Your search keyword '"MECHANICAL-PROPERTIES"' showing total 2,087 results

1. DNA hydrogels and their derivatives in biomedical engineering applications

Author

Rui Wu, Wenting Li, Pu Yang, Naisi Shen, Anqi Yang, Xiangjun Liu, Yikun Ju, Lanjie Lei, and Bairong Fang

Subjects

DNA hydrogels, Self-assembly, Crosslinking, Mechanical-properties, Biomedical application, Biotechnology, TP248.13-248.65, Medical technology, R855-855.5

Abstract

Abstract Deoxyribonucleotide (DNA) is uniquely programmable and biocompatible, and exhibits unique appeal as a biomaterial as it can be precisely designed and programmed to construct arbitrary shapes. DNA hydrogels are polymer networks comprising cross-linked DNA strands. As DNA hydrogels present programmability, biocompatibility, and stimulus responsiveness, they are extensively explored in the field of biomedicine. In this study, we provide an overview of recent advancements in DNA hydrogel technology. We outline the different design philosophies and methods of DNA hydrogel preparation, discuss its special physicochemical characteristics, and highlight the various uses of DNA hydrogels in biomedical domains, such as drug delivery, biosensing, tissue engineering, and cell culture. Finally, we discuss the current difficulties facing DNA hydrogels and their potential future development. Graphical Abstract

Published

2024

2. DNA hydrogels and their derivatives in biomedical engineering applications

Author

Wu, Rui, Li, Wenting, Yang, Pu, Shen, Naisi, Yang, Anqi, Liu, Xiangjun, Ju, Yikun, Lei, Lanjie, and Fang, Bairong

Published

2024

3. CSN 12050 Carbon Steel Mechanical Property Enhancement Using Thermal Treatment to Optimize Product Sustainability

Author

Wakjira, Melesse Workneh, Altenbach, Holm, Ramulu, Perumalla Janaki, Akan, Ozgur, Series Editor, Bellavista, Paolo, Series Editor, Cao, Jiannong, Series Editor, Coulson, Geoffrey, Series Editor, Dressler, Falko, Series Editor, Ferrari, Domenico, Series Editor, Gerla, Mario, Series Editor, Kobayashi, Hisashi, Series Editor, Palazzo, Sergio, Series Editor, Sahni, Sartaj, Series Editor, Shen, Xuemin (Sherman), Series Editor, Stan, Mircea, Series Editor, Xiaohua, Jia, Series Editor, Zomaya, Albert Y., Series Editor, Zimale, Fasikaw Atanaw, editor, Enku Nigussie, Temesgen, editor, and Fanta, Solomon Workneh, editor

Published

2019

4. Comparison of thermal and mechanical properties of γ′-Pt3Al and γ′-Ni3Al phases: A first principles study.

Author

Zhang, Xiao, Zhou, Xiao-long, Yao, Bi-xia, Yu, Jie, and Wang, Li-hui

Abstract

Copyright of Journal of Central South University is the property of Springer Nature 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

2022

5. In search of the elusive IrB2: Can mechanochemistry help?

Author

Lis, Jerzy [AGH - Univ. of Science and Technology, Krakow (Poland)]

Published

2015

6. A precipitation-hardened high-entropy alloy with outstanding tensile properties

Author

Lu, Z. [University of Science and Technology Beijing (China). State Key Laboratory for Advanced Metals and Materials] (ORCID:0000000314638948)

Published

2015

7. Chitosan binders for sustainable lithium-sulfur batteries: Synergistic effects of mechanical and polysulfide trapping properties.

Author

Mayrén, Alfonso, Alcaraz-Espinoza, José Jarib, Hernández-Sánchez, Arturo, González, Ignacio, and Ramos-Sánchez, Guadalupe

Subjects

*POLYSULFIDES, *LITHIUM sulfur batteries, *CHITOSAN, *POLYMER networks, *LITHIUM cells, *TENSILE tests, *BIOPOLYMERS

Abstract

The lithium-sulfur (Li-S) system is a promising candidate for the next generation of lithium batteries; however, for practical applications, there are still problems to solve as the loss of active material due to polysulfides diffusion and migration (shuttle effect), passivation of interfaces of both electrodes by deposition of insulating species. Chitosan, as an abundant and sustainable biopolymer has been previously modified to solve issues related to polysulfides retention through biopolymer functionalization; however, the effect of such modifications on the mechanical properties, related to the structural modifications, has been poorly investigated; moreover, the coupled effects of both phenomena, polysulfide trapping capacity and mechanical properties, and its impact on battery capacity and cyclability has not been discussed. In order to determine those effects, in this work is proposed a new binder based on chitosan modified by Methanesulfonic Acid as a plasticizer in the fabrication of sulfur cathodes for Li-S batteries. The improvement in the overall performance of the system was investigated by C-Rate, deep cycling and tensile test, and the results were compared with those of the sulfur cathode using brittle and water-insoluble pristine chitosan as binder. Our results indicated that the Chitosan – Methanesulfonic Acid, ChMSA25 polymer network, is able to modulate the mechanical strength and binding performance of the system. Due to the aforementioned characteristics, the ChMSA25 based sulfur cathode exhibits a low-capacity fade (0.058% per cycle) at 1.0 C for 500 cycles. Therefore, the ChMSA25 binder is a promising candidate for the development of high-performance, water processable lithium-sulfur batteries. [ABSTRACT FROM AUTHOR]

Published

2024

8. Review of novel energetic polymers and binders – high energy propellant ingredients for the new space race

Author

Tianze Cheng

Subjects

energetic-binder, azide, propellant, solid-propellant, energetic-materials, specific-impulse, mechanical-properties, htpb, Polymers and polymer manufacture, TP1080-1185

Abstract

Current solid rocket propellant formulations still employ traditional ingredients utilized since the 1960s, such as hydroxyl terminated polybutadiene (HTPB). Recent advances in energetic polymer see many binders capable of providing higher specific impulse and burn rates over HTPB. As shown by calculations, even slight increases in specific impulse can drastically increase the maximum payload of a launch system. Therefore, replacing HTPB with energetic binders could provide heavy space missions the needed extra boost. Energetic binders could also be paired with chlorine-free energetic oxidizers to synergistically provide a specific impulse exceedingly higher than the current formulation while reducing pollution. A comprehensive evaluation of the synthesis, mechanical properties, and performance of various trending and overlooked energetic polymers is described. Several outstanding candidates show promising properties to replace HTPB.

Published

2019

9. A comparative analysis of the effect of post production treatments and layer thickness on tensile and impact properties of additively manufactured polymers

Author

Çağın Bolat, Berkay Ergene, and Hasan Ispartalı

Subjects

Polymers and Plastics, heat treatment, General Chemical Engineering, Mechanical-Properties, Industrial and Manufacturing Engineering, Parts, water absorption, Materials Chemistry, Pla, impact strength, layer thickness, Strength, fused filament fabrication, 3d

Abstract

In recent years, additive manufacturing (AM) technologies have become greatly popular in the polymer, metal, and composite industries because of the capability for rapid prototyping, and appropriateness for the production of complex shapes. In this study, a comprehensive comparative analysis focusing on the influence of post-processing types (heat treatment and water absorption) on tensile and impact responses was carried out on 3D printed PETG, PLA, and ABS. In addition, layer thickness levels (0.2, 0.3, and 0.4 mm) were selected as a major production parameter and their effect on mechanical properties was combined with post-processing type for the first time. The results showed that both tensile and impact resistance of the printed polymers increased thanks to the heat treatment. The highest tensile strength was measured for heat-treated PLA, while the peak impact endurance level was reached for heat-treated PETG. Also, water absorption caused a mass increment in all samples and induced higher tensile elongation values. Decreasing layer thickness had a positive effect on tensile features, but impact strength values dropped. On the other hand, all samples were subjected to macro and micro failure analyses to understand the deformation mechanism. These inspections indicated that for impact samples straight crack lines converted to zigzag style separation lines after the heat treatment. As for the tensile samples, the exact location of the main damage zone altered with the production stability, the water absorption capacity of the polymer, and the thermal diffusion ability of the filament.

Published

2023

10. Comparison of the Color Change of Porcelain Laminate Veneers Produced by Different Materials After Luting with Three Resin Cements

Author

Karaokutan, I, Aykent, F., and Özdoğan, M. S.

Subjects

Surface, Internal Fit, Optical-Properties, Mechanical-Properties, Strength, Translucency, Thickness, Stability, Microstructure, General Dentistry, Exposure

Abstract

SUMMARYObjectivesThis study aimed to compare color change of porcelain laminate veneers fabricated with two lithium disilicate ceramics and a zirconia-reinforced lithium silicate ceramic material after luting with conventional dual-cure, amine-free dual-cure, or light-cure resin cements using artificial accelerated aging (AAA).Methods and MaterialsNinety noncarious human maxillary central incisors were embedded in autopolymerizing acrylic resin blocks to prepare conventional laminate veneers with incisal coverage. Prepared teeth were randomly divided into 3 groups (n=30) to fabricate laminate veneer restorations using: (1) lithium disilicate ceramic, (2) lithium disilicate ceramic with high-density micronization, and (3) zirconia-reinforced lithium silicate ceramic. Impressions of the preparations were taken with a laboratory scanner. Acquired 3D images were processed into a surface tessellation language file. Data were exported for 3D printing on a printer, and laminate veneers were printed in castable wax resin. Ceramic veneers were heat-pressed after investment according to the manufacturer’s recommendations and further divided into three groups (n=10) according to luting cement type: (1) light-cure resin cement, (2) amine-free dual-cure resin cement, and (3) conventional dual-cure resin cement. Color measurements were performed from the middle of each specimen with a spectrophotometer before and after AAA for 300 hours with a total energy of 150 kJ/m2. Color changes were calculated with the CIEDE 2000 (ΔE00) formula. Color differences were assessed using two-way analysis of variance (ANOVA) (α=0.05), and the paired t-test was used to compare the L*, a*, and b* parameters in each group before and after aging.ResultsThere were no significant differences between the ceramic groups (p>0.05). The color changes of the materials ranged from 2.26 to 3.13. All materials were above the clinically acceptable limit (ΔE00>1.8). The conventional dual-cure resin cement group showed more color change (p>0.05).ConclusionsColor changes were observed in all porcelain laminate veneers after artificial accelerated aging. The zirconia-reinforced lithium silicate veneers showed similar color changes as lithium disilicate veneers; the amine-free dual-cure resin cement showed a similar color change as light-cure resin cement after aging.

Published

2023

11. Dissimilar Welding Applications and Evaluation of Fatigue Behaviour of Welded Jo ints: An Overview

Author

Karakaş, O., Kardeş, F. B., Foti, P., and Berto, F.

Subjects

fatigue strength, Aluminum-Alloy, Austenitic Stainless-Steel, dissimilar weld, Mechanical-Properties, Inconel 625, mechanical properties, Microstructure Characteristics, Joint Properties, dissimilar metal couples, Mechanics of Materials, Carbon-Steel, Resistance Spot Welds, Al-Alloy, Intermetallic Layer

Abstract

Recently, the welding of dissimilar metals has attracted great interest due to its widespread use in engineering building applications. In this article, welding methods of dissimilar metal joints containing different metal types with different chemical compositions are examined and their fatigue behavior is evaluated. In dissimilar metal welds, the difference in chemical composition affects the weldability and mechanical properties of the joints. In this study, the factors affecting the fatigue strength of dissimilar welded joints are described. Since welded structures can be used in sensitive and risky places, welding quality and mechanical properties of the weld are extremely important. In the research, a detailed literature review was presented by evaluating the latest studies on the mechanical properties of dissimilar welded joints such as fatigue strength, tensile strength, hardness, and the latest developments in the welding of different metals were reviewed. This study, which deals with the latest developments in the joining of different metal alloy combinations, is expected to increase the interest of the researchers in the future.

Published

2023

12. Fabrication and characterization of electrospun GelMA/PCL/CS nanofiber composites for wound dressing applications

Author

Esra Pilavci, Musa Ayran, Dilay Ulubay, Elif Kaya, Gulgun Tinaz, Ozlem Bingol Ozakpinar, Aykut Sancakli, Oguzhan Gunduz, and Pilavci E., Ayran M., Ulubay D., Kaya E., TINAZ G., Ozakpinar O. B., Sancakli A., GÜNDÜZ O.

Subjects

Malzeme Bilimi (çeşitli), MATERIALS SCIENCE, BIOMATERIALS, Polymers and Plastics, Mikrobiyoloji, Kimya (çeşitli), Temel Bilimler (SCI), Mechanical-Properties, wound dressing, Physical Chemistry, MATERIALS SCIENCE, Applied Microbiology and Biotechnology, Kimya, Polimerler ve Plastikler, CHEMISTRY, Cross-Linking, Materials Chemistry, General Materials Science, GelMA, Moleküler Tıp, Temel Bilimler, Polimer Karakterizasyonu, Fizikokimya, Life Sciences, BIOTECHNOLOGY & APPLIED MICROBIOLOGY, Hydrogels, POLİMER BİLİMİ, Chemistry (miscellaneous), Natural Sciences (SCI), Physical Sciences, Engineering and Technology, Molecular Medicine, Natural Sciences, Biotechnology, MICROBIOLOGY, Characterization of Polymers, Materials Science (miscellaneous), Life Sciences (LIFE), POLYMER SCIENCE, Bioengineering, Biomaterials, Yaşam Bilimleri, Engineering, Computing & Technology (ENG), Scaffolds, Electrospinning, Mühendislik, Bilişim ve Teknoloji (ENG), General Chemistry, Genel Kimya, BİYOTEKNOLOJİ VE UYGULAMALI MİKROBİYOLOJİ, Fizik Bilimleri, Yaşam Bilimleri (LIFE), Biyomalzemeler, Uygulamalı Mikrobiyoloji ve Biyoteknoloji, Release, MALZEME BİLİMİ, BİYOMATERYAL, Genel Malzeme Bilimi, Mühendislik ve Teknoloji, Biyoteknoloji, Malzeme Bilimi

Abstract

In the present study, the effect of different ratios of GelMA concentration has been exhibited for wound dressing implementation by the electrospinning method using a new polymer combination of Gelatin methacrylate (GelMA)/Polycaprolactone (PCL)/Chitosan (CS). The nanofiber composites were fabricated due to their biocompatible, biodegradable, improved mechanical strength, low degradation rate, and hydrophilic nature to develop cell-mimicking, cell adhesion, proliferation, and differentiation. Different concentrations of GelMA were added to the PCL/CS solution as 5, 10, and 20 wt%, respectively, in the formic acid/acetic acid (7:3) solution. A photoinitiator was added to the solution for photo-crosslinking of GelMA. The influence of different solution concentrations (5, 10, and 20 wt%) on the structure’s nanofiber production and fiber morphology was examined. SEM micrographs revealed that varied GelMA concentrations resulted in suitable and stable nanofiber composites. The average diameter of nanofiber composites grows as the GelMA concentration rises. FTIR, DSC, tensile test, degradation, and swelling test were evaluated. The results demonstrated that high mechanical strength, hydrophilic properties, and a slow degradation rate were observed with the presence and increment of GelMA concentration within the nanofiber composites. The antibacterial potential of GelMA/PCL/CS nanofiber composites was evaluated against P. aeruginosa and S. aureus using a disc diffusion assay. In vitro cell culture research was conducted by seeding NIH 3T3 fibroblast cells on nanofiber composites, proving these cells’ high cell proliferation rate, viability, and adhesion. 10 wt% GelMA-based nanofiber composites were found to have great potential for wound dressing applications.

Published

2022

13. Concentration Independent Modulation of Local Micromechanics in a Fibrin Gel

Author

Kotlarchyk, Maxwell A., Shreim, Samir G., Alvarez-Elizondo, Martha B., Estrada, Laura C., Singh, Rahul, Valdevit, Lorenzo, Kniazeva, Ekaterina, Gratton, Enrico, Putnam, Andrew J., and Botvinick, Elliot L.

Subjects

extracellular-matrix mimics, mechanical-properties, endothelial-cells, particle tracking, stress fibers, mesh size, hydrogels, elasticity, migration, behavior

Abstract

Methods for tuning extracellular matrix (ECM) mechanics in 3D cell culture that rely on increasing the concentration of either protein or cross-linking molecules fail to control important parameters such as pore size, ligand density, and molecular diffusivity. Alternatively, ECM stiffness can be modulated independently from protein concentration by mechanically loading the ECM. We have developed a novel device for generating stiffness gradients in naturally derived ECMs, where stiffness is tuned by inducing strain, while local mechanical properties are directly determined by laser tweezers based active microrheology (AMR). Hydrogel substrates polymerized within 35 mm diameter Petri dishes are strained non-uniformly by the precise rotation of an embedded cylindrical post, and exhibit a position-dependent stiffness with little to no modulation of local mesh geometry. Here we present the device in the context of fibrin hydrogels. First AMR is used to directly measure local micromechanics in unstrained hydrogels of increasing fibrin concentration. Changes in stiffness are then mapped within our device, where fibrin concentration is held constant. Fluorescence confocal imaging and orbital particle tracking are used to quantify structural changes in fibrin on the micro and nano levels respectively. The micromechanical strain stiffening measured by microrheology is not accompanied by ECM microstructural changes under our applied loads, as measured by confocal microscopy. However, super-resolution orbital tracking reveals nanostructural straightening, lengthening, and reduced movement of fibrin fibers. Furthermore, we show that aortic smooth muscle cells cultured within our device are morphologically sensitive to the induced mechanical gradient. Our results demonstrate a powerful cell culture tool that can be used in the study of mechanical effects on cellular physiology in naturally derived 3D ECM tissues.

Published

2011

14. Processing of T6 heat-treated Al-12Si-0.6Mg alloy.

Author

Bayraktar, Şenol and Demir, Onur

Subjects

HYPEREUTECTIC alloys, HEAT treatment, DIE castings, CUTTING tools, ALLOYS, CUTTING force, MACHINABILITY of metals

Abstract

In this study, ternary Al-12Si-0.6Mg material was manufactured by gravity die casting method in induction melting furnace. Microstructure images of alloy were taken on optical microscope after T6 heat treatment. Hardness, yield and tensile strength and breaking elongation of as-cast and heat-treated materials were measured by universal methods. CNC lathe was used for cutting tests and dynamometer was used to measure cutting force. Cutting tests were performed by using different cutting speeds-CS (450-500-550 m/min), feed rates-FR (0.05–0.15-0.25 mm/rev) and constant depth of cut-DOC (1.5 mm). Uncoated (A), CVD-TiCN + TiN (B) and PVD-TiAlN+TiN (C) coated carbide inserts were selected as a cutting tool. In the microstructural observations, it was determined that the structure of the material made up of aluminum rich α, primary and eutectic silicon, δ (Al4FeSi2) and π (Al8Mg3FeSi6) phases. The heat treatment refined the phases in the structure of the alloy. In addition, it has been determined that it improves mechanical properties (hardness, yield and tensile strength) by spheroidizing silicon particles. As a result of the cutting tests, it was detected that the cutting force (CF) reduced with T6 heat treatment at all CS and FR values. The CF, BUE (Built up edge) and BUL (Built up layer) heightened with increasing FR, while it reduced with increasing CS on all cutting tools. CF, BUE and BUL were formed at least in tools A, B and C, respectively. While continuous chip formation was detected in the as-cast part, brittle chip formation was observed in the heat-treated part due to the reduction in breaking elongation of the material. [ABSTRACT FROM AUTHOR]

Published

2020

15. Review of novel energetic polymers and binders – high energy propellant ingredients for the new space race.

Author

Cheng, Tianze

Subjects

*SOLID propellants, *PROPELLANTS, *POLYMERS

Abstract

Current solid rocket propellant formulations still employ traditional ingredients utilized since the 1960s, such as hydroxyl terminated polybutadiene (HTPB). Recent advances in energetic polymer see many binders capable of providing higher specific impulse and burn rates over HTPB. As shown by calculations, even slight increases in specific impulse can drastically increase the maximum payload of a launch system. Therefore, replacing HTPB with energetic binders could provide heavy space missions the needed extra boost. Energetic binders could also be paired with chlorine-free energetic oxidizers to synergistically provide a specific impulse exceedingly higher than the current formulation while reducing pollution. A comprehensive evaluation of the synthesis, mechanical properties, and performance of various trending and overlooked energetic polymers is described. Several outstanding candidates show promising properties to replace HTPB. [ABSTRACT FROM AUTHOR]

Published

2019

16. Effects of PVDF-HFP concentration on membrane distillation performance and structural morphology of hollow fiber membranes

Author

García Payo, María del Carmen, Essalhi, M., Khayet Souhaimi, Mohamed, García Payo, María del Carmen, Essalhi, M., and Khayet Souhaimi, Mohamed

Abstract

© 2009 Elsevier B.V. The authors gratefully acknowledge the financial support of the Spanish Ministry of Science and Education (MEC) (Project FIS2006-05323) and the UCM-BSCH (Project GR58/08, UCM group 910336). M. Essalhi is thankful to the Middle East Desalination Research Centre for the grant (MEDRC 06-AS007)., Poly(vinylidene fluoride-hexafluoropropylene), PVDF-HFP, hollow fiber membranes were prepared by the dry/wet spinning technique using different copolymer concentrations in the dope solutions ranging from 17 to 24 wt.%. All the spinning parameters were maintained constant except the copolymer concentration. The morphological properties of the hollow fiber membranes were studied in terms of scanning electron microscopy (SEM), atomic force microscopy (AFM) and void volume fraction. The effects of PVDF-HFP content in the spinning solutions were also studied by measuring the water entry pressure and direct contact membrane distillation (DCMD) permeate flux of the hollow fiber membranes. An increase in the copolymer concentration of the spinning solution resulted in a decrease in the precipitation rate and a transition of the cross-section structure from a finger-type structure to a sponge-type structure. Pore size, nodule size and roughness parameters of both the internal and external hollow fiber surfaces were determined by AFM. It was observed that the pore size decreased in both the internal and external surfaces of the hollow fiber membranes with increasing the copolymer concentration and reached a minimum value at the outer surface for PVDF-HFP concentrations greater than 20 wt.%. Water entry pressure values were decreased whereas both the void volume fraction and the DCMD permeate flux increased with decreasing the copolymer concentration., Spanish Ministry of Science and Education (MEC), UCM-BSCH, Middle East Desalination Research Centre (MEDRC), Depto. de Estructura de la Materia, Física Térmica y Electrónica, Fac. de Ciencias Físicas, TRUE, pub

Published

2023

17. Influence of the processing temperature on the microstructure, texture, and hardness of the 7075 aluminum alloy fabricated by accumulative roll bonding

Author

Hidalgo Alcalde, Pedro, Cepeda Jimenez, C. M., Ruano, O. A, Carreño, F., Hidalgo Alcalde, Pedro, Cepeda Jimenez, C. M., Ruano, O. A, and Carreño, F.

Abstract

© The Minerals, Metals & Materials Society and ASM International 2010. Financial support from CICYT (Project Nos. MAT2003-01172 and MAT2006-11202) is gratefully acknowledged. Two of the authors, PH and CMC, thank CSIC for an I3P fellowship and an I3P contract, respectively. We also thank A. García-Delgado for assistance with electron microscopy and C.C. Moreno-Hernández and J.A. Jiménez- Rodríguez for assistance with X-ray diffraction. Finally, the authors make a special mention in memory of P.J. González-Aparicio for his assistance with electron microscopy during all these years., The 7075 alloy is an Al-Zn-Mg-Cu wrought age-hardenable aluminum alloy widely used in the aeronautical industry. The alloy was accumulative roll bonded at 300 A degrees C (573 K), 350 A degrees C (623 K), and 400 A degrees C (673 K), and the microstructure, texture, and hardness were investigated. Cell/(sub)grain size in the nanostructured range, typical beta-fiber rolling texture, and homogeneous hardness through thickness were determined in all cases. Misorientation was different at each processing temperature. At 400 A degrees C, the presence of elements in solid solution and the partial dissolution of the hardening precipitates lead to a poorly misoriented microstructure with a high dislocation density and a homogeneous beta-fiber texture of low intensity, typical of intermediate degrees of rolling. At 350 A degrees C and 300 A degrees C, highly misoriented microstructures with smaller dislocation density and intense heterogeneous beta-fiber rolling texture are observed, especially at 350 A degrees C, wherein the degree of dynamic recovery (DRV) is higher. Hardness of the accumulative roll bonded samples is smaller than that of the starting material due to particle coarsening, and it is affected by solid solution and/or by fine precipitates produced by reprecipitation of the elements in solid solution., CICYT, CSIC, Depto. de Física de Materiales, Fac. de Ciencias Físicas, TRUE, pub

Published

2023

18. Reduced hardness at the onset of plasticity in nanoindented titanium dioxide

Author

Navarro, V., Rodríguez de la Fuente, Óscar, Mascaraque Susunaga, Arantzazu, Rojo Alaminos, Juan Manuel, Navarro, V., Rodríguez de la Fuente, Óscar, Mascaraque Susunaga, Arantzazu, and Rojo Alaminos, Juan Manuel

Abstract

© 2008 The American Physical Society. The authors acknowledge financial support from the Comunidad de Madrid Project No. CAM-S-0505/PPQ/0316, from Santander-UCM Project No.PR27/05-13926, and from the Spanish Ministerio de Educación y Ciencia Project No. MAT2006-13149-C02-01., Titanium dioxide rutile crystals have been nanoindented and studied by a combination of atomic force microscopy imaging and analysis of force vs penetration curves. In all the experiments, gold crystals have been used as a reference. A concept of nanoindentation effective volume is introduced to differentiate the bulk behavior from that of a small defect-free volume around the indentation. In the latter volume, a reversible Hertzian elastic stage is identified with a Young modulus comparable to that of the bulk. At higher loads, an incipient plastic range is recognized in which the load is linear on the penetration and permanent traces are left behind at the surface upon tip retraction. In that range, the hardness is constant, about five times smaller than the yield strength and more than three times smaller than the corresponding bulk value. This reduced hardness is explained in terms of the operation of dislocation sources with a low-energy barrier., Comunidad de Madrid, Santander-UCM, Spanish Ministerio de Educacion y Ciencia, Depto. de Física de Materiales, Fac. de Ciencias Físicas, TRUE, pub

Published

2023

19. Grain boundary configurational entropy: a challenge

Author

Lejček, Pavel, Školáková, Andrea, Lejček, Pavel, and Školáková, Andrea

Abstract

While the bulk of the high-entropy alloys is widely studied and characterized by their configurational entropy, there is a lack of general information regarding the configurational entropy of the grain boundaries. Here, we derived for the first time the basic relationships of this thermodynamic quantity related to the solute segregation at grain boundaries. Some examples of the appearance of the grain boundary configurational entropy are shown, and its effect on intergranular properties is discussed. It is stated that the role of grain boundary configurational entropy in interfacial properties is not completely clear and represents a challenge for future research.

Published

2023

20. Local epidermal growth factor delivery using nanopillared chitosan-gelatin films for melanogenesis and wound healing

Author

Amiji, Mansoor, Radwan, Ahmed Eid, Büyükserin, Fatih, Dhaliwal, Harkiranpreet Kaur, Altuntaş, Sevde, Amiji, Mansoor, Radwan, Ahmed Eid, Büyükserin, Fatih, Dhaliwal, Harkiranpreet Kaur, and Altuntaş, Sevde

Abstract

Epidermal growth factor (EGF) is required for various regulations of skin tissue including wound healing; however, it has limited stability due to the physicochemical conditions of the wound milieu. The lack of functional EGF within the wound can cause permanent tissue defects and therefore, current wound patch designs involve EGF-releasing components. Consequently, the focus of such systems is to improve the wound healing mechanism, with minimal attention on melanogenesis of the scar tissue. The present study investigates in vitro/in vivo wound healing and melanogenesis potential of the EGF-doped films comprised of arrays of chitosan:gelatin nanopillars (nano C:G films) prepared by using nanoporous anodic alumina molds. The potential of EGF-doped films in wound healing was examined with individual and coculture systems of fibroblasts and melanocytes to mimic the wound conditions. The outcomes demonstrated that compared to the control groups, the combination of EGF doping and nanotopography consistently provided the highest levels of melanogenic activity-related genes, melanin contents as well as EGFR expressions for both melanocyte-only and coculture setups. Proteomic, genomic and histological analysis of the excisional wound model further demonstrated that if EGF was present within the nanostructured films, the performance of these substrates in terms of wound closure, collagen thickness as well as melanin deposition was considerably improved. Furthermore, when compared with the control saline treatment and healthy mice groups, significant differences for such parameters were obtained for the nano C:G films, irrespective of their EGF contents. Overall, the results indicate that EGF-doped nano C:G films are good candidates as wound patches that not only provide desirable healing characteristics but also cause improved melanogenic outputs., Scientific and Technological Research Council of Turkey TUBITAK BIDEB 2214-A Program; [1059B141601323], S. A. would like to thank grants from the Scientific and Technological Research Council of Turkey TUBITAK BIDEB 2214-A Program (no. 1059B141601323).

Published

2023

21. Fatigue life prediction of lattice structures using a strain-life method based on an equivalent solid model

Author

Özay, Arda, I, Görgülüarslan, Recep M., Özay, Arda, I, and Görgülüarslan, Recep M.

Abstract

In this study, an efficient fatigue life estimation approach is proposed based on an equivalent solid model, along with two stress concentration factors, instead of a lattice model to simplify simulations for the strain-life method. One of the stress concentration factors accounts for the stress concentrations at the strut joints in lattice structures without any manufacturing effect, while the other accounts for the stress concentrations due to surface defects on the struts introduced by the additive manufacturing process. A simple solid cell, for which the dimensions are the same as those of the lattice cell, is first used to estimate the fatigue life of the bulk material used in the additive manufacturing process using the Brown-Miller strain-life method. Combinations of two stress concentration factors were then utilized to predict the fatigue life of the lattice structure from the equivalent solid model. Using this approach, computationally expensive lattice structure simulations were eliminated, and the fatigue life of the lattice structure was predicted directly from the bulk material fatigue life estimation. The proposed approach was applied to different lattice types made of Ti-6Al-4V alloy using the laser-powder bed fusion additive manufacturing process. The fatigue life results estimated using the proposed approach were in good agreement with the experimental fatigue life results reported in the literature.

Published

2023

22. Reply to the Comment on Two-dimensional penta-like PdPSe with a puckered pentagonal structure: a first-principles study'' by S. Chowdhury, F. Shojaei and B. Mortazavi, Phys. Chem. Chem. Phys., 2023, 25, DOI: 10.1039/D2CP01587K

Author

Fadlallah, Mohamed M., Bafekry, Asadollah, Faraji, Mehrdad, Shafique, A., Jappor, Hamad R., Sarsari, I. Abdolhoseini, Ang, Yee Sin, Fadlallah, Mohamed M., Bafekry, Asadollah, Faraji, Mehrdad, Shafique, A., Jappor, Hamad R., Sarsari, I. Abdolhoseini, and Ang, Yee Sin

Published

2023

23. Improving the energy absorption capacity of bending-dominated additively manufactured polylactic acid (PLA) lattices

Author

Paygozar, Bahman, Görgülüarslan, Recep M., Paygozar, Bahman, and Görgülüarslan, Recep M.

Abstract

Article; Early Access, This study aims to investigate the energy absorption performance of three bending-dominated lattice structures including quad-diametral (QD), quad-diametral-line (QDL), and dodecahedron (DO)). Compression test specimens with these three lattice types were manufactured using the material extrusion additive manufacturing technique with PLA material. The specimens were manufactured with different sets of values of the print temperature, layer thickness, and line width to identify their effect on the energy absorption performance. Taguchi's method was utilized for this purpose which revealed that the temperature is the most effective and its optimized value is 225 ; DEG;C. It was also found that the energy absorption performance of the DO lattice is superior to that of QD and QDL lattices. In the following set of experiments, the print temperature was fixed to its optimized value (i.e. 225 ; DEG;C), and another process parameter (i.e. print speed) along with layer thickness and line width were investigated among eight different groups of DO lattices. Numerical investigations were also performed and validated based on the experimental results. Parametric studies were also done for the DO lattice to improve its energy absorption performance by changing the strut diameters and introducing grading to the struts at each lattice cell., Scientific and Technological Research Council of Turkiye; [122M823], This research was funded by a grant from The Scientific and Technological Research Council of Turkiye, project number 122M823.

Published

2023

24. Simultaneous optimization of topology and process parameters for laser-powder bed fusion additive manufacturing

Author

Acar, Erdem, Gokdag, Istemihan, Acar, Erdem, and Gokdag, Istemihan

Abstract

Additive manufacturing (AM) technology is used in sectors such as automotive and aerospace, due to its advantages in producing complex and lightweight structures. However, it is necessary to reduce the total manufacturing costs for AM technology to become widespread. The topology optimization (TO) studies in the literature typically optimize only the design without taking into account the manufacturing phase or sequentially optimize the topology first and then the process parameters. On the other hand, simultaneous optimization of topology together with process parameters provides more efficient and less costly solutions. This paper describes a strategy for simultaneous optimization of topology along with process parameters of the laser-powder bed fusion (L-PBF) process. The topology, laser power, scanning speed, energy density, and yield strength are controlled by integrating the overall process-property-structure-performance relationship of the L-PBF process into the optimization. The proposed simultaneous optimization method aims to minimize the total cost function including material, manufacturing, and energy costs. Moreover, the constraint functions of the optimization include the volume fraction, the strength of the structure, and the energy density calculated according to the process parameters. The proposed method is successfully applied to three different design problems as cantilever beam, MBB beam, and L bracket, respectively. The results of different TO methods including conventional TO (compliance minimization), structural TO (similar to stress-constrained TO), and sequential process parameters and topology optimization are compared with the results of the proposed method. It is found that the proposed method provided the minimum cost results, and the obtained designs met the structural requirements., Scientific and Technological Research Council of Turkey (TUEBITAK) [5189901], This study is a part of the project (# 5189901) supported by The Scientific and Technological Research Council of Turkey (TUEBITAK) under the Frontier R ; amp;D Laboratory Support Program and performed in Turkish Aerospace Industries Inc. The funding provided by TUEBITAK under Grant No. 5189901 is gratefully acknowledged.

Published

2023

25. Histological and Biomechanical Effects of Local Anesthetics and Steroids on Achilles Tendon: A Study in Rats

Author

Demir, Teyfik, Yazıcı Güvercin, Ayşe Canan, Fidan, Pınar Ayran, Helvacıoğlu, Fatma, Sahin, Mehmet Şükrü, Kafa, Barış, Çakmak, Gökhan, Demir, Teyfik, Yazıcı Güvercin, Ayşe Canan, Fidan, Pınar Ayran, Helvacıoğlu, Fatma, Sahin, Mehmet Şükrü, Kafa, Barış, and Çakmak, Gökhan

Abstract

Background: Peritendinous injection of local anesthetics, alone or in combination with corticosteroids, is widely used in the treatment of tendinopathies. Toxicity of local anesthetics has been demonstrated in many cells, including myocytes, chondrocytes, and neurons. Bupivacaine and lidocaine are known to have time- and dose-dependent cytotoxicity in these cells. The effects of these agents on the tendon remain unknown. Purpose: To show histological and biomechanical effects after the injection of different local anesthetics and steroids, both single and combined, at different concentrations into the peritendinous sheath of rat Achilles tendon. Study Design: Controlled laboratory study. Methods: In the study, 100 rats were divided into 10 groups with equal body weights. Inflammation was induced in both Achilles tendons of each rat by means of the ball drop technique; 7 hours later, injections were made into the peritendinous sheaths of both Achilles tendons using lidocaine, bupivacaine, and dexamethasone as appropriate for the rat's group. At the end of the first week, the right Achilles tendons of the rats were removed for histological study. Left Achilles tendons were evaluated in terms of biomechanics. Results: Histological findings demonstrated that the group with the most toxicity to the tendon was the group that received injection of dexamethasone alone. The groups with the least toxicity were those receiving dexamethasone combined with low- or high-dose bupivacaine. Biomechanical findings showed that the experimental groups had similar results to each other with the exception of the groups receiving 0.25% bupivacaine alone and dexamethasone alone, in which tendons revealed higher tensile strength. Conclusion: Local anesthetic and steroid applications have different histological and biomechanical effects on the tendon. Although the dexamethasone-injected group was the most affected in terms of histology, these changes could not be demonstrated biomechanically

Published

2023

26. Variation in the properties of Ti-6Al-4V alloys fabricated by electron beam melting due to build plate location

Author

Güngör, Utku O., Görgülüarslan, Recep M., Arslan Hamat, Burcu, Durlu, Nuri, Memu, Fırat, Güngör, Utku O., Görgülüarslan, Recep M., Arslan Hamat, Burcu, Durlu, Nuri, and Memu, Fırat

Abstract

The build plate location and post-processing effects on the properties of Ti-6Al-4V alloys fabricated via electron beam melting (EBM) are investigated in the context of spatial variability. Tensile test specimens are fabricated in four corner and center locations of the EBM machine build plate with three different dimensions. One specimen has standard dimensions of 6 mm gauge length diameter; the second one has 25% higher diameters, called the offset specimens, and the third is a cylinder with a diameter of 15 mm, called the block specimens. The standard specimen dimensions are obtained by applying machining to the block and offset specimens to evaluate the influence of the larger dimension and post-processing on the mechanical properties, including spatial variability. The yield strength, tensile strength, and ductility are obtained by performing tensile tests. The density and surface roughness of the specimens are measured before and after machining. Correlation plots and semivariograms are used to examine the effect of spatial variability on the properties of the fabricated specimens at different build plate locations. The densities of the block, offset, and standard specimens are 99.4%, 98.6%, and 98.8%, respectively. The surface roughness (Ra) values reduced from 29.5 to 0.7 mu m after machining the block specimens, while the roughness is as high as 47.2 mu m for the standard specimens. Following the machining process, the yield strength increases from 970 MPa for the standard specimens to 1039 MPa for the block specimens. The tensile strengths are approximately 1115 MPa and 1074 MPa for the block and offset specimens, respectively, whereas for the standard specimens, it is as low as 996 MPa. Similarly, the ductility increases to 13.8% when the block specimens are machined compared to the standard specimen result of 5.4%. For the standard specimens, approximately 5% change in the parameters could be observed at different build plate locations. The location depe, Presidency of Defense Industries; Turkish Aerospace under the SAYP project [DDKIT1], This work was supported by Presidency of Defense Industries and the Turkish Aerospace under the SAYP project DDKIT1.

Published

2023

27. Local epidermal growth factor delivery using nanopillared chitosan-gelatin films for melanogenesis and wound healing

Author

Dhaliwal, Harkiranpreet Kaur, Büyükserin, Fatih, Altuntaş, Sevde, Radwan, Ahmed Eid, Amiji, Mansoor, Dhaliwal, Harkiranpreet Kaur, Büyükserin, Fatih, Altuntaş, Sevde, Radwan, Ahmed Eid, and Amiji, Mansoor

Abstract

Epidermal growth factor (EGF) is required for various regulations of skin tissue including wound healing; however, it has limited stability due to the physicochemical conditions of the wound milieu. The lack of functional EGF within the wound can cause permanent tissue defects and therefore, current wound patch designs involve EGF-releasing components. Consequently, the focus of such systems is to improve the wound healing mechanism, with minimal attention on melanogenesis of the scar tissue. The present study investigates in vitro/in vivo wound healing and melanogenesis potential of the EGF-doped films comprised of arrays of chitosan:gelatin nanopillars (nano C:G films) prepared by using nanoporous anodic alumina molds. The potential of EGF-doped films in wound healing was examined with individual and coculture systems of fibroblasts and melanocytes to mimic the wound conditions. The outcomes demonstrated that compared to the control groups, the combination of EGF doping and nanotopography consistently provided the highest levels of melanogenic activity-related genes, melanin contents as well as EGFR expressions for both melanocyte-only and coculture setups. Proteomic, genomic and histological analysis of the excisional wound model further demonstrated that if EGF was present within the nanostructured films, the performance of these substrates in terms of wound closure, collagen thickness as well as melanin deposition was considerably improved. Furthermore, when compared with the control saline treatment and healthy mice groups, significant differences for such parameters were obtained for the nano C:G films, irrespective of their EGF contents. Overall, the results indicate that EGF-doped nano C:G films are good candidates as wound patches that not only provide desirable healing characteristics but also cause improved melanogenic outputs., Scientific and Technological Research Council of Turkey TUBITAK BIDEB 2214-A Program; [1059B141601323], S. A. would like to thank grants from the Scientific and Technological Research Council of Turkey TUBITAK BIDEB 2214-A Program (no. 1059B141601323).

Published

2023

28. Variation in the properties of Ti-6Al-4V alloys fabricated by electron beam melting due to build plate location

Author

Arslan Hamat, Burcu, Görgülüarslan, Recep M., Güngör, Utku O., Durlu, Nuri, Memu, Fırat, Arslan Hamat, Burcu, Görgülüarslan, Recep M., Güngör, Utku O., Durlu, Nuri, and Memu, Fırat

Abstract

The build plate location and post-processing effects on the properties of Ti-6Al-4V alloys fabricated via electron beam melting (EBM) are investigated in the context of spatial variability. Tensile test specimens are fabricated in four corner and center locations of the EBM machine build plate with three different dimensions. One specimen has standard dimensions of 6 mm gauge length diameter; the second one has 25% higher diameters, called the offset specimens, and the third is a cylinder with a diameter of 15 mm, called the block specimens. The standard specimen dimensions are obtained by applying machining to the block and offset specimens to evaluate the influence of the larger dimension and post-processing on the mechanical properties, including spatial variability. The yield strength, tensile strength, and ductility are obtained by performing tensile tests. The density and surface roughness of the specimens are measured before and after machining. Correlation plots and semivariograms are used to examine the effect of spatial variability on the properties of the fabricated specimens at different build plate locations. The densities of the block, offset, and standard specimens are 99.4%, 98.6%, and 98.8%, respectively. The surface roughness (Ra) values reduced from 29.5 to 0.7 mu m after machining the block specimens, while the roughness is as high as 47.2 mu m for the standard specimens. Following the machining process, the yield strength increases from 970 MPa for the standard specimens to 1039 MPa for the block specimens. The tensile strengths are approximately 1115 MPa and 1074 MPa for the block and offset specimens, respectively, whereas for the standard specimens, it is as low as 996 MPa. Similarly, the ductility increases to 13.8% when the block specimens are machined compared to the standard specimen result of 5.4%. For the standard specimens, approximately 5% change in the parameters could be observed at different build plate locations. The location depe, Presidency of Defense Industries; Turkish Aerospace under the SAYP project [DDKIT1], This work was supported by Presidency of Defense Industries and the Turkish Aerospace under the SAYP project DDKIT1.

Published

2023

29. Complex hemolymph circulation patterns in grasshopper wings

Author

Salcedo, Mary K., Jun, Brian H., Socha, John J., Pierce, Naomi E., Vlachos, Pavlos P., Combes, Stacey A., Salcedo, Mary K., Jun, Brian H., Socha, John J., Pierce, Naomi E., Vlachos, Pavlos P., and Combes, Stacey A.

Abstract

An insect's living systems-circulation, respiration, and a branching nervous system-extend from the body into the wing. Wing hemolymph circulation is critical for hydrating tissues and supplying nutrients to living systems such as sensory organs across the wing. Despite the critical role of hemolymph circulation in maintaining healthy wing function, wings are often considered "lifeless" cuticle, and flows remain largely unquantified. High-speed fluorescent microscopy and particle tracking of hemolymph in the wings and body of the grasshopper Schistocerca americana revealed dynamic flow in every vein of the fore- and hindwings. The global system forms a circuit, but local flow behavior is complex, exhibiting three distinct types: pulsatile, aperiodic, and "leaky" flow. Thoracic wing hearts pull hemolymph from the wing at slower frequencies than the dorsal vessel; however, the velocity of returning hemolymph (in the hindwing) is faster than in that of the dorsal vessel. To characterize the wing's internal flow mechanics, we mapped dimensionless flow parameters across the wings, revealing viscous flow regimes. Wings sustain ecologically important insect behaviors such as pollination and migration. Analysis of the wing circulatory system provides a template for future studies investigating the critical hemodynamics necessary to sustaining wing health and insect flight. Study of grasshopper wings shows that hemolymph flows through every vein in the insect wing, creating a broad circuitous flow pattern in the wings, with three different flow behaviours (pulsatile, leaky, aperiodic).

Published

2023

30. Coir from Coconut Processing Waste as a Raw Material for Applications beyond Traditional Uses

Author

Stelte, Wolfgang, Reddy, Narendra, Barsberg, Søren, Sanadi, Anand Ramesh, Stelte, Wolfgang, Reddy, Narendra, Barsberg, Søren, and Sanadi, Anand Ramesh

Abstract

The global production of coconut, mainly for food and oil production, exceeds 62 million tonnes per annum. Large quantities of coconut husk remain unutilized after industrial processing, giving rise to environmental problems. This fails to exploit the potential presented by the extraction of coir, which could have numerous applications. Traditional products such as textiles, mats, and brushes made from coir are increasingly being joined by new, high-value, non-traditional uses. This review article summarizes new fields of application for coir as reinforcing fibers in binderless fiberboards, natural fiber composites, construction materials, solid biofuels, and an absorbent for heavy metals and toxic materials. The use of coir in these new fields will reduce waste and increase sustainability.

Published

2023

31. Textile Fiber Production of Biopolymers - A Review of Spinning Techniques for Polyhydroxyalkanoates in Biomedical Applications

Author

Kopf, Sabrina, Åkesson, Dan, Skrifvars, Mikael, Kopf, Sabrina, Åkesson, Dan, and Skrifvars, Mikael

Abstract

The superior biocompatibility and biodegradability of polyhydroxyalkanoates (PHAs) compared to man-made biopolymers such as polylactic acid promise huge potential in biomedical applications, especially tissue engineering (TE). Textile fiber-based TE scaffolds offer unique opportunities to imitate the anisotropic, hierarchical, or strain-stiffening properties of native tissues. A combination of PHAs' enhanced biocompatibility and fiber-based TE scaffolds could improve the performance of TE scaffolds. However, the PHAs' complex crystallization behavior and the resulting intricate spinning procedures remain a challenge. This review focuses on discussing the developments in PHA melt and wet spinning, their challenges, process parameters, and fiber characteristics while revealing the lack of an in-depth fiber characterization of wet-spun fibers compared to melt-spun filaments, leading to squandered potential in scaffold development. Additionally, the biomedical application of PHAs other than poly-4-hydroxybutyrate is hampered by a failure of polymer purity to meet the requirements for biomedical applications.

Published

2023

32. Approaching Self-Bonded Medium Density Fiberboards Made by Mixing Steam Exploded Arundo donax L. and Wood Fibers: A Comparison with pMDI-Bonded Fiberboards on the Primary Properties of the Boards

Author

Universitat Rovira i Virgili, Vitrone, F; Brinker, S; Ramos, D; Ferrando, F; Salvadó, J; Mai, C, Universitat Rovira i Virgili, and Vitrone, F; Brinker, S; Ramos, D; Ferrando, F; Salvadó, J; Mai, C

Abstract

This study presents an unexplored method to produce formaldehyde-free MDF. Steam exploded Arundo donax L. (STEX-AD) and untreated wood fibers (WF) were mixed at different mixing rates (0/100, 50/50, and 100/0, respectively) and two series of boards were manufactured, with 4 wt% of pMDI, based on dry fibers, and self-bonded. The mechanical and physical performance of the boards was analyzed as a function of the adhesive content and the density. The mechanical performance and dimensional stability were determined by following European standards. The material formulation and the density of the boards had a significant effect on both mechanical and physical properties. The boards made solely of STEX-AD were comparable to those made with pMDI, while the panels made of WF without adhesive were those that performed the worst. The STEX-AD showed the ability to reduce the TS for both pMDI-bonded and self-bonded boards, although leading to a high WA and a higher short-term absorption for the latter. The results presented show the feasibility of using STEX-AD in the manufacturing of self-bonded MDF and the improvement of dimensional stability. Nonetheless, further studies are needed especially to address the enhancement of the internal bond (IB).

Published

2023

33. New approach in the reuse of modified ground tire rubber as thermal and acoustic insulation to be used in civil engineering

Author

Enginyeria Mecànica, Universitat Rovira i Virgili, Colom X; Girbau J; Marin M; Formela K; Saeb RM; Carrillo F; Cañavate J, Enginyeria Mecànica, Universitat Rovira i Virgili, and Colom X; Girbau J; Marin M; Formela K; Saeb RM; Carrillo F; Cañavate J

Abstract

The concern for the amount of end-of-life tires generated each year has arisen from constant research directed to their valorisation. Herein we propose a new material, which is constituted by GTR with a binder, as acoustic and also as a thermal insulator for civil engineering. The insulator can also include the fibre mat present in the tire, seldomly considered as a recyclable sub-product. To provide insight into the insulating behaviour of these materials, four mathematical models have been tested and compared with the experimental results of thermal conductivity. The Lewis-Nielsen modelization presented good accuracy with deviations of less than 3%. A statistical analysis has also been conducted on the experimental data showing that the parameter with more effect on thermal conductivity is thickness (differences up to 43%) being particle size, less important (ca 6%). In acoustic properties, different effects can be observed depending on the frequency range, being the density the most relevant. From the mathematical, statistical and experimental analysis can be deduced that good insulation properties would be achieved in materials with: low density, porous; including mat and thick. The effect of these parameters causes variations of thermal conductivity from 0.189 to 0.117 W/m·K and in sound absorption coefficient from 0.06 to 0.6.

Published

2023

34. Use of operational research techniques for concrete mix design: A systematic review

Author

Universitat Rovira i Virgili, Rosa, AC; Hammad, AWA; Boer, D; Haddad, A, Universitat Rovira i Virgili, and Rosa, AC; Hammad, AWA; Boer, D; Haddad, A

Abstract

Traditional methods for designing concrete mixtures provide good results; however, they do not guarantee the optimum composition. Consequently, applying operational research techniques is motivated by an increasing need for designers to proportion the concrete's raw materials that satisfy the concrete performance requirements such as mechanical properties, chemical properties, workability, sustainability, and cost. For this reason, many authors have been looking for mathematical programming and machine learning solutions to predict concrete mix properties and optimise concrete mixtures. Therefore, a comprehensive review of operational research techniques concerning the design and proportioning of concrete mixtures and a classification framework are presented herein.

Published

2023

35. Comparison of thermal and mechanical properties of γ′-Pt3Al and γ′-Ni3Al phases: A first principles study

Author

Zhang, Xiao, Zhou, Xiao-long, Yao, Bi-xia, Yu, Jie, and Wang, Li-hui

Published

2022

36. Effect of Vanadium on Wear and Corrosion Resistance of Fe-C-Cr Hardfacing Coatings

Author

Comez, Nilay

Subjects

wear, Tribological Performance, Behavior, corrosion, Mechanical Engineering, carbide, hardfacing, Temperature, Mechanical-Properties, White Cast Irons, M7c3 Carbide, Steel, Mechanics of Materials, Alloys, Abrasion Resistance, General Materials Science, Microstructure

Abstract

The objective of the study was to investigate the effect of vanadium on wear and corrosion resistance in Fe-Cr-C hardfacing alloy. The hardfacing coatings were deposited onto the S235JR steel using metal arc welding method. The addition of vanadium gave rise to the formation of VC and V2C carbides. The increase in vanadium and the decrease in carbon content reduced the size of primary carbides and carbide volume fraction. However, vanadium increased the microhardness of the primary carbide. The vanadium-free coating showed maximum hardness and wear resistance while having the maximum corrosion rate. The optimal vanadium content was 2% by weight to achieve a coating as wear-resistant as Fe-Cr-C alloy without vanadium. Scratches due to abrasive wear and fracture of the primary carbide were observed on the worn surface of the coatings. The addition of vanadium raised the corrosion resistance 3-4 times., Scientific Research Project Office of Manisa Celal Bayar University [2019-074], Author thanks Scientific Research Project Office of Manisa Celal Bayar University for the financial support (Project number: 2019-074). Author also thanks Assoc. Prof. Dr. Metin YURDDASKAL and Dr. Melis YURDDASKAL who performed 3D-profilometer analyses.

Published

2022

37. Field and saccharification performances of poplars severely downregulated in CAD1

Author

Barbara De Meester, Rebecca Van Acker, Marlies Wouters, Silvia Traversari, Marijke Steenackers, Jenny Neukermans, Frank Van Breusegem, Annabelle Déjardin, Gilles Pilate, and Wout Boerjan

Subjects

water content, Physiology, XYLEM, LIGNIN BIOSYNTHESIS, Biology and Life Sciences, MECHANICAL-PROPERTIES, Plant Science, CINNAMYL-ALCOHOL-DEHYDROGENASE, Lignin, saccharification, Alcohol Oxidoreductases, field trial, Populus, poplar, TRANSGENIC POPLARS, POPULUS-TRICHOCARPA, HYBRID POPLAR, TRADE-OFF, GROWTH, CAD, lignin engineering, PLANTS, Biomass, wood

Abstract

Lignin is one of the main factors causing lignocellulosic biomass recalcitrance to enzymatic hydrolysis. Glasshouse-grown poplars severely downregulated for CINNAMYL ALCOHOL DEHYDROGENASE 1 (CAD1), the enzyme catalysing the last step in the monolignol-specific branch of lignin biosynthesis, have increased saccharification yields and normal growth. Here, we assess the performance of these hpCAD poplars in the field under short rotation coppice culture for two consecutive rotations of 1 yr and 3 yr. While 1-yr-old hpCAD wood had 10% less lignin, 3-yr-old hpCAD wood had wild-type lignin levels. Because of their altered cell wall composition, including elevated levels of cinnamaldehydes, both 1-yr-old and 3-yr-old hpCAD wood showed enhanced saccharification yields upon harsh alkaline pretreatments (up to +85% and +77%, respectively). In contrast with previous field trials with poplars less severely downregulated for CINNAMYL ALCOHOL DEHYDROGENASE (CAD), the hpCAD poplars displayed leaning phenotypes, early bud set, early flowering and yield penalties. Moreover, hpCAD wood had enlarged vessels, decreased wood density and reduced relative and free water contents. Our data show that the phenotypes of CAD-deficient poplars are strongly dependent on the environment and underpin the importance of field trials in translating basic research towards applications.

Published

2022

38. Fluid shear stress-induced mechanotransduction in myoblasts

Author

Mohammad Haroon, Niek G.C. Bloks, Louise Deldicque, Katrien Koppo, Hadi Seddiqi, Astrid D. Bakker, Jenneke Klein-Nulend, Richard T. Jaspers, UCL - SSS/IONS/CEMO - Pôle Cellulaire et moléculaire, Physiology, AMS - Tissue Function & Regeneration, Oral Cell Biology, AMS - Rehabilitation & Development, and Elderly care medicine

Subjects

EXPRESSION, GROWTH-FACTOR, Myoblast, Science & Technology, ENDOTHELIAL GLYCOCALYX, Mechanotransduction, PROLIFERATION, Fluid shear stress, Nitric oxide, MECHANICAL-PROPERTIES, Cell Biology, FORCE TRANSMISSION, Glycocalyx, Mechanotransduction, Cellular, NITRIC-OXIDE PRODUCTION, ACTIN DYNAMICS, Myoblasts, Cell deformation, Oncology, SATELLITE CELLS, SKELETAL-MUSCLE, Stress, Mechanical, Life Sciences & Biomedicine

Abstract

Muscle stem cells (MuSCs) are involved in muscle maintenance and regeneration. Mechanically loaded MuSCs within their native niche undergo tensile and shear deformations, but how MuSCs sense mechanical stimuli and translate these into biochemical signals regulating function and fate is still poorly understood. We aimed to investigate whether the glycocalyx is involved in the MuSC mechanoresponse, and whether MuSC morphology affects mechanical loading-induced pressure, shear stress, and fluid velocity distribution. FSS-induced deformation of active proliferating MuSCs (myoblasts) with intact or degraded glycocalyx was assessed by live-cell imaging. Glycocalyx-degradation did not significantly affect nitric oxide production, but reduced FSS-induced myoblast deformation and modulated gene expression. Finite-element analysis revealed that the distribution of FSS-induced pressure, shear stress, and fluid velocity on myoblasts was non-uniform, and the magnitude depended on myoblast morphology and apex-height. In conclusion, our results suggest that the glycocalyx does not play a role in NO production in myoblasts but might impact mechanotransduction and gene expression, which needs further investigation. Future studies will unravel the underlying mechanism by which the glycocalyx affects FSS-induced myoblast deformation, which might be related to increased drag forces. Moreover, MuSCs with varying apex-height experience different levels of FSS-induced pressure, shear stress, and fluid velocity, suggesting differential responsiveness to fluid shear forces. ispartof: EXPERIMENTAL CELL RESEARCH vol:417 issue:1 ispartof: location:United States status: published

Published

2022

39. Closed-form analytical solutions for predicting stress transfers and thermo-elastic properties of short fiber composites

Author

Rashidinejad, Ehsan, Ahmadi, Hossein, Hajikazemi, Mohammad, and Van Paepegem, Wim

Subjects

Technology and Engineering, Mechanical Engineering, General Mathematics, MEAN-FIELD HOMOGENIZATION, effective thermo-elastic properties, MECHANICAL-PROPERTIES, Short fiber reinforced composites, SHORT-GLASS-FIBER, analytical modeling, fiber-matrix stress transfer, cylindrical short fiber model, REINFORCED POLYPROPYLENE, ELASTIC PROPERTIES, Mechanics of Materials, STIFFNESS PREDICTIONS, General Materials Science, TENSILE-STRENGTH, ORIENTATION, periodic boundary conditions, MULTIPHASE COMPOSITES, LOCAL ANISOTROPY ANALYSIS, Civil and Structural Engineering

Abstract

Novel analytical solutions with closed-form expressions for the stress and displacement fields of short fiber reinforced composites (SFRCs) and analytical prediction of their effective thermo-elastic properties are presented. The cylindrical SFRC unit-cells with periodic boundary conditions are subjected to axial and transverse stresses as well as thermally induced residual stresses. By comparison with available numerical and analytical solutions, it is revealed that the present closed-form solutions provide accurate stress field variations as well as accurate predictions for the effective thermo-elastic properties of SFRCs in a split second, and thus, the developed model is much more computationally efficient than numerical methods.

Published

2022

40. Monitoring the decrease of abrasion resistance on natural building stones due to deterioration caused by freezing and thawing cycles

Author

Kazim Gireson, Sefer Beran Çelik, and İbrahim Çobanoğlu

Subjects

Wide wheel abrasion test, P-wave velocity, Capon, Weathering, Natural building stones, Mechanical-Properties, Geology, Freeze thaw cycles, Open porosity, Geotechnical Engineering and Engineering Geology

Abstract

Natural building stones, used as floor cladding stones in outdoor applications in cold regions, are negatively affected by freezing and thawing processes, and this reduces the service life of the stone. The aim of this study is to reveal the change of abrasion resistance of natural stones determined by the wide wheel abrasion test (W-A) with laboratory freeze-thaw (FT) tests. For this purpose, FT tests were applied up to 84 cycles on 23 groups of samples, mainly consisted of carbonate rocks. According to the results, no significant decrease was determined in the dry unit weight (gamma(d)) value, but significant decreases were obtained in open porosity (n) and P-wave velocity (V-P) values. It has been revealed that W-A values are also significantly affected by increasing FT cycles and increased up to about 14%. It was concluded that the increase was evident up to 35 FT cycles, and after this level, the increase continued with a decrease.

Published

2023

41. EVALUATION OF THE POTENTIAL OF BARIUM ZIRCONATE ON THE SINTERABILITY AND PROPERTIES OF BOVINE HYDROXYAPATITE

Author

PAZARLIOĞLU, SÜLEYMAN SERDAR and PAZARLIOĞLU S. S., Bakdemir S. A., Gökçe H.

Subjects

General Chemical Engineering, Properties, MICROSTRUCTURAL PROPERTIES, MATERIALS SCIENCE, MALZEME BİLİMİ, SERAMİK, FRACTURE-TOUGHNESS, Analytical Chemistry, MATERIALS SCIENCE, CERAMICS, COMPOSITES, Materials Chemistry, General Materials Science, Barium zirconate, Physical and Theoretical Chemistry, Engineering, Computing & Technology (ENG), Seramik ve Kompozitler, BIOLOGICAL-PROPERTIES, Sintering performance, SUPERCONDUCTING PROPERTIES, OXIDE, Mühendislik, Bilişim ve Teknoloji (ENG), MECHANICAL-PROPERTIES, GRAIN-SIZE, BAZRO3, Fizik Bilimleri, Physical Sciences, Genel Malzeme Bilimi, Ceramics and Composites, Engineering and Technology, Bovine hydroxyapatite, Mühendislik ve Teknoloji, SINTERING TEMPERATURE, Malzeme Bilimi

Abstract

In the present study, the potential of barium zirconate (BaZrO3; 1-5 wt. %) on the sinterability, and properties of bovine hydroxyapatite (BHA) was evaluated. BHA decomposed into beta and alpha-tricalcium phosphate (beta and alpha-TCP) at a 4.7 % rate. Tetracalcium phosphate (TTCP) was detected as the decomposition phase in the BaZrO3 added BHAs, and it increased up to 10.7 % with an increasing BaZrO3 ratio. In addition to TTCP, the phases of BaZrO3, Ba2ZrO4, sigma-Ba2P2O7, Ba3P2O8 and CaZrO3 were detected in the composites. The addition of BaZrO3 at an amount of 3 wt. % has a higher potential than the others to improve the sinterability and properties of BHA. It contributed to the increase in the fracture toughness from 0.99 +/- 0.13 to 1.80 +/- 0.12 MPa center dot m1/2 and the compressive strength from 115.75 +/- 4.27 to 173.66 +/- 13.61 MPa, and the de-crease in the brittleness index from 4.24 +/- 0.31 to 2.45 +/- 0.15 mu-1/2. The in-vitro bioactivity of BHA also increases with the additional BaZrO3. However; it is recommended to be used in applications that do not require load bearing in the human body due to its insufficient fracture toughness.

Published

2023

42. A Review of Electrospun Nanofiber Interleaves for Interlaminar Toughening of Composite Laminates

Author

Biltu Mahato, Stepan V. Lomov, Aleksei Shiverskii, Mohammad Owais, and Sergey G. Abaimov

Subjects

toughening mechanism, Science & Technology, Polymers and Plastics, Polymer Science, NONWOVEN VEILS, General Chemistry, MECHANICAL-PROPERTIES, INTERLAYER, electrospun veil, interleave, delamination, REINFORCEMENT, fracture toughness, FRACTURE-TOUGHNESS, CARBON-FIBER COMPOSITES, cohesive zone modeling, Physical Sciences, STRENGTH, MODE-I, CONDUCTIVITY, BEHAVIOR

Abstract

Recently, polymeric nanofiber veils have gained lot of interest for various industrial and research applications. Embedding polymeric veils has proven to be one of the most effective ways to prevent delamination caused by the poor out-of-plane properties of composite laminates. The polymeric veils are introduced between plies of a composite laminate, and their targeted effects on delamination initiation and propagation have been widely studied. This paper presents an overview of the application of nanofiber polymeric veils as toughening interleaves in fiber-reinforced composite laminates. It presents a systematic comparative analysis and summary of attainable fracture toughness improvements based on electrospun veil materials. Both Mode I and Mode II tests are covered. Various popular veil materials and their modifications are considered. The toughening mechanisms introduced by polymeric veils are identified, listed, and analyzed. The numerical modeling of failure in Mode I and Mode II delamination is also discussed. This analytical review can be used as guidance for veil material selection, for estimation of the achievable toughening effect, for understanding the toughening mechanism introduced by veils, and for the numerical modeling of delamination.

Published

2023

43. Anomalous crystal structure of γ″ phase in the Mg-RE-Zn(Ag) series alloys: Causality clarified by ab initio study.

Author

Bai, Junyuan, Pang, Xueyong, Meng, Xiangying, Xie, Hongbo, Pan, Hucheng, Ren, Yuping, Jiang, Min, and Qin, Gaowu

Subjects

CRYSTAL structure, ALLOYS, SILVER sulfide, MODULUS of rigidity, LATTICE constants, SILVER alloys, STRUCTURAL models

Abstract

The crystal structure of the single-unit-cell thickness γ″ phase, as a key strengthening phase in Mg-RE-Zn (Ag) series alloys, has been extensively studied, and several structural models have been proposed in the past two decades. However, these reported models, and even the lattice constants at the same proposed structure, are scattered severely, which has led to considerable confusion and not available for further mechanical property simulation and prediction of Mg alloys containing this phase. In this study, by using first-principles calculations, the crystal structure of γ" phase is clarified, resolving the discrepancies among different experiments, and its intrinsic mechanical properties have also been studied for the first time. It is verified that the γ″ phase contains quasi-five atomic layers, instead of the previously reported tri-layer, and surprisingly, its crystal structure has many variants, which would change with the alloy composition. Besides, with the help of the simulated selected area electron diffraction (SAED) patterns, it is found that the atoms in the central layer remain partially ordered distribution, and this ordered extent primarily depends on the atomic ratio of RE: Zn(Ag) and the solute content in an alloy. That is, the ordered extent increases with decreasing the atomic ratio of RE:Zn(Ag) and/or increasing solute content of alloy, and vice versa. Ag and Zn dissolved in the γ″ phase would produce almost opposed mechanical anisotropy for the γ″ phase under the identical crystal structure, and the addition of Ag shows more efficient on increasing the shear modulus of γ″ phase. [ABSTRACT FROM AUTHOR]

Published

2020

44. Karakterizacija emisije formaldehida i svojstava gorenja ekoloških kompozitnih ploča za graditeljstvo proizvedenih na bazi ljusaka kikirikija (Arachis hypogaea)

Author

KESKİN, HAKAN, Kucuktuvek, Mustafa, ATAR, MUSA, Ercan, Ersin, Mimarlık Fakültesi -- İç Mimarlık Bölümü, and Küçüktüvek, Mustafa

Subjects

Combustion property, Composite panels, Materials Science, Mechanical-properties, Green buildings, Particleboard, Wood-based panels, Intelligent buildings, Urea Formaldehyde, Oilseeds, Adhesives, Formaldehyde, Arachis hypogaea, Earth Sciences - Environmental Sciences - Formaldehyde, Mechanical Properties, Bamboo, Lighting, Combustion properties, Combustion time, Hulls, Additives, Emissions and combustion, Manufacture, Forestry, Peanut husk, Wood, Medium Density Fiberboards, Building materials, Green building materials, Formaldehyde emission

Abstract

The building sectors are increasingly in need of more wood-based panels. Forests and environments are being destroyed to produce these wood-based panels. The aim of this study is to protect forest assets by recycling peanut (Arachis hypogaea) husk and manufacturing particleboard for green building design. The manufactured composite panels were subjected to combustion and formaldehyde tests. According to the test results, peanut husk reduced the combustion time and increased the combustion temperature. Phenol-formaldehyde adhesive decreased illuminance values and the peanut husk ratio increased the illuminance values. It was understood that, when the peanut husk additive ratio increased, combustion times decreased. Slow-combustion of green building composite panels delays the danger of collapse in case of a fire in a building. The combustion performance of the composite panels can be improved by adding non-combustible materials that do not affect the adhesion performance of the composite panels. When the adhesive type is taken into consideration, it is seen that the FF additive ratio reduces the combustion time. According to the formaldehyde emission test results, 24 hours after the manufacturing process all composite panels met the requirements of the board formaldehyde class E1. These composite panels can be used in green buildings as a sustainable building material. The furniture industry can also use these agro-fiber composite panels as green materials.

Published

2022

45. The role of in-situ nano-TiB2 particles in improving the printability of noncastable 2024Al alloy

Author

Sun, Tengteng, Wang, Hongze, Gao, Zhenyang, Wu, Yi, Wang, Mingliang, Jin, Xinyuan, Leung, Chu Lun Alex, Lee, P.D., Fu, Yanan, and Wang, Haowei

Subjects

grain refinement efficiency, Technology, Science & Technology, ALUMINUM-ALLOYS, DUCTILITY, Materials Science, heterogeneous nucleating, Materials Science, Multidisciplinary, MECHANICAL-PROPERTIES, POWDERS, composites, EVOLUTION, Laser powder bed fusion, STRENGTH, LASER, General Materials Science, MICROSTRUCTURE

Abstract

In-situ pre-decorated different content of TiB2 particle reinforced 2024 Al matrix composites (xTiB2/2024Al composite, x = 0, 1, 2, 4, 6, 8 wt.%) were printed by laser powder bed fusion (LPBF). A quantitative equation was established to quantify heterogeneous nucleating potency by TiB2 nanoparticles on the grain size of the LPBFed samples. Optimized mechanical properties were obtained in the as-printed 4TiB2/2024Al alloy which proved the feasibility of replacing the wrought part with the LPBFed one. This manuscript provides a method to determine the optimized content of TiB2 nanoparticles to change the noncastable material to the printable one. This manuscript provides a method to determine the optimized TiB2 content to change the noncastable material to the printable one, and can potentially guide the introduction of many other nanoparticles.

Published

2022

46. Impact behaviors of composite plates filled with chitosan/carbon nanotubes

Author

Callioglu, Hasan, Sayer, Metin, and Demir, Ersin

Subjects

Fibers, Impact, Mechanical Engineering, filler, Mechanical-Properties, Carbon Nanotubes, General Materials Science, composite, chitosan, carbon nanotube, Prepreg Composites, damage, Vibration

Abstract

In this study, the effects of chitosan (1%, 2%, and 3%), multi-walled carbon nanotubes (0.1%, 0.2%, and 0.3%), and chitosan-carbon nanotube hybrid (1%, 2%, and 3% chitosan + 0.3% carbon nanotube) additions at different rates on the impact behaviors and the damage mechanisms of the E-glass/epoxy composite plates were investigated experimentally. The low-velocity drop impact testing was applied to the composite plates under different impact energies. The impact energy varied between 5 J and 30 J and it was possible to examine the impact response and the damage mechanism until the starting of the penetration of the composite plates. The experimental results revealed that the absorbed impact energies in chitosan and chitosan + carbon nanotube-filled composite plates were slightly higher than those in carbon nanotube-filled composite plates. The best energy absorption performances were obtained in chitosan + carbon nanotube hybrid filled composite plates when compared to all other composite plates and the neat composite plate. A certain amount of improvement in the impact strengths of the filled composite plates was observed when compared to neat composite plate. By increasing the impact energy, the fibers on the front surface were increasingly separated from the surface in an elliptical form, and the matrix cracking and the fiber breakages occurred throughout a line on the back surface.

Published

2022

47. Strain rate effect on the tensile properties of plain weave aramid, carbon, and glass fabric reinforced monolithic and hybrid composites

Author

Fatih Balıkoğlu, Tayfur K. Demircioğlu, Ege A. Diler, and Akın Ataş

Subjects

Behavior, Fiber Epoxy, Tensile properties, Fractography, Failure, Metals and Alloys, Strain rate, Surface-Treatment, Mechanical-Properties, Glass/Epoxy Composites, Condensed Matter Physics, Materials Chemistry, Hybrid composites, Shear-Strength, Epoxy Composite, Physical and Theoretical Chemistry, Laminate, Woven Fabrics

Abstract

The tensile responses of three monolithic composites (aramid, carbon, and glass) and three different interply hybrid composite laminates (aramid/carbon, glass/aramid, and glass/carbon) were studied at quasi-static and intermediate strain rates. Monolithic composites were found to be more sensitive to strain rate than hybrid counterparts. The hybrids with glass layers had the highest sensitivity among the hybrid laminates. Tensile strengths of aramid, carbon, and glass monolithic composites improved by 15.2 %, 10.1 %, and 22.2 %, respectively, as the strain rate was increased from 0.001 s−1 to 10 s−1, while increases in tensile strengths of aramid/carbon, glass/aramid and glass/carbon hybrid laminates were 8.8 %, 17.7 %, and 5.2 %, respectively. Hybridization of glass with aramid gave the highest failure strain gain. Carbon layers located at the centre of the hybrid laminates resulted in increased tensile strength.

Published

2022

48. Physiological basis for longitudinal motion of the arterial wall

Author

Athaide, Chloe E., Spronck, Bart, and Au, Jason S.

Subjects

COMMON CAROTID-ARTERY, MOVEMENTS, STRESS, Swine, Physiology, ventricular vascular coupling, blood pressure, BLOOD-PRESSURE, MECHANICAL-PROPERTIES, Arteries, AGE-RELATED-CHANGES, COLLAGEN, longitudinal prestretch, arterial stiffness, tunica media, Physiology (medical), Animals, ELASTIN, INTRAMURAL SHEAR STRAIN, Cardiology and Cardiovascular Medicine, DISPLACEMENT, Ultrasonography

Abstract

As opposed to arterial distension in the radial plane, longitudinal wall motion (LWM) is a multiphasic and bidirectional displacement of the arterial wall in the anterograde (i.e., in the direction of blood flow) and retrograde (i.e., opposing direction of blood flow) directions. Although initially disregarded as imaging artifact, LWM has been consistently reported in ultrasound investigations in the past decade and is reproducible beat-to-beat, albeit with large interindividual variability across healthy and diseased populations. Emerging literature has sought to examine the mechanistic control of LWM to explain the shape and variability of the motion pattern but lacks considerations for key foundational vascular principles at the level of the arterial wall ultrastructure. The purpose of this review is to summarize the potential factors that underpin the causes and control of arterial LWM, spanning considerations from the arterial extracellular matrix to systems-level integrative theories. First, an overview of LWM and relevant aspects wall composition will be discussed, including major features of the multiphasic pattern, arterial wall extracellular components, tunica fiber orientations, and arterial longitudinal prestretch. Second, current theories on the systems-level physiological mechanisms driving LWM will be discussed in the context of available evidence including experimental human research, porcine studies, and mathematical models. Throughout, we discuss implications of these observations with suggestions for future priority research areas.

Published

2022

49. Physiological basis for longitudinal motion of the arterial wall

Subjects

COMMON CAROTID-ARTERY, MOVEMENTS, STRESS, ventricular vascular coupling, blood pressure, BLOOD-PRESSURE, MECHANICAL-PROPERTIES, AGE-RELATED-CHANGES, COLLAGEN, longitudinal prestretch, arterial stiffness, tunica media, ELASTIN, INTRAMURAL SHEAR STRAIN, DISPLACEMENT

Abstract

As opposed to arterial distension in the radial plane, longitudinal wall motion (LWM) is a multiphasic and bidirectional displacement of the arterial wall in the anterograde (i.e., in the direction of blood flow) and retrograde (i.e., opposing direction of blood flow) directions. While initially disregarded as imaging artifact, LWM has been consistently reported in ultrasound investigations in the last decade and is reproducible beat-to-beat, albeit with large inter-individual variability across healthy and diseased populations. Emerging literature has sought to examine the mechanistic control of LWM to explain the shape and variability of the motion pattern but lacks considerations for key foundational vascular principles at the level of the arterial wall ultrastructure. The purpose of this review is to summarize the potential factors that underpin the causes and control of arterial LWM, spanning considerations from the arterial extracellular matrix to systems-level integrative theories. First, an overview of LWM and relevant aspects wall composition will be discussed, including major features of the multiphasic pattern, arterial wall extracellular components, tunica fiber orientations, and arterial longitudinal pre-stretch. Second, current theories on the systems-level physiological mechanisms driving LWM will be discussed in the context of available evidence including experimental human research, porcine studies, and mathematical models. Throughout, we discuss implications of these observations with suggestions for future priority research areas.

Published

2022

50. Suppression in Melt Viscosity of the Homogeneously Mixed Blends of Polypropylene (iPP-UHMWiPP) in the Presence of an Oxalamide

Author

Ramiro Marroquin-Garcia, Nils Leone, Laurence G. D. Hawke, Dario Romano, Carolus H. R. M. Wilsens, Sanjay Rastogi, UCL - SST/IMCN - Institute of Condensed Matter and Nanosciences, RS: FSE AMIBM, and AMIBM

Subjects

POLYETHYLENE, Polymers and Plastics, ISOTACTIC POLYPROPYLENE, Organic Chemistry, MECHANICAL-PROPERTIES, PLATEAU MODULI, ENTANGLEMENT MOLECULAR-WEIGHTS, CONSTITUTIVE MODEL, Inorganic Chemistry, CARBON, Materials Chemistry, COMPOSITES, SHEAR, POLYMERS

Abstract

Here we report on the influence of an aliphatic oxalamide-based nucleating agent (OXA3,6) on the viscoelastic and mechanical properties of isotactic polypropylene (iPP) blended with ultrahigh molecular weight iPP (UHMWiPP). The linear viscoelastic properties are investigated by using a plate-plate rheometer; the presence of only 0.5 wt % of OXA3,6 in the iPP-UHMWiPP blends results in a reduction of the complex viscosity in the entire frequency domain examined. This observation holds irrespective of the UHMWiPP weight fraction, up to 25 wt %. The viscosity suppression is attributed to an acceleration of the reorientation times of the chains, especially the longer ones, due to partial alignment of their molecular segments. Furthermore, SAXS measurements on cooled, injection molded samples hint that OXA3,6-containing samples display enhanced alignment under processing conditions (injection molding). Compared to samples without OXA, an increase in the SAXS intensity along the equator is observed in the OXA3,6 samples, implying an enhanced ability of shish-kebab formation. Such a morphological development results in higher yield stress while maintaining the elastic behavior.

Published

2022