Article
Engineering, Manufacturing
Antonio Vinci, Laura Silvestroni, Nicola Gilli, Luca Zoli, Diletta Sciti
Summary: This study investigates the effects of rare earth oxides on carbon fibre-ZrB2/SiC composites and finds that the addition of Y2O3, La2O3, and CeO2 improves the densification of the material, while Sc2O3 promotes the formation of solid solutions in the matrix. All the composites exhibit improved mechanical properties, but CeO2 is detrimental to the long-term structural stability.
COMPOSITES PART A-APPLIED SCIENCE AND MANUFACTURING
(2022)
Article
Engineering, Manufacturing
Talha J. Pirzada, Shraddha Singh, Robin De Meyere, Philip Earp, Marina Galano, T. James Marrow
Summary: The effects of different processing temperatures on Nextel 312 fiber SiCO ceramic matrix composite were studied, showing that processing at 950 degrees Celsius or above provided a combination of high effective elastic modulus, good resistance to mechanical damage from tensile strain, and good thermal stability.
COMPOSITES PART A-APPLIED SCIENCE AND MANUFACTURING
(2021)
Article
Engineering, Manufacturing
Marco Riva, Alessandro Airoldi, Antonio Maria Caporale, Lorenzo Cavalli, Mario De Stefano Fumo
Summary: This study investigates the interlaminar properties of a C/SiC composite produced by Liquid Silicon Infiltration through experiments and numerical analysis. Experimental methods are introduced to obtain pre-cracks with sharp tips at precise locations, and specimens with different thicknesses are used to study the effects of bending stress states in the delamination process. Numerical techniques are utilized to identify the properties of tri-linear Cohesive Zone Models for simulating delamination, without additional assumptions or testing. The study also considers fiber bridging effects and evaluates process zone lengths using different experimental, analytical, and numerical methods. Overall, the study provides qualitative insights into the delamination process of cost-affordable long fiber reinforced C/SiC laminates, and proposes an experimental and numerical protocol that takes into account the scattering of material properties.
COMPOSITES PART A-APPLIED SCIENCE AND MANUFACTURING
(2023)
Article
Materials Science, Ceramics
Hao Li, Munan Lu, Yufeng Xue, Wenfeng Qiu
Summary: The continuous NextelTM 720 fiber-reinforced zirconia/alumina ceramic matrix composites (CMCs) were prepared by slurry infiltration process and precursor infiltration pyrolysis (PIP) process. The introduction of sub-micron zirconia powders improved the sintering activity, thermal resistance, and mechanical properties of the CMCs. The CMC sample achieved a high flexural strength of 200 MPa after one infiltration cycle of alumina preceramic polymer and thermal treatment.
CERAMICS INTERNATIONAL
(2022)
Article
Materials Science, Ceramics
Longbiao Li
Summary: Under monotonic and cyclic tensile loading, stochastic brittle fragmentations significantly influence the mechanical behavior of fiber-reinforced ceramic-matrix composites (CMCs). Experimental and theoretical models were used to study the synergistic effects of matrix and fiber fragmentations on loading/unloading hysteresis behavior. The study also analyzed the impacts of fiber volume fraction and strength on the hysteresis loops of CMCs, providing valuable insights for composite material design optimization.
CERAMICS INTERNATIONAL
(2021)
Article
Materials Science, Ceramics
Antonio Vinci, Luca Zoli, Laura Silvestroni, Nicola Gilli, Diletta Sciti
Summary: A significant improvement in mechanical performance was achieved in ZrB2-based ultra-high temperature ceramic matrix composites (UHTCMCs) through the introduction of rare earth oxides, resulting in the formation of ternary boro-carbides of general formula REB2C2. This study investigated the potential routes for synthesizing YB2C2 phases at UHTC sintering temperatures by using different boron sources, and analyzed their microstructure using SEM, XRD, and TEM. The findings showed that the mixture with B4C exhibited the highest selectivity for the formation of YB2C2, and a long carbon fibre reinforced YB2C2 ceramic composite with a flexural strength of 380 MPa was successfully fabricated. The chemical stability of these materials in air was also assessed.
JOURNAL OF THE EUROPEAN CERAMIC SOCIETY
(2023)
Article
Engineering, Manufacturing
Lukas Wagner, Georg Puchas, Walter Krenkel, Stefan Schaffoener
Summary: This study investigated the influence of porosity on the mechanical properties of a NextelTM 610/Al2O3-ZrO2 composite. The results showed that as the porosity decreased, the bending strength and strain of the material also decreased. Additionally, the material lost its damage-tolerant behavior at a submicron porosity of 37%.
COMPOSITES PART A-APPLIED SCIENCE AND MANUFACTURING
(2023)
Article
Materials Science, Ceramics
Matteo Mor, Antonio Vinci, Simone Failla, Pietro Galizia, Luca Zoli, Diletta Sciti
Summary: A new technique for manufacturing short fibre-reinforced ultra-refractory ceramics is introduced. It allows the production of solvent-free, thin, flexible, and easy-to-handle sheets suitable for various structures. The composition range can be adjusted from 0% to 100%. By increasing the fibre amount, the mechanical properties of the ceramics showed improvement. Functionally graded composites were also successfully fabricated using this technique.
JOURNAL OF ADVANCED CERAMICS
(2023)
Article
Nanoscience & Nanotechnology
Zhengxiang Song, Xiaoshi Hu, Yeyang Xiang, Kun Wu, Xiaojun Wang
Summary: The toughness of CNTs/Mg laminated composites is improved by intercepting dislocations, producing higher back stress strengthening, delaying crack propagation, and enhancing plastic deformability.
MATERIALS SCIENCE AND ENGINEERING A-STRUCTURAL MATERIALS PROPERTIES MICROSTRUCTURE AND PROCESSING
(2021)
Article
Materials Science, Ceramics
Yuelong Tian, Jidong Hu, Zhihai Feng, Xin Sun, Yuan Li, Yifen Xu
Summary: In this study, carbon fibers reinforced SiCN ceramic matrix composites (C/SiCN) were prepared using homemade polysilazanes (PSN-T03) via PIP. It was found that SiCN ceramics began to lose weight at 1400 degrees C, leading to a collapse in the mechanical properties of C/SiCN composites above this temperature.
JOURNAL OF THE EUROPEAN CERAMIC SOCIETY
(2022)
Review
Engineering, Manufacturing
Xinyuan Lv, Fang Ye, Laifei Cheng, Litong Zhang
Summary: Whisker-reinforced ceramic matrix composites (CMCs) are emerging materials for structural applications at high temperatures. This review presents a composite preparation route that allows for scalability and industrialization. It discusses the sequential preparation of whisker, whisker preform, interphase, and matrix, and the different synthesis methods and morphology control mechanisms of whiskers (SiCw, Si3N4w, Al2O3w). Directions for future development are also proposed.
COMPOSITES PART A-APPLIED SCIENCE AND MANUFACTURING
(2022)
Article
Materials Science, Ceramics
Kazuya Shimoda, Tatsuya Hinoki
Summary: Unidirectional SiCf/SiC-matrix composites with a pyrocarbon interface were prepared by hot-pressing SiC nano powder at high temperature (1900 degrees C) and pressure (20 MPa). The volume fraction of SiC reinforcing fiber significantly affected densification and mechanical properties, with improvements in mechanical properties observed with an increase in fiber volume fraction up to a certain level, beyond which the ultimate strength degraded due to open porosity and fiber damage.
JOURNAL OF THE EUROPEAN CERAMIC SOCIETY
(2021)
Article
Materials Science, Ceramics
Khaled H. Khafagy, Christopher Sorini, Travis Skinner, Aditi Chattopadhyay
Summary: In this study, a three-dimensional viscoplasticity formulation with progressive damage is developed to investigate the time-dependent constituent load transfer and damage behavior in ceramic matrix composites subjected to creep. The formulation, based on Hill's orthotropic plastic potential and the Norton-Bailey creep power law, is used to simulate creep behavior in single fiber SiC/SiC microcomposites. Results show excellent agreement with experimental and numerical data.
CERAMICS INTERNATIONAL
(2021)
Article
Engineering, Manufacturing
Yuekai Yan, Hui Mei, Minggang Zhang, Zhipeng Jin, Yuntian Fan, Laifei Cheng, Litong Zhang
Summary: This paper investigates the interfacial bonding issue in continuous fiber 3D printed ceramics and proposes a method to control the interface through chemical vapor infiltration. Experimental results show that controlling the interface and filling the fiber bundles can improve the mechanical properties of ceramic materials.
COMPOSITES PART A-APPLIED SCIENCE AND MANUFACTURING
(2022)
Article
Engineering, Mechanical
Longbiao Li
Summary: A micromechanical approach was developed to predict crack opening displacement (COD) of fiber-reinforced ceramic-matrix composites under tensile loading, considering matrix fragmentation and fiber/matrix interface debonding. Relationships between composite constituent properties, COD, and matrix fragmentation were established, and the effects of various factors on crack behavior were analyzed, providing insights into the mechanisms governing crack initiation and propagation in such composite materials.
THEORETICAL AND APPLIED FRACTURE MECHANICS
(2021)
Article
Materials Science, Composites
Xi Liu, Wei Shen, Jincun Fu, Toshiaki Natsuki, Lvtao Zhu
Summary: The 3-D carbon fiber reinforced resin matrix composite tubes were designed and formed using a novel braiding-winding-pultrusion processing technique. The effects of temperature environments on the mechanical responses and damage behaviors of the composite tubes were investigated, and it was found that the structural design of the tubes directly affects their axial bearing capacity.
COMPOSITES SCIENCE AND TECHNOLOGY
(2024)
Article
Materials Science, Composites
Weihao Yuan, Ziyang Zhang, Yueshan Li, Yudong Huang, Zhengxiang Zhong, Zhen Hu
Summary: In this study, the simultaneous self-healing of matrix and interface damage of fiber-reinforced composites was achieved by integrating extrinsic self-healing based on microcapsules and internal self-healing based on coordination interaction. The high exothermic action of epoxy resin and mercaptan repair agent in the self-healing process was observed using infrared thermal imaging technology for in-situ and real-time damage detection.
COMPOSITES SCIENCE AND TECHNOLOGY
(2024)
Article
Materials Science, Composites
Israr Ud Din, Adnan Ahmed, Farah Tarek, Wesley Cantwell, Kamran A. Khan
Summary: In this study, a finite element model driven by XCT was developed to simulate the folding characteristics of origami structures, and the results showed good agreement with experimental data. The study demonstrates the potential application of XCT-driven FE modeling in simulating foldable structures.
COMPOSITES SCIENCE AND TECHNOLOGY
(2024)
Article
Materials Science, Composites
Yishan Yang, Yukang Lai, Song Zhao, Hongguang Chen, Renshu Li, Yongjiang Wang
Summary: This study reports the synthesis of a new transparent fiber reinforced polymer material (tGFRP) with high transparency and superior mechanical properties by controlling the refractive index of epoxy resin and using a novel processing technique.
COMPOSITES SCIENCE AND TECHNOLOGY
(2024)
Article
Materials Science, Composites
Yuhang Liu, Kai Huang, Junfeng Ding, Shangyang Yu, Zhixing Li, Li Zhang, Licheng Guo
Summary: This study proposes a method for accurately predicting the penetration failure load of composites using acoustic emission (AE) data. The method includes a cyclic loading test schedule and an extrapolation method based on uncertainty. The results show that this method can accurately predict the failure load when LR equals 1.
COMPOSITES SCIENCE AND TECHNOLOGY
(2024)
Article
Materials Science, Composites
Jinxia Cai, Bing Xie, Yunliang Jiang, Jinshan Lu, Zeyu Li, Pu Mao, Mohsin Ali Marwat, Haibo Zhang
Summary: This research aims to develop ternary nanocomposites composed of polycarbonate, Al2O3 nanoparticles, and BaTiO3 nanowires for capacitive energy-storage. By optimizing the capacitor materials, the discharge energy density and efficiency have been improved, and the superiority of the ternary polymer nanocomposites for dielectric energy-storage has been validated through finite element analysis.
COMPOSITES SCIENCE AND TECHNOLOGY
(2024)
Article
Materials Science, Composites
Hon Lam Cheung, Mohsen Mirkhalaf
Summary: The aim of this study is to develop physics-based models and establish a structure-property relationship for short fiber composites. High-fidelity full-field simulations are computationally expensive and time-consuming, so the use of artificial neural networks and transfer learning technique is proposed to solve this issue and improve modeling accuracy and efficiency.
COMPOSITES SCIENCE AND TECHNOLOGY
(2024)
Article
Materials Science, Composites
Yue Jiang, Juyoung Leem, Ashley M. Robinson, Shuai Wu, Andy H. Huynh, Dongwon Ka, Ruike Renee Zhao, Yan Xia, Xiaolin Zheng
Summary: The effect of interface engineering on the combustion and mechanical performance of high-loading B/HTPB composites was investigated in this study. It was found that both covalently bonded and nonpolar/nonpolar interfaces effectively reduced the aggregation of B particles, promoting combustion efficiency and burning rate, and enhancing the mechanical properties of the composites.
COMPOSITES SCIENCE AND TECHNOLOGY
(2024)
Article
Materials Science, Composites
R. Mohsenzadeh, B. H. Soudmand, A. H. Najafi, M. Fattahi, D. P. Uyen
Summary: This study examines the morphological features of nano-zeolite nanoparticles incorporated into ultra-high molecular weight polyethylene nanocomposites. The dispersion of nanoparticles within the polymer matrix was improved following nano-zeolite incorporation. The size and distribution of nanoparticles were determined through tailored histograms, and the effective elastic moduli of nanocomposites were calculated, considering interfacial effects.
COMPOSITES SCIENCE AND TECHNOLOGY
(2024)
Article
Materials Science, Composites
Chunming Ji, Jiqiang Hu, Rene Alderliesten, Jinchuan Yang, Zhengong Zhou, Yuguo Sun, Bing Wang
Summary: This paper investigates the effect of impact damage on the fatigue behavior of CF/PEEK-titanium hybrid laminates. A fatigue life model is proposed to predict the S-N curves of the laminates based on energy dissipation approach. The energy dissipation behavior of the laminates under different experimental conditions is analyzed through post-impact fatigue tests, and the correlation between impact damage and fatigue dissipation energy is determined. The validity of the proposed model is verified through fatigue tests under different stress ratios and impact energy levels.
COMPOSITES SCIENCE AND TECHNOLOGY
(2024)
Article
Materials Science, Composites
Shaokai Hu, Ping Han, Chao Meng, Ying Yu, Shaolong Han, Haoyu Wang, Gang Wei, Zheng Gu
Summary: This study decorates MXene on the surface of carbon fiber using different bonding interactions to improve the interface adhesion and mechanical properties of carbon fiber-reinforced polymers composites (CFRPs). The results demonstrate that CFRPs reinforced by CF-c-MXene show the optimal properties, with significant improvements in impact strength and interfacial shear strength compared to the unsized carbon fiber-reinforced composites.
COMPOSITES SCIENCE AND TECHNOLOGY
(2024)
Article
Materials Science, Composites
Steven U. Mamolo, Henry A. Sodano
Summary: This study demonstrates that chlorination of ANFs and oxygen plasma treatment of carbon fibers enables the formation of a chlorinated ANF (Cl-ANF) interphase, resulting in a 79.8% increase in interfacial shear strength and a 33.7% increase in short beam strength in CFRP composites. This method provides a rapid and reliable process to improve the mechanical properties of CFRPs without degrading the tensile strength of the carbon fibers.
COMPOSITES SCIENCE AND TECHNOLOGY
(2024)
Article
Materials Science, Composites
Yuyang Zhang, Huimin Li, Xin Liu, Yanhong Chen, Chengwei Qin, Daining Fang
Summary: Establishing a prediction model for the mechanical properties of three-dimensional tubular braided composites at different temperatures is of great significance. This study adopted a multi-scale modeling framework based on micro-computed tomography to consider the characteristics of the real yarn cross section and establish a realistic trans-scale finite element model for the composites. The predicted mechanical properties were found to be significantly affected by temperature.
COMPOSITES SCIENCE AND TECHNOLOGY
(2024)
Article
Materials Science, Composites
Shengtao Dai, Fei Yan, Jiaming Guo, Huiru Hu, Yu Liu, Liu Liu, Yuhui Ao
Summary: This study successfully synthesized a hyperbranched waterborne polyurethane sizing agent and cellulose nanocrystal modified zinc oxide nanohybrids to improve the interface and properties of carbon fiber reinforced composites. The modified composites exhibited remarkable enhancements in mechanical properties and exceptional UV resistance.
COMPOSITES SCIENCE AND TECHNOLOGY
(2024)
Article
Materials Science, Composites
Libera Vitiello, Martina Salzano de Luna, Veronica Ambrogi, Giovanni Filippone
Summary: The identification of the percolation threshold in short fiber composites is crucial for assessing material properties and biodegradation speed. In this study, an original rheological approach was used to estimate the percolation threshold of hemp and kenaf-based composites, which showed good agreement with conventional dielectric spectroscopy analyses.
COMPOSITES SCIENCE AND TECHNOLOGY
(2024)