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Alkali-Activated Materials Reinforced via Fibrous Biochar: Modification Mechanisms, Environmental Benefits, and Challenges
Fabrication and Characterisation of Fully Bio-Based Flax Fibre-Reinforced Polyester Composites
Deep Artificial Neural Network Modeling of the Ablation Performance of Ceramic Matrix Composites in the Hydrogen Torch Test
Sustainable Tunable Anisotropic Ultrasound Medical Phantoms for Skin, Skeletal Muscle, and Other Fibrous Biological Tissues Using Natural Fibers and a Bio-Elastomeric Matrix

Journal Description

Journal of Composites Science

Journal of Composites Science is an international, peer-reviewed, open access journal on the science and technology of composites published monthly online by MDPI.

Open Access— free for readers, with article processing charges (APC) paid by authors or their institutions.
High Visibility: indexed within Scopus, ESCI (Web of Science), Inspec, CAPlus / SciFinder, and other databases.
Journal Rank: JCR - Q2 (Materials Science, Composites) / CiteScore - Q1 (Engineering (miscellaneous))
Rapid Publication: manuscripts are peer-reviewed and a first decision is provided to authors approximately 16.2 days after submission; acceptance to publication is undertaken in 3.5 days (median values for papers published in this journal in the first half of 2025).
Recognition of Reviewers: reviewers who provide timely, thorough peer-review reports receive vouchers entitling them to a discount on the APC of their next publication in any MDPI journal, in appreciation of the work done.

Impact Factor: 3.7 (2024); 5-Year Impact Factor: 3.9 (2024)

Imprint Information Journal Flyer Open Access ISSN: 2504-477X

Latest Articles

28 pages, 6245 KB

Open AccessArticle

Time Response of Delaminated Active Sensory Composite Beams Assuming Non-Linear Interfacial Effects

by Nikolaos A. Chrysochoidis, Christoforos S. Rekatsinas and Dimitris A. Saravanos

J. Compos. Sci. 2025, 9(9), 500; https://doi.org/10.3390/jcs9090500 - 15 Sep 2025

A layerwise laminate FE model capable of predicting the dynamic response of delaminated composite beams with piezoelectric actuators and sensors encompassing local non-linear contact and sliding at the delamination interfaces was formulated. The kinematic assumptions of the layerwise model enabled the representation of [...] Read more.

A layerwise laminate FE model capable of predicting the dynamic response of delaminated composite beams with piezoelectric actuators and sensors encompassing local non-linear contact and sliding at the delamination interfaces was formulated. The kinematic assumptions of the layerwise model enabled the representation of opening and sliding of delamination interfaces as generalized strains, thereby allowing the introduction of interfacial contact and sliding effects through constitutive relations at the interface. This realistic FE model, assisted by representative experiments, was used to study the time response of delaminated active sensory composite beams with predefined delamination extents. The time response was measured and simulated for narrowband actuation signals at two distinct frequency levels using a surface-bonded piezoceramic actuator, while signal acquisition was performed with a piezopolymer sensor. Four different composite specimens, each containing a different delamination size, were used for this study. Experimental results were directly compared with model predictions to evaluate the performance of the proposed analytical approach. Damage signatures were identified in both the signal amplitude and the time of flight, and the sensitivity to delamination size was examined. Finally, the distributions of axial and interlaminar stresses at various time snapshots of the transient analysis are presented, along with contour plots across the structure’s thickness, which illustrate the delamination location and wave propagation patterns. Full article

(This article belongs to the Special Issue Editorial Board Members’ Collection Series: Modeling and Simulation of Composite Materials)

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15 pages, 3253 KB

Open AccessArticle

Magnetoresistive Polyaniline Nanocomposites Incorporating Nickel Ferrite-Modified Carbon Nanotubes

by Bing Zhang, Ziqi Wang, Weiping Guo, Donghua Xing, Duo Pan, Wenke Yang and Hu Liu

J. Compos. Sci. 2025, 9(9), 499; https://doi.org/10.3390/jcs9090499 - 14 Sep 2025

In this work, nickel ferrite/carbon nanotubes–polyaniline (NiFe₂O₄@CNTs-PANI) nanocomposites with positive magnetoresistance (MR) phenomenon was obtained by the hydrothermal method combined with the surface-initiated polymerization (SIP) method. The NiFe₂O₄@CNTs-PANI nanocomposites’ resistivity decreased as the temperature increased, [...] Read more.

In this work, nickel ferrite/carbon nanotubes–polyaniline (NiFe₂O₄@CNTs-PANI) nanocomposites with positive magnetoresistance (MR) phenomenon was obtained by the hydrothermal method combined with the surface-initiated polymerization (SIP) method. The NiFe₂O₄@CNTs-PANI nanocomposites’ resistivity decreased as the temperature increased, exhibiting typical semiconductor behavior. This temperature-dependent resistivity revealed a quasi-three-dimensional (3D) variable range hopping (VRH) charge carrier transport mechanism. Based on the wave function shrinkage model, its positive MR was studied. It was found that the localization length (a₀) and average hopping distance (R_hop) were decreased with increasing magnetic field strength, indicating the reduction in the hopping probability of the charge carrier, which was beneficial for the positive MR. Meanwhile, the values of a₀ and R_hop were decreased with increasing NiFe₂O₄@CNTs loading, expressing a nanofiller loading-dependent behavior. Full article

(This article belongs to the Special Issue Feature Papers in Journal of Composites Science in 2025)

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21 pages, 13425 KB

Open AccessArticle

Increasing the Corrosion Resistance of Austenitic Stainless Steel Products by Depositing Vanadium Nitride-Based Coatings on Their Surface

by Sergey Grigoriev, Marina Volosova, Valery Zhylinski, Catherine Sotova, Filipp Milovich, Anton Seleznev, Hanna Pianka, Kirill Makarevich, Pavel Potapov and Alexey Vereschaka

J. Compos. Sci. 2025, 9(9), 498; https://doi.org/10.3390/jcs9090498 - 13 Sep 2025

This study investigated the anticorrosive properties of nitride coatings (V,Zr,Nb)N, VN and (Zr,V)N with a thickness of approximately 3 μm, deposited on a substrate of AISI 321 steel. Experiments were conducted in 3.0 and 0.9% aqueous NaCl solutions. The results indicate that the [...] Read more.

This study investigated the anticorrosive properties of nitride coatings (V,Zr,Nb)N, VN and (Zr,V)N with a thickness of approximately 3 μm, deposited on a substrate of AISI 321 steel. Experiments were conducted in 3.0 and 0.9% aqueous NaCl solutions. The results indicate that the use of (V,Zr,Nb)N, VN and (Zr,V)N coatings to protect AISI 321 steel in corrosive environments (e.g., chloride-containing solutions) allowed corrosion currents to be reduced by 10–20 times (from 7.0 to 0.29 μA/cm²) for a sample with a (Zr,V)N coating in a 3.0% aqueous NaCl solution, and by 2 times (from 0.36 to 0.18 μA/cm²) for a sample with a (V,Zr,Nb)N coating in a 0.9% aqueous NaCl solution. Based on the distribution of elements on the surface of the samples after holding for 168 h in a 3.0% aqueous NaCl solution at 25 °C, it can be qualitatively concluded that the oxidation intensity of the (Zr,V)N coating was the lowest under this condition, and that the VN coating exhibited the highest oxidation intensity among the considered coatings. Analysis of the structure of the (Zr,V)N coating after holding in a 3.0% aqueous NaCl solution for 168 h at 25 °C shows the presence of nanometre-sized chips, while the analysis of the distribution of elements does not record the presence of anything other than the elements comprising the coating. Based on the distribution of elements on the surface of the VN coating, it can be assumed that the destruction of this coating mainly occurs due to peeling off from the substrate; however, corrosion processes also occur in the VN coating itself. Analysis of the distribution of elements in the surface layers of the (V,Zr,Nb)N coating did not show noticeable signs of oxidation. The destruction of this coating occurs due to fragments peeling off from the substrate, while oxidation processes and substrate corrosion do not have a significant effect on the process of (V,Zr,Nb)N coating destruction. Full article

(This article belongs to the Section Composites Manufacturing and Processing)

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26 pages, 5613 KB

Open AccessArticle

Insulation Strategies to Enhance Fire Resistance in Composite Slabs with Reduced Carbon Emissions

by Otavio G. N. Ribeiro, Paulo A. G. Piloto and Gustavo de M. S. Gidrão

J. Compos. Sci. 2025, 9(9), 497; https://doi.org/10.3390/jcs9090497 - 12 Sep 2025

Composite slabs have gained popularity in modern high-rise construction due to their superior load-bearing capacity and reduced self-weight. The vulnerability of the unprotected steel deck under fire conditions poses serious challenges, as the rapid reduction in steel strength and stiffness can compromise structural [...] Read more.

Composite slabs have gained popularity in modern high-rise construction due to their superior load-bearing capacity and reduced self-weight. The vulnerability of the unprotected steel deck under fire conditions poses serious challenges, as the rapid reduction in steel strength and stiffness can compromise structural resistance and accelerate fire spread. This study presents a comprehensive numerical simulation to assess the fire behaviour of a novel composite slab and a new proposal for a simplified method. Three insulation techniques are investigated: a steel shield for the thinner part, a steel shield with the cavity filled with mineral wool, and a mineral wool plate applied from below. The simplified method is proposed to evaluate the fire resistance using new empirical coefficients, recalibrated within the framework of the prEN 1994-1-2 to allow for precise temperature predictions in steel components under standard fire. The numerical model, validated against experimental results, shows that the steel shield insulation extends the time to reach critical temperatures by approximately 25%. In contrast, mineral wool insulation proved to be substantially more effective by reducing temperatures in the UPPER 2 region by up to 89% compared to uninsulated slabs, after 60 min of fire exposure. This significant temperature reduction increases the load-bearing capacity during 60 min of fire exposure by 29%, also resulting in a potential reduction of approximately 22% in carbon emissions. The findings underscore and highlight the potential of these insulation systems to enhance the overall safety and resilience of composite slabs under fire, offering valuable insights for structural fire design. Full article

(This article belongs to the Special Issue Editorial Board Members’ Collection Series: Modeling and Simulation of Composite Materials)

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18 pages, 3492 KB

Open AccessArticle

Wet Compression Molding of Biocomposites for a Transportation Industry Application

by Sharmad Joshi, Daniel Walczyk, Ronald Bucinell and Jaron Kuppers

J. Compos. Sci. 2025, 9(9), 496; https://doi.org/10.3390/jcs9090496 - 12 Sep 2025

The transportation and automotive industries are slowly integrating biocomposite materials into products where the economics make sense; this typically means a short manufacturing cycle time, not using expensive prepreg, and with little waste generated from the process. In a previous investigation into the [...] Read more.

The transportation and automotive industries are slowly integrating biocomposite materials into products where the economics make sense; this typically means a short manufacturing cycle time, not using expensive prepreg, and with little waste generated from the process. In a previous investigation into the use of biocomposites for electric bus seats and backs, three different material systems (hemp, flax, and pure cellulosic fibers, each paired with a high-bio-content epoxy) and two manufacturing processes (wet layup followed by compression molding, vacuum-assisted resin transfer molding) were investigated, but neither process proved to be viable. In this paper, a relatively obscure process called Wet Compression Molding (WCM) is considered for economical production of the biocomposite bus seats using the same three material systems. Darcy’s law predictions of full impregnation time for a nominally 3.5 mm thick part using experimentally determined permeability values are all less than 2 s. Furthermore, prepreg is not used, and net-shape parts without excess resin show potential. Important design details of the WCM mold set, used in the manufacturing of flat test panels from each material system, that are generally not discussed in the literature include a high-pressure O-ring seal, and semi-permeable membranes covering injection pins and vacuum vents (evacuates trapped air) to prevent resin ingress. Biocomposite laminate specimens are fabricated using the mold set in a thermal press and a vacuum pump. Part characterization includes fiber volume fraction estimates and measurements of thickness, density, flexural modulus, and outer fiber maximum stress at failure. Due to its rapid impregnation with just enough resin, WCM should be considered for the economical manufacture of parts similar in shape and size to electric bus seats and backs. Full article

(This article belongs to the Collection Editorial Board Members’ Collection Series: Fibre Composite Materials)

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14 pages, 4634 KB

Open AccessArticle

Functionally Graded WC-Reinforced Stainless-Steel Composites via Casting: Microstructure and Wear Performance

by Aida B. Moreira, Laura M. M. Ribeiro and Manuel F. Vieira

J. Compos. Sci. 2025, 9(9), 495; https://doi.org/10.3390/jcs9090495 - 12 Sep 2025

This study presents an effective route for producing functionally graded metal matrix composites with enhanced abrasion wear resistance by incorporating ex situ Fe–WC preforms into austenitic stainless-steel castings. The preforms, produced by cold-pressing mixed WC and Fe powders, were positioned in the desired [...] Read more.

This study presents an effective route for producing functionally graded metal matrix composites with enhanced abrasion wear resistance by incorporating ex situ Fe–WC preforms into austenitic stainless-steel castings. The preforms, produced by cold-pressing mixed WC and Fe powders, were positioned in the desired locations in sand molds and reacted in situ with the molten steel during casting. This process generated a metallurgically bonded reinforcement zone with a continuous microstructural and compositional gradient, characteristic of a Functionally Graded Material (FGM). Near the surface, the microstructure consisted of a martensitic matrix with WC particles and (W,Fe,Cr)₆C carbides, while towards the base metal, it transitioned to austenitic dendrites with an interdendritic network of Cr- and W-rich carbides, including (W,Fe,Cr)₆C, (Fe,Cr,W)₇C₃, and (Fe,Cr,W)₂₃C₆. Vickers hardness measurements revealed surface-adjacent values (969 ± 72 HV 30) approximately six times higher than those of the base alloy, and micro-abrasion tests demonstrated a 70% reduction in micro-abrasion wear rate in the reinforced zones. These findings show that WC dissolution during casting enables tailored hardness and abrasion wear performance, offering an accessible manufacturing solution for high-demand mechanical environments. Full article

(This article belongs to the Special Issue Functional Composites: Fabrication, Properties and Applications)

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14 pages, 4849 KB

Open AccessArticle

Loading Rate Influence on Delamination Behavior of Reinforced ENF Specimens by Additively Manufactured Interlayer

by Mazaher Salamat-Talab, Hossein Kazemi, Alireza Akhavan-Safar and Lucas F. M. da Silva

J. Compos. Sci. 2025, 9(9), 494; https://doi.org/10.3390/jcs9090494 - 11 Sep 2025

Laminated composites have distinct mechanical properties that suit various industries. However, varying loading rates during their service life increase their vulnerability to one of their main weaknesses, delamination. Moreover, some interlayers that are used to improve delamination resistance are (often) limited, expensive, and [...] Read more.

Laminated composites have distinct mechanical properties that suit various industries. However, varying loading rates during their service life increase their vulnerability to one of their main weaknesses, delamination. Moreover, some interlayers that are used to improve delamination resistance are (often) limited, expensive, and pollute the environment. Therefore, in this study, the performance of additively manufactured organic wood/PLA interlayers was examined in terms of the mode II interlaminar fracture toughness (ILFT) of glass/epoxy composites under 1, 50, and 100 mm/min loading rates, aiming to address these challenges. The experimental findings showed that in non-interleaved specimens, increasing the loading rate improved delamination resistance, primarily because of the distributed shear hackles across the delamination surfaces. However, incorporating 3D-printed interlayers improved ILFT by 76% (at 1 mm/min) and 23% (at 50 mm/min), compared to counterparts without interlayers, driven by synergistic mechanisms, including crack arrest and shear hackle. In contrast, a loading rate of 100 mm/min resulted in a reduction in ILFT of interleaved specimens compared to their counterparts without interlayers due to the inherent brittleness of the interlayers. Also, fractography analyses revealed that shear hackles were the primary fracture feature in all tested conditions. However, in interleaved specimens, an additional mechanism, filament breakage, became evident. Full article

(This article belongs to the Special Issue 3D Printing and Additive Manufacturing of Composites)

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16 pages, 3563 KB

Open AccessArticle

Effect of Polyethylene and Steel Fibers on the Fracture Behavior of Coral Sand Ultra-High Performance Concrete

by Hongwei Han, Xiao Xue, Dongxu Hou, Wei Li, Hao Han and Yudong Han

J. Compos. Sci. 2025, 9(9), 493; https://doi.org/10.3390/jcs9090493 - 10 Sep 2025

As a representative high-performance construction material, ultra-high performance concrete (UHPC) is typically prepared using quartz sand and steel fibers. To alleviate the shortage of building materials in island and reef regions, this study employs coral sand for UHPC preparation and investigates the effects [...] Read more.

As a representative high-performance construction material, ultra-high performance concrete (UHPC) is typically prepared using quartz sand and steel fibers. To alleviate the shortage of building materials in island and reef regions, this study employs coral sand for UHPC preparation and investigates the effects of different fibers on its mechanical properties. This study demonstrates that this approach mitigates brittle failure patterns and enhances the durability of structures. To investigate the enhancement effects of PE and steel fibers on the mechanical properties of coral sand ultra-high performance concrete (CSUHPC), 12 mix designs were formulated, including a plain (no fiber) reference group and PE fiber-reinforced, steel fiber-reinforced, and hybrid fiber combinations. Compressive tests, tensile tests, and three-point bending tests on pre-notched beams were conducted. Key parameters such as 28-day compressive strength, tensile strength, and flexural strength and toughness were measured. A multi-criteria evaluation framework was established to comprehensively assess the integrated performance of each group. The experimental results demonstrated that fiber incorporation significantly enhanced the compressive strength and fracture properties of CSUHPC compared to the plain reference group. Steel fiber-only reinforcement exhibited the most pronounced improvement in compressive strength and fracture properties, while hybrid fiber combinations provided superior tensile performance. Through the established multi-criteria evaluation framework, the optimal comprehensive performance was achieved with a 3% steel fiber dosage, achieving improvements of 0.93 times in compressive strength, 2.80 times in tensile strength, 1.84 times in flexural strength, 192.08 times in fracture energy, and 1.84 times in fracture toughness relative to the control group. Full article

(This article belongs to the Special Issue High-Performance Composite Materials in Construction)

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32 pages, 15669 KB

Open AccessArticle

Numerical Study on the Performance and Failure Modes of Bolted Connections in Pultruded-Fibre-Reinforced Polymer (PFRP) Profiles

by Abdur Rahman, Ingrid Boem and Natalino Gattesco

J. Compos. Sci. 2025, 9(9), 492; https://doi.org/10.3390/jcs9090492 - 10 Sep 2025

The use of pultruded-fibre-reinforced polymer (PFRP) composite profiles in structural applications is rapidly increasing, due to their high strength-to-weight ratio, corrosion resistance, and durability. Bolted joints between PFRP play a critical role, as localized high stresses in a material that typically exhibits brittle [...] Read more.

The use of pultruded-fibre-reinforced polymer (PFRP) composite profiles in structural applications is rapidly increasing, due to their high strength-to-weight ratio, corrosion resistance, and durability. Bolted joints between PFRP play a critical role, as localized high stresses in a material that typically exhibits brittle behaviour—especially in tension and shear—can lead to sudden failure. This study aims to investigate the mechanical performance of such bolted connections (in terms of stiffness, strength, displacement capacities and failure modes), contributing to the development of reliable yet optimized design criteria for structural applications. In particular, numerical analyses of single-bolted connections in PFRP profiles are presented in the paper. To emphasize the general validity of the model and demonstrate its applicability across different configurations, the simulations were validated against experimental results from three separate test campaigns, which varied in both material (three different PFRP composites) and geometry (profile thickness, bolt diameter, and hole–end distance). Finite element models using continuum shell elements in ABAQUS, based on the Hashin failure criteria, successfully captured typical failure modes, including shear-out and pin-bearing. Two analysis approaches—implicit and explicit solvers—were also compared and discussed. Sensitivity analyses were carried out to enhance the model’s accuracy and its computational efficiency. The validated model was then extended to simulate different configurations, investigating the role of the main parameters influencing the connections. Full article

(This article belongs to the Special Issue Editorial Board Members’ Collection Series: Modeling and Simulation of Composite Materials)

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13 pages, 2302 KB

Open AccessArticle

Controlling the Ductile/Fragile Behavior of a 3D-Printed PLA-BaTiO₃ Biocomposite by PBS Addition

by Paul Burel, Mohamed Ragoubi, Pierre Millet, Sébastien Alix and Richard Gattin

J. Compos. Sci. 2025, 9(9), 491; https://doi.org/10.3390/jcs9090491 - 9 Sep 2025

The demand for patient-specific medicine is steadily increasing, particularly with the need for innovative materials capable not only of supporting tissue regeneration but also accelerating it. The aim of this study was to develop a new printable composite material exhibiting ductile behavior, in [...] Read more.

The demand for patient-specific medicine is steadily increasing, particularly with the need for innovative materials capable not only of supporting tissue regeneration but also accelerating it. The aim of this study was to develop a new printable composite material exhibiting ductile behavior, in contrast to brittle failure, in order to support cell growth even under structural compromise. PBS was selected as a blending component with PLA due to its enhanced biocompatibility for bone tissue regeneration. Both neat PLA and the PLA/PBS blend were subsequently combined with BaTiO₃, processed into filaments, 3D printed, and subjected to mechanical testing. PLA-based composites demonstrated higher stiffness under compression, with up to a 6.5% increase in Young’s modulus compared to the blended samples. However, the incorporation of PBS resulted in a more ductile response, as evidenced by three-point bending tests, even at BaTiO₃ concentrations of 10 wt%. This improved ductility is expected to provide safer conditions for cell growth and enable elastic recovery following mechanical loading. Full article

(This article belongs to the Special Issue 3D Printing and Additive Manufacturing of Composites)

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14 pages, 7043 KB

Open AccessArticle

Damage Evolution and Residual Strength Evaluation of Al/CFRTP Adhesive Joints Under Transverse Impact

by Xi Luan, Yulong Deng, Jun Chen and Yibo Li

J. Compos. Sci. 2025, 9(9), 490; https://doi.org/10.3390/jcs9090490 - 9 Sep 2025

Lightweight, high-strength materials formed by bonding aluminum alloy (Al) and carbon-fiber-reinforced thermoplastic (CFRTP) composite materials are widely used in impact-exposed structures, leading to structural damage and reduced service life. In this study, transverse impact experiments were conducted on Al/CFRTP adhesive joints with varying [...] Read more.

Lightweight, high-strength materials formed by bonding aluminum alloy (Al) and carbon-fiber-reinforced thermoplastic (CFRTP) composite materials are widely used in impact-exposed structures, leading to structural damage and reduced service life. In this study, transverse impact experiments were conducted on Al/CFRTP adhesive joints with varying impact energies (10 J, 20 J, 30 J, 40 J) on different impact surfaces (Al and CFRTP). The energy absorption rate, damage morphology, residual strength, strain evolution on the impact surface, and failure mechanisms of the joint cross-section were analyzed. The results show that using CFRTP as the impact surface can minimize damage and maintain residual tensile strength. Regardless of whether Al or CFRTP is used as the impact surface, the energy absorption rate remains around 80%, with the final impact outcome being determined by both impact damage and mechanical interlocking. This study provides a theoretical basis for the design of high-impact-resistant Al/CFRTP adhesive joints. Full article

(This article belongs to the Section Composites Modelling and Characterization)

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28 pages, 4985 KB

Open AccessArticle

The Effect of Surface Treatments on the Mechanical Properties of Low-Density Polyethylene/Natural Rubber Composites Reinforced with Sugarcane Bagasse Ash

by Giovanni Barrera, Leonardo Lataro Paim, Renivaldo José dos Santos, Flavio Camargo Cabrera, Elton Prado dos Reis, Juan Camilo Sánchez, Jaime Jaramillo Carvalho, Alexander Ossa and Aldo Eloizo Job

J. Compos. Sci. 2025, 9(9), 489; https://doi.org/10.3390/jcs9090489 - 9 Sep 2025

Polymeric biocomposites are emerging as a new generation of eco-friendly and cost-effective materials that provide sustainable alternatives for the polymer industry while supporting environmental conservation. This study investigates the mechanical behavior of Low-Density Polyethylene (LDPE) compounds blended with natural rubber (NR) and reinforced [...] Read more.

Polymeric biocomposites are emerging as a new generation of eco-friendly and cost-effective materials that provide sustainable alternatives for the polymer industry while supporting environmental conservation. This study investigates the mechanical behavior of Low-Density Polyethylene (LDPE) compounds blended with natural rubber (NR) and reinforced with silanized Sugarcane Bagasse Ash (SCBA), chemically modified with bis(3 triethoxysilylpropyl) tetrasulfide (TESPT). Blends were formulated in LDPE/NR-SCBA weight ratios (wt%) of 90/10, 70/30, and 50/50, and processed at mixing speeds of 40 and 80 rpm to evaluate their potential as thermoplastic additives. Mechanical testing showed that blends mixed at 80 rpm achieved an 86% increase in elongation, while those processed at 40 rpm demonstrated a 78% enhancement in tensile strength. The incorporation of NR and vulcanizing systems markedly improved the overall mechanical properties of the composites. These biocomposites present promise for applications in the footwear industry (especially for soles) and for ergonomic molded components by conferring the advantageous combination of mechanical performance and esthetic appeal. Furthermore, development supports innovative manufacturing processes and contributes to reducing the industry`s carbon footprints, mitigating its negative impact on the planet. Full article

(This article belongs to the Special Issue Editorial Board Members' Collection Series: Mechanical Analysis of Composite Materials)

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21 pages, 4382 KB

Open AccessArticle

Development and Characterization of Hybrid Coconut-S-Glass Fiber Composites for Enhanced Mechanical and Thermal Performance

by Pankaj Singh Chandel, Nalin Somani, Nitin Kumar Gupta, Appurva Jain and Ali Elrashidi

J. Compos. Sci. 2025, 9(9), 488; https://doi.org/10.3390/jcs9090488 - 8 Sep 2025

Composite materials are replacing traditional metals across various industries as they offer lighter weight and affordability, as well as excellent mechanical properties. In the present work, a hybrid composite was developed by combining randomly oriented S-glass fibers and coconut fibers within an epoxy [...] Read more.

Composite materials are replacing traditional metals across various industries as they offer lighter weight and affordability, as well as excellent mechanical properties. In the present work, a hybrid composite was developed by combining randomly oriented S-glass fibers and coconut fibers within an epoxy matrix by using the hand lay-up method. The laminate was prepared by using two sheets of raw coconut fiber and eight layers of 200 GSM S-glass fiber, maintaining an epoxy-to-hardener ratio of 10:1. The laminate was cured under a hydraulic press at 80 °C for two hours and then post-cured at a temperature of 100 °C for four hours. In order to assess the performance of the composites, a series of tests, including mode II interlaminar fracture toughness, tensile strength, impact resistance, and hardness, as well as thermal conductivity, were performed. SEM analysis of the fracture surfaces confirmed the combined presence of fiber pull-out and good fiber–matrix bonding, supporting the observed improvements in mechanical properties. The results indicate that the hybrid composite has clear advantages over the composites reinforced with individual fibers alone. It showed a 358% higher tensile strength, a 30% increment in impact strength, and roughly 31% better flexural strength as compared to the coconut fiber composite. In comparison to the glass fiber composite, the hybrid composite offered enhanced toughness and better thermal stability, along with lower material costs and improved sustainability due to the addition of the natural fibers. Considering the rising need for lightweight, strong, and eco-friendly materials for industries, this fabricated hybrid composite appears to be a promising option for structural applications in fields like automotive, aerospace, and construction, where reducing weight without compromising strength is essential. Full article

(This article belongs to the Section Polymer Composites)

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22 pages, 7322 KB

Open AccessArticle

Performance of Pultruded FRP Beam-Column Connections Under Different Design Parameters

by Said Abdel-Monsef, Alaa Elsisi, Hassan Maaly and Ossama El-Hosseiny

J. Compos. Sci. 2025, 9(9), 487; https://doi.org/10.3390/jcs9090487 - 8 Sep 2025

In frame structures, connections play a vital role in governing both serviceability and ultimate strength. For pultruded fiber-reinforced polymer (PFRP) frames, connection design is even more critical due to the anisotropic and viscoelastic nature of the composite materials used in the primary elements [...] Read more.

In frame structures, connections play a vital role in governing both serviceability and ultimate strength. For pultruded fiber-reinforced polymer (PFRP) frames, connection design is even more critical due to the anisotropic and viscoelastic nature of the composite materials used in the primary elements (e.g., beams and columns) and their joints. This study presents a finite element model (FEM) to evaluate the influence of several connection parameters—namely, connection stiffening, bolt diameter, washer diameter, and clamping force—on the elastic behavior of beam-column joints composed of PFRP elements. The results demonstrate that stiffening the upper and lower connection angles significantly enhances joint performance. Increasing the bolt diameter improves moment capacity, reduces rotational deformation, decreases stress concentrations around bolt-hole edges, and increases both minor principal and compressive stresses beneath the bolt shank. Similarly, a larger washer diameter contributes to higher connection stiffness and reduces stress concentrations at bolt holes. Although the clamping force has a relatively modest effect on global connection behavior, it positively influences the through-thickness stress distribution in the angle beneath the bolt shank. Finally, regression equations were developed to quantify the relationship between rotation, moment, bolt diameter, washer diameter, and clamping force, providing a valuable tool for the design and optimization of PFRP connections in structural applications. Full article

(This article belongs to the Special Issue Polymer Composites and Fibers, 3rd Edition)

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13 pages, 4881 KB

Open AccessArticle

Optimisation of Fibre-Reinforced Hybrid Composites Under Combined Loading

by Chensong Dong and Joseph Abel Philip Vaidyan

J. Compos. Sci. 2025, 9(9), 486; https://doi.org/10.3390/jcs9090486 - 8 Sep 2025

Fibre-reinforced hybrid composites offer an effective balance between strength, weight, and cost by combining multiple fibre types within a single matrix. This study focuses on optimising the design of carbon/glass fibre-reinforced hybrid composites under combined bending and torsional loading using finite element analysis [...] Read more.

Fibre-reinforced hybrid composites offer an effective balance between strength, weight, and cost by combining multiple fibre types within a single matrix. This study focuses on optimising the design of carbon/glass fibre-reinforced hybrid composites under combined bending and torsional loading using finite element analysis (FEA) and response surface methodology. Twelve different layup configurations, including sandwich and non-sandwich hybrid designs, were analysed to identify the optimal ply angles and fibre volume fractions that maximise failure load while minimising material cost and density. The results reveal that sandwich-type layups, such as [C₃G]_S, [C₂G₂]_S, and [CG₃]_S, demonstrate superior strength-to-weight performance, achieving failure loads exceeding 300 N. The study also confirms that optimal ply angles range from 12° to 30°, depending on the layup configuration, and that increasing the carbon fibre volume fraction generally enhances failure load, though an optimal balance with glass fibres must be maintained. The findings provide valuable design guidelines for engineers seeking to tailor hybrid composites for aerospace, automotive, and structural applications. Future work should focus on experimental validation and extending the analysis to additional loading conditions, such as impact and fatigue, to further improve the robustness of hybrid composite structures. Full article

(This article belongs to the Special Issue Recent Progress in Hybrid Composites)

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25 pages, 7254 KB

Open AccessArticle

Punching Strengthening of Lightweight Aggregate Reinforced Concrete Flat Slabs Using Fiber-Reinforced Polymers

by Esraa Abaza, Mohamed T. Elshazli, Ahmed Elbelbisi, Hamdy Shehab and Mahmoud Zaghlal

J. Compos. Sci. 2025, 9(9), 485; https://doi.org/10.3390/jcs9090485 - 7 Sep 2025

Lightweight Aggregate Reinforced Concrete (LWARC) is increasingly used in structural systems to reduce dead load, especially in flat slabs. This study focuses on LWARC-incorporating polystyrene foam as a partial aggregate replacement, achieving a dry unit weight reduction from 23.0 kN/m³ to 19.0 [...] Read more.

Lightweight Aggregate Reinforced Concrete (LWARC) is increasingly used in structural systems to reduce dead load, especially in flat slabs. This study focuses on LWARC-incorporating polystyrene foam as a partial aggregate replacement, achieving a dry unit weight reduction from 23.0 kN/m³ to 19.0 kN/m³. While beneficial for lowering dead loads, this substitution exacerbates punching shear vulnerability, necessitating innovative strengthening solutions. Fiber-Reinforced Polymers (FRPs), recognized for their high strength-to-weight ratio, corrosion resistance, and adaptability, are employed to address these limitations. This paper evaluates the punching shear strengthening of LWARC flat slabs using externally bonded carbon fiber-reinforced polymer (CFRP) sheets, embedded through-section (ETS) steel bars, and ETS glass fiber-reinforced polymer (GFRP) bars. Ten specimens were tested under concentric loading, including an unstrengthened control slab. Experimental results were compared with predictions from ECP 203-2023, ACI 318-19, and BS 8110 to assess code applicability. Strengthened specimens demonstrated significant improvements in punching capacity and ductility. The ETS steel bar technique increased punching strength by 41% compared to the control, while inclined reinforcement configurations outperformed vertical layouts by 24% due to optimized shear transfer. Full article

(This article belongs to the Special Issue Polymer Composites and Fibers, 3rd Edition)

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18 pages, 6373 KB

Open AccessArticle

Experimental Study on the Cyclic Loading Behavior of Hybrid Fiber-Reinforced Rubber Concrete in Sulfate Environment

by Yushan Liu and Jianyong Pang

J. Compos. Sci. 2025, 9(9), 484; https://doi.org/10.3390/jcs9090484 - 5 Sep 2025

In the saline soil area of western China, the concrete is simultaneously subjected to cyclic loading and sulfate attack. To reveal the effect of sulfate attack on fatigue performance of normal concrete (NC) and hybrid fiber-reinforced rubber concrete (HFRRC), the uniaxial compression test [...] Read more.

In the saline soil area of western China, the concrete is simultaneously subjected to cyclic loading and sulfate attack. To reveal the effect of sulfate attack on fatigue performance of normal concrete (NC) and hybrid fiber-reinforced rubber concrete (HFRRC), the uniaxial compression test and cyclic loading test were carried out on the specimens after sulfate erosion. The loading strain, plastic strain, and elastic strain of the concrete were compared and analyzed. The compressive strength, fatigue resistance, and strain energy of the concrete were compared and analyzed. Ultrasonic Pulse Velocity (UPV) measurements were also used to quantify the damage in sulfate attack tests. The results indicate that the fatigue failure stress of concrete is lower than its uniaxial compressive strength. The fatigue resistance coefficient of HFRRC is always higher than that of NC. Under the cyclic loading with the same level, the stress–strain curve of HFRRC is denser than that of NC, exhibiting good elasticity. The energy evolution is independent of whether or not sulfate attacks, but its growth rate is affected by sulfate erosion time. It can provide an experimental and theoretical foundation for the application of HFRRC in engineering structures subjected to repeated loads in sulfate environments. Full article

(This article belongs to the Special Issue Rubber-Based Composites: Challenges in Reusing Waste and Nanostructures as Fillers)

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12 pages, 1276 KB

Open AccessArticle

Delving into Process–Microstructure–Property Relationships in Cast-Extruded Polylactic Acid/Talc Composite Films: Effect of Different Screw Designs

by Giulia Bernagozzi, Chiara Gnoffo, Rossella Arrigo and Alberto Frache

J. Compos. Sci. 2025, 9(9), 483; https://doi.org/10.3390/jcs9090483 - 4 Sep 2025

In the context of polymer-based composites, the knowledge of the correlations between the processing conditions, the microstructure, and the final properties is essential to tailor polymeric systems for specific applications. Specifically concerning the extrusion process, an accurate design of the screw profile allows [...] Read more.

In the context of polymer-based composites, the knowledge of the correlations between the processing conditions, the microstructure, and the final properties is essential to tailor polymeric systems for specific applications. Specifically concerning the extrusion process, an accurate design of the screw profile allows for achieving composites with modulable microstructures, according to the specific properties required by the intended application. In this work, films of polylactic acid-based composites with 5 wt.% of talc were obtained by means of a single-screw extruder equipped with a flat die and a calender unit. Three different screw profiles, namely a general-purpose compression screw, a screw with a reverse flow zone, and a barrier screw, were employed for the production of films. The ability of the screw profile in varying the degree of filler dispersion and distribution was assessed through morphological and rheological analyses, demonstrating that the barrier screw is more able in disaggregating the talc lamellae. Due to the achieved microstructures, films produced using this screw profile exhibited superior barrier properties, with a decrease of about 27% in the oxygen permeability as compared to unfilled PLA. However, a concurrent decrease in material ductility as compared to the other films was observed. Finally, the thermoformability of the composites was assessed; also in this case, trays with more precise edges and corners were obtained for the film formulated through the barrier screw. Full article

(This article belongs to the Special Issue Trends and Challenges in Developing and Processing Composite Materials)

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17 pages, 10832 KB

Open AccessArticle

Dynamic Compressive Behavior of CFRP-Confined High Water Material

by Feiyang Feng, Shuling Meng, Haishan Huang, Yafei Zhou and Hongchao Zhao

J. Compos. Sci. 2025, 9(9), 482; https://doi.org/10.3390/jcs9090482 - 4 Sep 2025

As mining operations extend deeper underground, support structures are increasingly subjected to severe impact loads. The dynamic mechanical performance of column-type support systems has, therefore, become a pressing concern. In the present research, a Split Hopkinson Pressure Bar (SHPB) apparatus, combined with Scanning [...] Read more.

As mining operations extend deeper underground, support structures are increasingly subjected to severe impact loads. The dynamic mechanical performance of column-type support systems has, therefore, become a pressing concern. In the present research, a Split Hopkinson Pressure Bar (SHPB) apparatus, combined with Scanning Electron Microscopy (SEM), is used to systematically examine how the water-to-cement ratio, number of carbon-fiber reinforced polymer (CFRP) layers, and strain rate influence the dynamic compressive behavior and microstructural evolution of CFRP-confined high-water material. The results indicate that unconfined specimens are strongly strain rate-dependent, with peak strength following a rise–fall trend. A lower water–cement ratio results in a denser internal structure and improved strength. Additionally, CFRP confinement markedly enhances peak strength and impact resistance, refines failure modes, and promotes the formation of denser hydration products by limiting lateral deformation. This confinement effect effectively mitigates microstructural damage under high strain rates. These findings clarify the reinforcement mechanism of CFRP from both macroscopic and microscopic perspectives, offering theoretical insights and engineering references for the design of impact-resistant support systems in deep mining applications. Full article

(This article belongs to the Special Issue Composite Materials for Civil Engineering Applications)

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22 pages, 30478 KB

Open AccessArticle

Influence of Multiaxial Loading and Temperature on the Fatigue Behaviour of 2D Braided Thick-Walled Composite Structures

by Tim Luplow, Jonas Drummer, Richard Protz, Linus Littner, Eckart Kunze, Sebastian Heimbs, Bodo Fiedler, Maik Gude and Marc Kreutzbruck

J. Compos. Sci. 2025, 9(9), 481; https://doi.org/10.3390/jcs9090481 - 4 Sep 2025

While size effects in composite structures have been widely studied under quasi-static uniaxial loading, their influence under fatigue conditions, particularly in the presence of multiaxial stress states and elevated temperatures, remains insufficiently understood. This study investigates the fatigue behaviour of thick-walled [...] Read more.

While size effects in composite structures have been widely studied under quasi-static uniaxial loading, their influence under fatigue conditions, particularly in the presence of multiaxial stress states and elevated temperatures, remains insufficiently understood. This study investigates the fatigue behaviour of thick-walled

\pm 45^{\circ}

braided glass fibre-reinforced polyurethane composite box structures under varying temperature and loading conditions. A combined experimental approach is adopted, coupling quasi-static and fatigue tests on large-scale structures with reference data from standardised coupon specimens. The influence of temperature (23–80 °C) and multiaxial shear–compression loading is systematically evaluated. The results demonstrate a significant temperature-dependent decrease in compressive strength and fatigue life, with a linear degradation trend that aligns closely between the box structure and coupon data. Under moderate multiaxial conditions, the fatigue life of box structures is not significantly impaired compared to uniaxial test coupon specimens. Complementary non-destructive testing using air-coupled ultrasound confirms these trends, demonstrating that guided-wave phase-velocity measurements capture the evolution of anisotropic damage and are therefore suitable for in situ structural health monitoring applications. Furthermore, these findings highlight that (i) the temperature-dependent fatigue behaviour of thick-walled composites can be predicted using small-scale coupon data and (ii) small shear components have a limited impact on fatigue life within the studied loading regime. Full article

(This article belongs to the Section Fiber Composites)

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