.disease, chemistry.chemical_compound, chemistry, Chemical engineering, Natural gas, Regenerative heat exchanger, medicine, General Earth and Planetary Sciences, Dehydration, business, Condenser (heat transfer), Water vapor, General Environmental Science, Triethylene glycol

Abstract

Proses dehidrasi merupakan salah satu proses yang sering dijumpai pada pabrik pengolahan gas alam. TEG (triethylene glycol) merupakan senyawa Glycol yang biasa digunakan pada proses dehidrasi gas alam. TEG dimanfaatkan sebagai absorben pada absorpsi air yang masih terkandung dalam gas alam yang bisa menyebabkan hydrate dan korosi. Proses absorpsi ini dilakukan di TEG contactor, TEG yang sudah digunakan akan dilakukan regenerasi, jika sudah di regenerasi maka TEG akan digunakan kembali. Tujuan dari penelitian ini yaitu melakukan proses estimasi temperatur yang sesuai untuk proses absorpsi unit regenerasi TEG, karena banyak TEG loss pada proses ini. TEG loss terjadi di TEG regenerator dan biasanya disebabkan oleh temperatur kondensor refluks yang kurang tepat sehingga menyebabkan TEG teruapkan keluar ke atmosfer bersama uap air. Kehilangan TEG adalah masalah bagi operasi yang penting dalam sistem dehidrasi. Langkah yang digunakan untuk mengurangi TEG loss adalah dengan melakukan estimasi temperatur dari condensor refluks dibuat menjadi 100°C dengan cara mengubah temperatur reboiler dari 190°C menjadi 197,3°C.

Published

2023

20. KAJIAN LITERATUR KARAKTERISTIK BIODEGRADABLE POLYMER BERBAHAN BAKU PATI DENGAN PENAMBAHAN FILLER DAN BEESWAX

Author

Lutfi Kusuma Wardani and Nanik Hendrawati

Subjects

Filler (packaging), Materials science, visual_art, visual_art.visual_art_medium, General Earth and Planetary Sciences, Composite material, Beeswax, General Environmental Science

Abstract

Biodegradable polymer berbahan dasar pati merupakan alternatif polymer ramah lingkungan yang dikembangkan untuk mengatasi permasalahan yang ditimbulkan oleh bahan – bahan polymer sekali pakai berbahan dasar minyak bumi . Biodegradable polymer dengan bahan dasar pati memiliki kelemahan antara lain nilai water vapor permeability dan water absorption nya yang besar serta nilai kuat tarik nya yang kecil. Kajian literatur ini bertujuan untuk mengetahui pengaruh filler dan coating beeswax terhadap karakteristik biodegradable polymer berdasarkan penelitian yang sudah dilakukan. Berdasarkan jurnal yang didapat pengaplikasian coating beeswax dapat menurunkan nilai water absorption lebih baik dari biodegradable polymer tanpa coating . Penelitian dengan menggunakan filler tanpa coating beeswax menghasilkan nilai water absorption sebesar 15,77% dengan bahan baku pati singkong. Penelitian menggunakan coating beeswax menghasilkan nilai water absorption sebesar 0,8%. Penelitian dengan coating beeswax menghasilkan nilai water vapor permeability sebesar 4,4042 x 10 -9 g mm/s m 2 Pa. Pada pengujian kuat tarik dengan menggunakan filler tanpa coating beeswax menghasilkan nilai kuat tarik sebesar 20 MPa. Penelitian menggunakan coating beeswax menghasilkan nilai kuat tarik terbaik yaitu 14 MPa.

Published

2023

21. Heat and mass transfer processes of solid-state hydrogen discharging: a CFD study

Author

Ali Boukhari, R. Menaceur, S. E. Laouini, and Mohammed El Hadi Attia

Subjects

Packed bed, Materials science, Computer simulation, Hydrogen, business.industry, chemistry.chemical_element, General Medicine, Mechanics, Metal hydride, LaNi5, Desorption, Numerical simulation, Finite volumes, Computational fluid dynamics, Mischmetal, chemistry, Mass transfer, Heat transfer, business

Abstract

This article deals with the numerical simulation of a two-dimensional instantaneous heat and mass transfer processes within a commonly used intermetallic compound (a.k.a. Mischmetal) packed in a unit disc of an annulus-disc reactors, during hydrogen gas desorption. Using the finite volumes technique bundled in the OpenFOAM® CFD code, temperature and amount of desorbed hydrogen and their time-averaged quantities inside the metal-hydride packed bed are obtained for various temperatures of fluids used in heat transfer, and several outlet pressure magnitudes. Using a set of numerical simulations, we have emphasized the impacts of both parameters on metal-hydride reactor performance related to discharging time. An excellent accord was recorded for the present simulations results compared against the literature-reported experimental data [20].

Published

2023

22. PENGARUH VARIASI WAKTU DAN SUHU PENCELUPAN PADA PROSES HOT DIP GALVANIZING TERHADAP KETEBALAN PERMUKAAN BAJA DI PT BONDI SYAD MULIA GRESIK

Author

Yugata Gama Widyanto and Hardjono Hardjono

Subjects

Materials science, chemistry, General Earth and Planetary Sciences, chemistry.chemical_element, Zinc, General Environmental Science, Nuclear chemistry

Abstract

Galvanisasi merupakan proses pelapisan dengan seng ( Zinc ), dengan caara mencelupkan logam yang akan dilapisi kedalam media pelapis zinc yang sebelumnya telah mengalami proses peleburan, dimana titik lebur logam pelapis harus lebih rendah dari logam yang akan dilapisi. Tujuan dari penelitian ini adalah untuk mengetahui pengaruh waktu pencelupan dan temperatur terhadap proses pencelupan. Analisis yang akan dilakukan adalah uji ketebalan permukaan dan melakukan uji kekerasan bahan setelah dilakukan pencelupan. Dalam penelitian ini material yang digunakan adalah baja dengan tipe UNP, Sebelum dilakukan Hot Dip Galvanized perlu dilakukan pretreatment menggunakan bahan kimia, yaitu proses degreasing, water rinsing, pickling, fluxing, drying . Setelah itu dilakukan tahap Galvanisasi, Variabel yang akan digunakan adalah suhu zinc bath 440 o C,445 o C,450 o C dan waktu pencelupan 2,4,6,8,10 menit. Dari hasil analisis semakin lama waktu pencelupan pada proses hot dip galvanizing mengakibatkan semakin tebal lapisan zinc yang dihasilkan dan Semakin tinggi temperatur zinc saat proses hot dip galvanizing juga mengakibatkan semakin tebal lapisan zinc yang di hasilkan, di karenakan kekentalan dari zinc menurun.

Published

2023

23. Experimental and Computational Investigation of Shaped Film Cooling Holes Designed to Minimize Inlet Separation

Author

David G. Bogard, Fraser B. Jones, and Dale W. Fox

Subjects

geography, geography.geographical_feature_category, Materials science, Machining, Mechanical Engineering, Separation (aeronautics), Mechanical engineering, Engineering simulation, Separation technology, Inlet, Coolant

Abstract

Film cooling is used to protect turbine components from the extreme temperatures by ejecting coolant through arrays of holes to create an air buffer from the hot combustion gases. Limitations in traditional machining meant film cooling holes universally have sharp inlets which create separation regions at the hole entrance. The present study uses experimental and computational data to show that these inlet separation are a major cause of performance variation in crossflow fed film cooling holes. Three hole designs were experimentally tested by independently varying the coolant velocity ratio (VR) and the coolant channel velocitty ratio (VRc) to isolate the effects of crossflow on hole performance. Leveraging additive manufacturing technologies, the addition of a 0.25D radius fillet to the inlet of a 7-7-7 shaped hole is shown to significantly improve diffuser usage and significantly reduce variation in performance with VRc. A second AM design used a very large radius of curvature inlet to reduce biasing caused by the inlet crossflow. Experiments showed that this “swept” hole design did minimize biasing of coolant flow to one side of the shaped hole and it significantly reduced variations due to varying VRc. RANS simulations at six VR and three VRc conditions were made for each geometry to better understand how the new geometries changed the velocity field within the hole. The sharp and rounded inlets were seen to have very similar tangential velocity fields and jet biasing. Both AM inlets created more uniform, slower velocity fields entering the diffuser. The results of this paper indicate large improvements in film cooling performance can be found by leveraging AM technology.

Published

2023

24. Flexural performance of spliced composite slim beam with slotted web

Author

Linqiang Zhou, Senwen Deng, Shan Gao, Wei Wang, and Qi Bai

Subjects

Materials science, Flexural strength, Composite number, medicine, Stiffness, Building and Construction, Composite material, medicine.symptom, Beam (structure), Civil and Structural Engineering

Abstract

The flexural performance of a spliced composite slim beam with a slotted web (SCSB-SW) was assessed and prediction formulae of flexural capacity and initial stiffness for the beam were deduced. Through a four-point bending test, the flexural performance of the SCSB-SW was preliminary studied. The experimental results indicated that the section of the SCSB-SW conformed to the plane section assumption in the elastic stage. The beam failed in a ductile failure mode while there was no obvious relative slip between the steel beam and concrete slab in the failure stage. Finite-element models were developed and validated using the test results. A parametric analysis revealed that even if the cross-sectional dimensions and the position of the neutral axis in the beam are changed, the results predicted by the formulae still matched the numerical results well. The material strength, the thickness of the bottom flange of the steel beam and the concrete slab dimensions were found to play key roles in the flexural capacity of the beam, whereas the compressive strength grade of the concrete, the depth of the steel beam web and the dimensions of the concrete flange have significant effects on the initial stiffness of the beam.

Published

2023

25. High‐pressure MOCVD growth of InGaN thick films toward the photovoltaic applications

Author

Bo Shen, Liwen Sang, Meiyong Liao, Xuelin Yang, and Masatomo Sumiya

Subjects

Multidisciplinary, Materials science, business.industry, High pressure, Photovoltaic system, Optoelectronics, Metalorganic vapour phase epitaxy, business

Published

2023

26. Strength and hydration of metakaolin-containing ultra-high-performance paste

Author

Xu Fu, Zongyun Mo, and Ligai Bai

Subjects

Materials science, Mechanics of Materials, General Materials Science, Composite material, Ultra high performance, Mortar, Metakaolin, Civil and Structural Engineering

Abstract

The influence of metakaolin (MK) addition on the mechanical and hydration performance of ultra-high-performance (UHP) paste was investigated. UHP mortars were prepared to evaluate the compressive strength when MK was used as a cement replacement at levels of 0, 5, 10, 15 and 20%. The hydration heat evolutions of pastes blended with MK were examined. The chemically bound water and MK reaction degree were determined to assess the hydration reaction degrees of the pastes. Differential thermal analysis, X-ray diffraction, mercury intrusion porosimetry and scanning electron microscopy were carried out to investigate the phase composition and microstructure of pastes. The results showed that the mechanical performance of UHP mortar at an early age is improved by the addition of MK due to its filling effect and pozzolanic reaction. The reaction rate of MK in the pastes significantly decreased at a later age and at a low water-to-binder ratio, but the incorporation of MK still had an improving effect on the mechanical strength of UHP mortars at a later age. The incorporation of MK reduced the content of calcium hydroxide crystals and increased the content of calcium silicate hydrate and calcium aluminium silicate hydrate phases in the pastes. The hardened MK-dosed paste samples showed improved microstructure with lower porosity and a refined pore structure.

Published

2023

27. Highly Accelerated UV Stress Testing for Transparent Flexible Frontsheets

Author

Lance Tamir, David Okawa, Samantha Hoang, Michael D. Kempe, Derek Holsapple, Joshua Morse, Trevor Lockman, Hoi Hong Ng, Peter Hacke, and Michael Owen-Bellini

Subjects

chemistry.chemical_classification, Materials science, Bending (metalworking), Photovoltaic system, Polymer, Polyethylene, Condensed Matter Physics, Electronic, Optical and Magnetic Materials, chemistry.chemical_compound, chemistry, Resist, Ultraviolet light, Fluoropolymer, Crystalline silicon, Composite material, Electrical and Electronic Engineering

Abstract

There are many photovoltaic (PV) applications where lighter weight and/or bendable PV power would be beneficial. This includes the curved surfaces of buildings, buildings with weight limitations, boats, automobiles, or other portable applications. In many of these cases, the bending will be only a single occurrence at installation or the amount of bending, even if repeated, is not dramatic. This allows for crystalline silicon modules to be used. For flexible applications, the dominant material for the frontsheet is polyethylene tetrafluoroethylene (PETFE). As a fluoropolymer it resists soiling, is UV stable, and PETFE is a more mechanically durable fluoropolymer. However, in the interests of keeping costs down, less expensive alternative polymers are desirable. In this study, highly accelerated ultraviolet light and heat stresses are applied to candidate materials and the degradation kinetics are determined to provide information to evaluate their suitability for use in a PV application.

Published

2023

28. ‘Rope effect’ mechanism of self-tapping screws as reinforcement on dowel-type connections

Author

Richard Harris, Wen-Shao Chang, Kiho Jung, and Cong Zhang

Subjects

Mechanism (engineering), Materials science, business.industry, Tapping, Building and Construction, Structural engineering, Dowel, business, Reinforcement, Material technology, Civil and Structural Engineering, Rope

Abstract

The ‘rope effect’ is a positive effect caused by the failure of fasteners of dowel-type connections. A similar mechanism can be found in connections with screw reinforcement. For self-tapping screws used as reinforcement for connections, bending of the self-tapping screws tends to close developed cracks. Utilising the withdrawal resistance provided by the threads on the pointed end of the screw and the pull-through resistance from the screw head, screw reinforcement enhances the embedment strength and splitting resistance of the wood and increases the ductility of the connection. The influence of different thread lengths and locations on reinforcement effectiveness regarding the embedment strength of the timber was investigated in this study. For cases with threads located only on the pointed end, the splitting resistance increased with longer thread length, indicating that the rope effect was progressively enhanced. It was also found that screws with halved thread length demonstrated similar reinforcement effectiveness to fully threaded screws while the partial threads reduced the risk of damaging the screw during installation. A calculation method to predict the load-carrying capacity of screw-reinforced dowel-type connections was also formulated.

Published

2023

29. Effect of organic matter on the shear strength of lime-stabilised clayey soils

Author

Benny Mathews Abraham, Asuri Sridharan, and Annie Joy

Subjects

chemistry.chemical_classification, Materials science, Soil Science, Building and Construction, engineering.material, Geotechnical Engineering and Engineering Geology, chemistry, Mechanics of Materials, Soil stabilization, Soil water, Compressibility, engineering, Shear strength, Organic matter, Geotechnical engineering, Clay soil, Lime

Abstract

Soils containing organic matter exhibit low shear strength and high compressibility. Lime stabilisation has been shown to improve the engineering properties of clayey soils. An attempt was made to study the effect of organic matter (starch and peat) on the shear strength of lime-stabilised clayey soils subjected to longer curing periods (up to 180 days). Most studies have reported the strength behaviour of lime-stabilised organic soils up to 60 days. Vane shear tests were carried out on artificially prepared organic soil mixtures treated with 6% lime after different curing periods (0, 7, 30, 60, 90 and 180 days). The results indicate that the improving effect of lime is deteriorated in the presence of organic matter as the curing period increases. It was observed that, for lime-stabilised clayey soils containing organic matter, the strength seemed to increase up to 30 days, after which it ceased. The strength reduction in lime-stabilised clayey soils containing organic matter depended on the pH and functional groups present in the soil. Fourier transform infrared spectroscopy of cured samples was also carried out to examine the microstructural changes responsible for the strength change in lime-stabilised clayey soils.

Published

2023

30. Effects of fibre additions on the tensile strength and crack behaviour of unsaturated clay

Author

Charles E. Augarde, Jianye Wang, and Paul Hughes

Subjects

Materials science, Mechanics of Materials, Ultimate tensile strength, Soil Science, Building and Construction, Composite material, Geotechnical Engineering and Engineering Geology

Abstract

Desiccation cracking in clay soils is a combined mechanical and hydraulic problem and such soils can be improved by various methods including reinforcement with fibres. The relationships between tensile strength, cracking resistance and water-retention properties of fibre-reinforced fine-grained soils lack coverage in the literature to date. In this study, these three properties are evaluated and connected by way of a series of tensile strength and desiccation cracking tests on fibre-reinforced London clay. The results confirm that increased fibre addition delays the occurrence of peak stress and changes failure behaviour from brittle to ductile. The tensile strength increment gets higher as water content decreases, and reaches a maximum value of 460 kPa when the water content is 12%. The crack intensity factor reduces from 7.20% to 0.89% when 12 mm long fibre is used at a ratio of 0.9%. Fibre reinforcement also changes the crack development pattern by reducing the size of large cracks and increasing the proportion of small individual cracks. However, the presence of fibres was not observed to change the water-retention properties of the soil, indicating that the tensile improvement comes from the pull-out resistance of the fibres rather than suction changes.

Published

2023

31. Effects of Nasalization on Vocal Tract Response Curve

Author

Miriam Havel, Johan Sundberg, Louisa Traser, Michael Burdumy, and Matthias Echternach

Subjects

Materials science, Resonance, LPN and LVN, Mr imaging, Nasalization, Coupling (electronics), 030507 speech-language pathology & audiology, 03 medical and health sciences, Speech and Hearing, 0302 clinical medicine, Nuclear magnetic resonance, Formant, Otorhinolaryngology, otorhinolaryngologic diseases, 030223 otorhinolaryngology, 0305 other medical science, Vocal tract

Abstract

Summary Background Earlier studies have shown that nasalization affects the radiated spectrum by modifying the vocal tract transfer function in a complex manner. Methods Here we study this phenomenon by measuring sine-sweep response of 3-D models of the vowels /u, a, ᴂ, i/, derived from volumetric MR imaging, coupled by means of tubes of different lengths and diameters to a 3-D model of a nasal tract. Results The coupling introduced a dip into the vocal tract transfer function. The dip frequency was close to the main resonance of the nasal tract, a result in agreement with the Fujimura & Lindqvist in vivo sweep tone measurements [Fujimura & Lindqvist, 1972]. With increasing size of the coupling tube the depth of the dip increased and the first formant peak either changed in frequency or was split by the dip. Only marginal effects were observed of the paranasal sinuses. For certain coupling tube sizes, the spectrum balance was changed, boosting the formant peaks in the 2 – 4 kHz range. Conclusion A velopharyngeal opening introduces a dip in the transfer function at the main resonance of the nasal tract. Its depth increases with the area of the opening and its frequency rises in some vowels.

Published

2023

32. Evaluation of the marginal and internal gaps of partially crystallized versus fully crystallized zirconia-reinforced lithium silicate CAD-CAM crowns: An in vitro comparison of the silicone replica technique, direct view, and 3-dimensional superimposition analysis

Author

Alaa El-Ashkar, Adel El-Tannir, and Maha Taymour

Subjects

Materials science, Replica, medicine.medical_treatment, chemistry.chemical_element, Crown (dentistry), Silicate, chemistry.chemical_compound, Silicone, chemistry, Replica Techniques, medicine, Superimposition, Lithium, Cubic zirconia, Oral Surgery, Composite material

Abstract

Statement of problem The crystallization process of lithium disilicate crowns has been reported to cause dimensional change, but whether the fit of chairside computer-aided design and computer-aided manufactured (CAD-CAM) zirconia-reinforced lithium silicate crowns is affected is unclear. Purpose The purpose of this in vitro study was to evaluate with a 3-dimensional superimposition analysis technique the marginal and internal adaptation of fully crystallized versus partially crystallized zirconia-reinforced lithium silicate ceramic CAD-CAM fabricated crowns. Additionally, the silicone replica technique and direct viewing of marginal gap values were compared with the 3-dimensional superimposition analysis technique. Material and methods The marginal and internal adaptation of a fully crystallized zirconia-reinforced lithium silicate (CELTRA DUO) were compared with those of a partially crystallized zirconia-reinforced lithium silicate (VITA SUPRINITY) after crystallization. Sixteen crowns (n=8) were fabricated with a chairside CAD-CAM system. The crowns and die and crown assembly were scanned with an optical scanner for the 3-dimensional superimposition analysis. Four hundred sixty-eight measurements were made for each crown, 78 in each 2-dimensional section. Marginal discrepancy was measured by using the direct viewing technique. The internal adaptation of the shoulder area, axial space, and occlusal space was measured by using the silicone replica technique. Both gap values were compared with the 3-dimensional superimposition analysis results by using the independent t test. The 2-way ANOVA was used to detect the effect of each variable (group and site) (α=.05). Results The VITA SUPRINITY crowns showed statistically higher marginal discrepancy values than the CELTRA DUO crowns in both 3-dimensional superimposition analysis and the direct viewing method, and the lingual aspect recorded the highest marginal discrepancy mean value when compared with other aspects. The 3-dimensional superimposition analysis and the direct viewing method were statistically similar (P=.076). The VITA SUPRINTY crowns showed higher internal gap mean values than the CELTRA DUO crowns in both 3-dimensional superimposition analysis and silicone replica techniques. The occlusal space recorded the highest mean value in both groups. Assessment by 3-dimensional superimposition analysis and silicone replica techniques showed statistical difference in internal gap values (P=.04). Conclusions CELTRA DUO showed better precision fit values than VITA SUPRINITY. Three-dimensional superimposition analysis is a reliable method of evaluating marginal and internal adaptation.

Published

2023

33. Effect of phase-change materials on the hydration and mineralogy of cement mortar

Author

Bibhuti Bhusan Das and K. Snehal

Subjects

Phase change, Materials science, Mechanics of Materials, General Materials Science, sense organs, Composite material, Mortar, skin and connective tissue diseases, Microstructure, Cement mortar, Civil and Structural Engineering

Abstract

The influence of direct incorporation of thermally efficient phase-change materials (PCMs) on the hydration and mineralogical properties of cement mortar was investigated. To assess the viability of bulk addition of PCMs to a cementitious system, tests of the early age, hydration, mechanical, durability and mineralogical properties were carried out. Organic PCMs showed an increase in setting time, while inorganic materials exhibited fast setting characteristics. Surface temperature was also found to be lower for cement paste with incremental dosages of PCM. However, chemical shrinkage was found to be reduced in the presence of PCM except for the inorganic type. It was observed from the results that PCMs negatively influenced the rate of strength development of a cementitious mortar. The slow rate of strength development was found to be attributed to interrupted hydration, which was confirmed through mineralogical studies. Further, from the thermo-gravimetric analysis, it was observed that the presence of PCMs in a cementitious system increased calcium hydroxide content and reduced the content of water related to hydration products.

Published

2023

34. Comparative Evaluation of the Shear Bond Strength and Debonding Properties of a New Self Etch Adhesive Composite Cement and Self Etching Primer Composite System Used for Orthodontic Bracket bonding - An In Vitro Study

Author

S M Laxmikanth and Sameer Ahmad Malik

Subjects

Cement, Orthodontic brackets, Self etch, Materials science, Composite number, General Earth and Planetary Sciences, In vitro study, Composite material, Self etch adhesive, Shear bond, General Environmental Science, Comparative evaluation

Published

2023

35. Concrete moisture diffusivity determination using electrical resistivity measurements

Author

Gasim Ayad Alaswad

Subjects

Materials science, Moisture, Mechanics of Materials, Electrical resistivity and conductivity, General Materials Science, Geotechnical engineering, Thermal diffusivity, Civil and Structural Engineering

Abstract

The movement of water in concrete structures and buildings is a fundamental subject and therefore it is necessary to understand the mechanisms and processes involved. This paper presents a method to estimate the moisture diffusivity of concrete using gravimetric measurements, together with discretised electrical resistivity measurements. To improve the repeatability of the method, various concrete mixes with and without supplementary cementitious materials were tested. The samples were conditioned under two regimes representing poor and good curing; the samples were then exposed to a simulated hot environment with a diurnal temperature fluctuation of 20–40°C and 60% ambient relative humidity. The basis of the method was to measure the amount of water absorbed by the concrete sample at different depths as a function of time and then Boltzmann's transformation was used to analyse the experimental results obtained. Once a master curve using the Boltzmann transformation is formed, the moisture diffusivity can be obtained. The results showed that the relationship between moisture diffusivity and moisture content can be described by an exponential function.

Published

2023

36. Predicting and optimising the surface roughness of additive manufactured parts using an artificial neural network model and genetic algorithm

Author

Osman Ulkir, Gazi Akgun, and Ulkir O., AKGÜN G.

Subjects

Additive manufacturing, Temel Bilimler (SCI), Fizik, MATERIALS SCIENCE, cascade forward artificial neural network, PHYSICS, genetic algorithm, Yoğun Madde Fiziği, box-benken design, General Materials Science, PHYSICS, CONDENSED MATTER, Engineering, Computing & Technology (ENG), Temel Bilimler, fused deposition modelling, Mühendislik, Bilişim ve Teknoloji (ENG), Condensed Matter 1: Structural, Mechanical and Thermal Properties, Condensed Matter Physics, Yoğun Madde 1:Yapısal, Mekanik ve Termal Özellikler, Fizik Bilimleri, Natural Sciences (SCI), Physical Sciences, surface roughness, Genel Malzeme Bilimi, Engineering and Technology, Mühendislik ve Teknoloji, Natural Sciences, FİZİK, YOĞUN MADDE, Malzeme Bilimi

Abstract

The selection of parameters affects the surface roughness in the additive manufacturing process. This study aims to determine the optimal combination of input parameters for predicting and minimising the surface roughness of samples produced by Fused Deposition Modelling on a 3D printer using a cascade-forward neural network (CFNN) and genetic algorithm. Box–Behnken Design with four independent printing parameters at three levels is used, and 25 parts are fabricated with a 3D printer. Roughness tests are performed on the fabricated parts. Models generated by the hybrid algorithm achieve the best results for predicting and optimising surface roughness in 3D-printed parts. The surface roughness prediction accuracy of the trained CFNN with optimised parameters is more accurate compared to previous random test results.

Published

2023

37. Development of Integrated Thermoelectric Sensors for Power Components

Author

P. Faucherand, R. Escoffier, M. Plissonnier, G. Savelli, and C. Bryan

Subjects

Fabrication, Materials science, business.industry, Tension (physics), Transistor, Heterojunction, law.invention, Power (physics), Planar, law, Thermoelectric effect, Optoelectronics, Electrical and Electronic Engineering, business, Fermi gas, Instrumentation

Abstract

Power components such as High Electron Mobility Transistors (HEMTs) are used for high power and high frequency applications. These tend to overheat and destroy their packaging and connections to the wire bondings. This paper presents planar micro-thermoelectric sensors (μTESs) developed to measure partial heat flow dissipated by the HEMTs to avoid the HEMTs from reaching critical temperatures. These sensors use the same active materials as well as the same fabrication process as the HEMTs, enabling them to be fabricated simultaneously for a simple integration. The HEMTs’ active layers consist in AlGaN/GaN heterostructures resulting in the formation of a 2D Electron Gas (2DEG) at the interface. Tension factors of 47 mV/(K.mm2) were obtained with these sensors and heat flows of 0.2 W to 7 W were measured.

Published

2023

38. Evaluación del desempeño térmico de ladrillos ecoamigables con incorporación de residuos de mullita

Author

David Carvajal, Mónica A. Villaquirán-Caicedo, María Camila Viera, Kevin Agudelo, Jonatan Arias, and Erick Hernández-Rengifo

Subjects

Cultural Studies, Linguistics and Language, History, Materials science, ceramic fibre, Metallurgy, ladrillo ecológico, Mullite, clay, recycling, refractarios, eco-friendly bricks, Environmentally friendly, reciclaje, Language and Linguistics, Anthropology, exposición a llama directa, fibra cerámica, refractory, Thermal, direct flame exposure, arcilla

Abstract

Resumen Se produjeron ladrillos de arcilla obtenidos con mezcla de arcilla con residuos de un horno eléctrico en desuso y reforzados con fibras cerámicas para la obtención de un material cerámico con características refractarias. Las mezclas de arcilla/partículas recicladas fueron 50:50 en peso, y la incorporación de fibra fue en un 10 y un 20 % en volumen, para obtener un cerámico por sinterización a 1.000 °C durante 2 h. Los materiales diseñados fueron caracterizados por difracción de rayos X, se determinó la resistencia a compresión, flexión, densidad, porosidad y absorción. También se comprobó su desempeño térmico por exposición directa a llama 1.000 °C. Los resultados mostraron que en la medida en que se incorpora fibra cerámica la resistencia a compresión disminuyó un 17,3 % para AF10 y un 17,0 % para AF20. Los valores de resistencia a flexión estuvieron en 3,4 MPa. El coeficiente de conductividad térmica fue de 0,5322 W/mK, y durante la exposición directa a la llama, las muestras lograron un gradiente térmico de -700 °C para muestras de 2 cm de espesor. Las fases mineralógicas obtenidas para los ladrillos fueron mullita, corindón y cordierita, las cuales se consideran refractarias. Abstract The aim of this research was the production of clay-brick, from red clay, waste from a disused electric furnace, reinforced with ceramic fibers, to obtain a ceramic material with refractory characteristics. The clay/waste particle proportion was 50:50 by weight, and the incorporation of fiber was 10% and 20% by volume, to obtain a ceramic by sintering at 1000°C, for 2 hours. The designed materials were characterized by X-ray diffraction, the flexural and compressive strength, density, porosity, and absorption were determined. The thermal performance was also verified by direct exposure to 1000°C flame. The results showed that as ceramic fiber was incorporated, the compressive strength decreased by 17.3% for AF10 and 17.0% for AF20. The flexural strength values were at 3.4 MPa. The coefficient of thermal conductivity was 0.5322 W/m.K, and, during direct flame exposure, the samples achieved a thermal gradient of ~ 700 °C for samples 2 cm thick. The mineralogical phases obtained for the bricks were mullite, corundum, and cordierite, which are considered refractory.

Published

2023

39. Developing super-hydrophobic and corrosion-resistant coating on magnesium-lithium alloy via one-step hydrothermal processing

Author

Jiangbo Cheng, Xiaolong Ma, Yanxin Qiao, Jinghua Jiang, Aibin Ma, Dan Song, Huan Liu, and Guowei Wang

Subjects

Materials science, Magnesium, Alloy, technology, industry, and agriculture, Metals and Alloys, chemistry.chemical_element, engineering.material, Microstructure, Surface energy, Hydrothermal circulation, Corrosion, Coating, Chemical engineering, chemistry, Mechanics of Materials, engineering, Lithium

Abstract

Formation of super-hydrophobic and corrosion-resistant coatings can provide significant corrosion protection to magnesium alloys. However, it remains a grand challenge to produce such coatings for magnesium-lithium alloys due to their high chemical reactivity. Herein, a one-step hydrothermal processing was developed using a stearic-acid-based precursor medium, which enables the hydrothermal conversion and the formation of low surface energy materials concurrently to produce the super-hydrophobic and corrosion-resistant coating. The multiscale microstructures with nanoscale stacks and microscale spheres on the surface, as well as the through-thickness stearates, lead to the super-hydrophobicity and excellent corrosion resistance of the obtained coating.

Published

2023

40. Dynamic crushing behaviors and enhanced energy absorption of bio-inspired hierarchical honeycombs with different topologies

Author

Nan-nan Liu, He-xiang Wu, Na Li, Ke-ming Hao, Xin-chun Zhang, and Chao-chao An

Subjects

Materials science, Mechanical Engineering, Metals and Alloys, Computational Mechanics, Shell (structure), Topology, Network topology, Finite element method, Shock (mechanics), Controllability, Ceramics and Composites, Honeycomb, Bearing capacity, Efficient energy use

Abstract

In order to pursue good crushing load uniformity and enchance energy absorption efficiency of conventional honeycombs, a kind of bio-inspired hierarchical honeycomb model is proposed by mimicking the arched crab shell structures. Three bio-inspired hierarchical honeycombs (BHHs) with different topologies are designed by replacing each vertex of square honeycombs with smaller arc-shaped structures. The effects of hierarchical topologies and multi-material layout on in-plane dynamic crushings and absorbed-energy capacities of the BHHs are explored based on the explicit finite element (FE) analysis. Different deformation modes can be observed from the BHHs, which mainly depend upon hierarchical topologies and impact velocities. According to energy efficiency method and one-dimensional (1D) shock theory, calculation formulas of densification strains and plateau stresses for the BHHs are derived to characterize the dynamic bearing capacity, which is consistent well with FE results. Compared with conventional honeycombs, the crushing load efficiency and energy absorption capacity of the BHHs can be improved by changing the proper hierarchical topology and multi-material layout. These researches will provide theoretical guidance for innovative design and dynamic response performance controllability of honeycombs.

Published

2023

41. Metal organic framework supported niobium pentoxide nanoparticles with exceptional catalytic effect on hydrogen storage behavior of MgH2

Author

Farai Michael Nyahuma, Lixin Chen, Changshan Cheng, Fuying Wu, Haoyu Zhang, Liuting Zhang, and Jiaguang Zheng

Subjects

Materials science, Hydrogen, Renewable Energy, Sustainability and the Environment, chemistry.chemical_element, Activation energy, Catalysis, law.invention, chemistry.chemical_compound, Hydrogen storage, chemistry, Chemical engineering, law, Metal-organic framework, Dehydrogenation, Calcination, Niobium pentoxide

Abstract

Nb2O5 nanoparticles with an average particle size of 10 nm supported on a rhombic dodecahedral metal organic framework (MOF) were successfully synthesized by a facile one-pot hydrothermal reaction and subsequent calcination process. Experimental results demonstrated that the prepared catalyst drastically improved the hydrogen storage behavior of MgH2. 7 wt% Nb2O5@MOF doped MgH2 started to desorb hydrogen at 181.9 °C and 6.2 wt% hydrogen could be released within 2.6 min and 6.3 min at 275 °C and 250 °C, respectively. The fully dehydrogenated composite also displayed excellent hydrogenation by decreasing the onset absorption temperature to 25 °C and taking up 4.9 wt% and 6.5 wt% hydrogen within 6 min at 175 °C and 150 °C, respectively. Moreover, the corresponding activation energy was calculated to be 75.57 ± 4.16 kJ mol−1 for desorption reaction and 51.38 ± 1.09 kJ mol−1 for absorption reaction. After 20 cycles, 0.5 wt% hydrogen capacity was lost for the MgH2+7 wt% Nb2O5@MOF composite, much lower than 1.5 wt% of the MgH2+7 wt% Nb2O5 composite. However, the addition of Nb2O5@MOF had limited effect on reducing the dehydrogenation enthalpy of MgH2. Microstructure analysis revealed that Nb2O5 particles were uniformly distributed on surface of the MgH2 matrix and synergistically improved the hydrogen storage property of MgH2 with MOF.

Published

2023

42. Burning rate analysis of laser controlled 5-aminotetrazole propellant

Author

Ruiqi Shen, Luigi T. DeLuca, Yinghua Ye, Lizhi Wu, Zhang Wei, and Nianbai He

Subjects

Propellant, Materials science, Laser ablation, Mechanical Engineering, Nuclear engineering, Micro computed tomography, Metals and Alloys, Computational Mechanics, Propulsion, Combustion, Laser, 5-Aminotetrazole, law.invention, chemistry.chemical_compound, chemistry, law, Ceramics and Composites, Combustor

Abstract

As an innovative propulsion technique, laser augmented chemical propulsion (LACP) seems superior to the traditional ones. However, the corresponding combustion theories have still to be ascertained for LACP. Burning rate of 5-aminotetrazole (5-ATZ) propellant has been studied by testing pressed samples under different combustor pressures and laser powers. Based on micro computed tomography (MicroCT), an advanced thickness-over-time (TOT) method to characterize the regression of the produced non-planar burning surface is established. Because of a shell structure covering the combustion surface, the burning rate of the implemented 5-ATZ propellant is not constant during laser ablation. Resorting to functional fitting, a new law of non-constant burning including the effect of the observed unique burning surface structures is proposed. Accordingly, applicable combustion conditions of 5-ATZ based propellants have been preliminarily speculated for future research activities.

Published

2023

43. The prediction of the polarization curves of a solid oxide fuel cell anode with an artificial neural network supported numerical simulation

Author

Marek Gnatowski, Grzegorz Brus, and Szymon Buchaniec

Subjects

Materials science, Computer simulation, Artificial neural network, Renewable Energy, Sustainability and the Environment, Energy Engineering and Power Technology, Charge (physics), Mechanics, Condensed Matter Physics, Anode, Fuel Technology, Test set, Solid oxide fuel cell, Polarization (electrochemistry), Transport phenomena

Abstract

The presented study focuses on a numerical simulation of the transport phenomena inside a solid oxide fuel cell anode. The classical mathematical model leads to a notable discrepancy between measured and predicted overpotentials. One of the possible reasons is the assumption of the constant values of electrochemical reaction charge transfer coefficients. A modified formulation of the problem includes data-driven correction of reaction charge transfer coefficients in the electrochemical reaction model. Here we show a dedicated computational scheme in which an artificial neural network updates the charge transfer coefficients depending on the operational conditions and the available datasets. The neural network was trained on twelve experimental data points of an anode's polarization curve obtained from the literature. The training set contained data for the anode operating in two different temperatures - 800 °C and 900 °C. The test set contained additional six data points for an anode operating at 1000 °C. Charge transfer coefficients were proposed by the Artificial Neural Network as a functional relation of the temperature and withdrawn current. The results of the predictions are juxtaposed with the experimental data from the literature. It was shown that an Artificial Neural Network could improve an electrochemical reaction model in Solid Oxide Fuel Cell modeling.

Published

2023

44. Asymmetric behavior of solid oxide cells between fuel cell and electrolyzer operations

Author

Masashi Kishimoto, Hideo Yoshida, Hiroshi Iwai, Haewon Seo, and Yuya Tanimura

Subjects

Electrolysis, Materials science, Standard hydrogen electrode, Hydrogen, Renewable Energy, Sustainability and the Environment, Diffusion, Energy Engineering and Power Technology, Thermodynamics, chemistry.chemical_element, Numerical simulation, Partial pressure, Overpotential, Reversible operation, Condensed Matter Physics, Electrochemistry, Solid oxide electrolysis cell, law.invention, Fuel Technology, Knudsen diffusion, chemistry, Solid oxide fuel cell, law, Asymmetric behavior

Abstract

The electrochemical performance of solid oxide cells (SOCs) is investigated under both fuel cell and electrolyzer operations to understand their asymmetric behavior between the two operation modes. The current–voltage and electrochemical impedance characteristics of a hydrogen-electrode-supported cell are experimentally analyzed. Also, a numerical model is developed to reproduce the cell performance and to understand the internal resistances of the cell. Partial pressures of supplied gas and load current are varied to evaluate their effects on the cell performance. The gas partial pressures of hydrogen and steam supplied to the hydrogen electrode are kept equivalent so that the cell performance can be fairly compared between the two operation modes when the same current is applied. It is found that the origin of the asymmetry is mostly from the hydrogen electrode; both activation and concentration overpotentials show asymmetric behavior particularly at high current densities. A numerical experiment is also conducted by deliberately changing parameters in the model. Asymmetry in the activation overpotential is found to be originated from the non-identical charge-transfer coefficients in the Butler–Volmer equation and also from the non-uniform gas concentration formed in the hydrogen electrode under current-biased conditions. On the other hand, asymmetry in the concentration overpotential is associated with the non-equimolar counter diffusion of hydrogen and steam caused by the effect of Knudsen diffusion. Therefore, enhancing gas transport in the hydrogen electrode and reducing the contribution of Knudsen diffusion are effective approaches to reduce asymmetry not only in the concentration overpotential but also in the activation overpotential.

Published

2023

45. Microstructures and electrochemical behaviors of casting magnesium alloys with enhanced compression strengths and decomposition rates

Author

Qingyuan Yu, Xi Chen, Qiaoxin Zhang, and Xuewu Li

Subjects

Materials science, Alloy, Metals and Alloys, engineering.material, Microstructure, Casting, Decomposition, Corrosion, Compressive strength, Mechanics of Materials, engineering, Magnesium alloy, Composite material, Dissolution

Abstract

New-type magnesium alloy with prominent solubility and mechanical property lays foundation for preparing fracturing part in petroleum extraction. Herein, Mg-xZn-Zr-SiC alloy is prepared with casting strategy. Electrochemical and compression tests are conducted to assess the feasibility as decomposable material. Morphology, composition, phase and distribution are characterized to investigate decomposition mechanism. Results indicate that floccule, substrate component and reticulate secondary phase are formed on as-prepared surface. Sample also acts out enhanced compression strength to maintain pressure and guarantee stability in dissolution process. Furthermore, as decomposition time and zinc content increase, couple corrosion intensifies, resulting in gradually enhanced decomposition rate. Rapid sample decomposition is mainly due to basal anode dissolution, micro particle exfoliation and poor decomposition resistance of corroding product. Such work shows profound significance in preparing new-type accessible alloy to ensure rapid dissolution of fracturing part and guarantee stable compression strength in oil-gas reservoir exploitation.

Published

2023

46. Deflagration to detonation transition in weakly confined conditions for a type of potentially novel green primary explosive: Al/Fe2O3/RDX hybrid nanocomposites

Author

Guixiang Liu, Chao Wu, Xinping Long, Fude Nie, and Qingping Luo

Subjects

Deflagration to detonation transition, Nanocomposite, Materials science, Explosive material, Chemical engineering, Mechanical Engineering, Chemical constituents, Flame propagation, Metals and Alloys, Ceramics and Composites, Computational Mechanics, Combustion

Abstract

The properties of the combustion and deflagration to detonation transition (DDT) of Al/Fe2O3/RDX hybrid nanocomposites, a type of potentially novel lead-free primary explosives, were tested in weakly confined conditions, and the interaction of Al/Fe2O3 nanothermite and RDX in the DDT process was studied in detail. Results show that the amount of the Al/Fe2O3 nanothermite has a great effect on the DDT properties of Al/Fe2O3/RDX nanocomposites. The addition of Al/Fe2O3 nanothermite to RDX apparently improves the firing properties of RDX. A small amount of Al/Fe2O3 nanothermite greatly increases the initial combustion velocity of Al/Fe2O3/RDX nanocomposites, accelerating their DDT process. When the contents of Al/Fe2O3 nanothermite are less than 20 wt%, the DDT mechanisms of Al/Fe2O3/RDX nanocomposites follow the distinct abrupt mode, and are consistent with that of RDX, though their DDT processes are different. The RDX added into the Al/Fe2O3 nanothermite increases the latter's peak combustion velocity and makes it generate the DDT when the RDX content is at least 10 wt%. RDX plays a key role in the shock compressive combustion, the formation and the properties of the DDT in the flame propagation of nanocomposites. Compared with RDX, the fast DDT of Al/Fe2O3/RDX nanocomposites could be obtained by adjusting the chemical constituents of nanocomposites.

Published

2023

47. A novel strategy for loading metal cocatalysts onto hollow nano-TiO2 inner surface with highly enhanced H2 production activity

Author

Ruixin Wang, Weizhou Jiao, Chen Nan, Yu Zhou, and Songtao Cao

Subjects

chemistry.chemical_classification, Materials science, Renewable Energy, Sustainability and the Environment, Composite number, Quantum yield, chemistry.chemical_element, Polymer, Metal, chemistry.chemical_compound, chemistry, Chemical engineering, visual_art, Photocatalysis, visual_art.visual_art_medium, Methanol, Pyrolysis, Carbon

Abstract

The loading strategy of cocatalysts affects its activity exerting and atom utilization. Here, a novel strategy for loading precious metal (Pt) cocatalysts by means of ultrathin N-doped carbon layer is reported. The strategy is based on a pyrolysis process of predesigned N-containing polymers and Pt complexes on hard-template surface, during which Pt can be reduced by carbon from pyrolysis at high temperatures. Finally, the hollow TiO2 composite with stable and dispersed Pt on its inner surface was prepared. It shows an ultrahigh photocatalytic H2 production activity as high as 25.7 mmol h−1 g−1 with methanol as sacrificial regent, and displays an apparent quantum yield as 13.2%. The improved photocatalytic activity and stability can be attributed to the highly dispersed and ultrafine Pt nanoparticles, enhanced interaction between Pt-species and carbon support, fast photo-excited electron transport from the high graphitization degree of NC layers, ample oxygen vacancies/defects, as well as the manipulated local charge distribution of Pt/NC-layer configuration. Additionally, the universality of the proposed strategy was demonstrated by replacing metal sources (such as, Ru and Pd). This work presented a promising strategy for the design and development of novel photocatalysts, which shows a broad application prospect.

Published

2023

48. Visible light triggered exfoliation of COF micro/nanomotors for efficient photocatalysis

Author

Kai Feng, Liang Zhang, Ran Niu, Jiang Gong, and Jinping Qu

Subjects

Materials science, Chemical engineering, Renewable Energy, Sustainability and the Environment, Metal ions in aqueous solution, Photocatalysis, Ionic bonding, Nanoparticle, Particle size, Dispersion (chemistry), Exfoliation joint, Visible spectrum

Abstract

We report a new facile light-induced strategy to disperse micron-sized aggregated bulk covalent organic frameworks (COFs) into isolated COFs nanoparticles. This was achieved by a series of metal-coordinated COFs, namely COF-909-Cu, -Co or -Fe, where for the first time the diffusio-phoretic propulsion was utilized to design COF-based micro/nanomotors. The mechanism studies revealed that the metal ions decorated in the COF-909 backbone could promote the separation of electron and holes and trigger the production of sufficient ionic and reactive oxygen species under visible light irradiation. In this way, strong light-induced self-diffusiophoretic effect is achieved, resulting in good dispersion of COFs. Among them, COF-909-Fe showed the highest dispersion performance, along with a drastic decrease in particle size from 5 μm to 500 nm, within only 30 min light irradiation, which is inaccessible by using traditional magnetic stirring or ultrasonication methods. More importantly, benefiting from the outstanding dispersion efficiency, COF-909-Fe micro/nanomotors were demonstrated to be efficient in photocatalytic degradation of tetracycline, about 8 times faster than using traditional magnetic stirring method. This work opens up a new avenue to prepare isolated nanosized COFs in a high-fast, simple, and green manner.

Published

2023

49. Moment redistribution in reinforced concrete castellated beams with external pre-stressing

Author

Abdelaziz Nabil, Nesreen M. Kassem, and Hamdy M. Afefy

Subjects

Pre stressing, Materials science, business.industry, Building and Construction, Structural engineering, Moment redistribution, Reinforced concrete, business, Civil and Structural Engineering

Abstract

This paper presents the results of both experimental and numerical investigations on the overall structural performance of two-equal-span reinforced concrete perforated (castellated) beams subjected to external pre-stressing. First, the effects of providing castellated openings along with the application of external pre-stressing on both the ultimate capacity and the percentage of moment redistribution were investigated experimentally. Then, after validation of the numerical modelling, the effects of controlling the parameters on the percentage of moment redistribution were investigated numerically. Experimental results showed that providing castellated openings accelerated the appearance of both flexural and shear cracks, and decreased the ultimate capacity by about 24% compared to that of a solid beam. Moreover, application of external pre-stressing on the castellated beam compensated for the reduction in ultimate capacity and outperformed it by about 9% compared to that of a solid beam. Based on the numerical results, it appears to be better to increase the amount of main tensile steel and strand eccentricity at the hogging moment zone, as well as increase the effective pre-stressing force, to reduce the percentage of moment redistribution at both sagging and hogging moments.

Published

2023

50. Phthalocyanine-derived catalysts decorated by metallic nanoclusters for enhanced CO2 electroreduction

Author

Minghui Zhu, Jiayu Li, Jing Xu, Yi-Fan Han, and Jiacheng Chen

Subjects

In situ, Materials science, Renewable Energy, Sustainability and the Environment, 02 engineering and technology, 010402 general chemistry, 021001 nanoscience & nanotechnology, Photochemistry, Electrochemistry, 01 natural sciences, 0104 chemical sciences, Catalysis, Nanoclusters, Metal, chemistry.chemical_compound, Electron transfer, chemistry, visual_art, Phthalocyanine, visual_art.visual_art_medium, 0210 nano-technology

Abstract

Electrochemical CO2 reduction (CO2RR) over molecular catalysts is a paramount approach for CO2 conversion to CO. Herein, we report a novel phthalocyanine-derived catalyst synthesized by a two-step method with a much improved electroconductivity. Furthermore, the catalyst contains both Ni–N4 sites and highly dispersed metallic Ni nanoclusters, leading to an increased CO2RR currents by two folds. Isotope labelling study and in situ spectroscopic analysis demonstrate that the existence of metallic Ni nanoclusters is the key factor for the activity enhancement and can shift the CO2RR mechanism from being electron transfer (ET)-limited (forming ∗COO−) to concerted proton-electron transfer (CPET)-limited (forming CO).

Published

2023