V. Semeykina, C. Appiah, S. Rothberg, S. Heinrich, D. Giuntini, G. A. Schneider
{"title":"珍珠层状复合材料的预期与现实:颗粒填料和聚合物封闭在机械性能中的主导作用","authors":"V. Semeykina, C. Appiah, S. Rothberg, S. Heinrich, D. Giuntini, G. A. Schneider","doi":"10.1007/s42114-024-01107-x","DOIUrl":null,"url":null,"abstract":"<div><p>After decades of research, mimicking the intricate structure of nacre shells with flawlessly packed blocks remains a laborious task in composite material design. For practical reasons, less ideal alternatives with reduced packing densities below 70 vol.% are often being explored. However, the extent to which the features of the nacre structure can be exploited remains unclear. This paper investigates whether mimicking nacre design in non-densely packed composites can still deliver exceptional mechanical performance. A wide range of ceramic particles (80–100 µm, including spheres and platelets) and methacrylate-based polymers was studied. All the composites exhibited little variation in strength (100–150 MPa) and E-modulus regardless of hierarchical structure, particle size, shape, or interfacial bonding, highlighting the greater importance of particle packing over these factors for ceramic loadings below 65 vol.%. In particular, the benefits of micron-sized anisotropic particles were diminished by the fundamental challenges in aligning such blocks: although these assemblies significantly enhanced fracture resistance, the elastic modulus was still lower than expected (25 GPa). A polydisperse mixture of irregularly shaped micron-sized particles surprisingly achieved a high elastic modulus of 20 GPa, suggesting that an optimized size distribution can provide benefits comparable to those of particle anisotropy. Composites loaded with small particles (< 500 nm) exhibited two key effects: the solvation shells contributed to the total organic content significantly, limiting the maximum ceramic loading, and the polymer confined within small interparticle voids exhibited increased stiffness, leading to more brittle fracture despite the abundance of organic phase. Both phenomena should be accounted for in theoretical simulations and the practical design of composite materials.</p><h3>Graphical Abstract</h3>\n<div><figure><div><div><picture><source><img></source></picture></div></div></figure></div></div>","PeriodicalId":7220,"journal":{"name":"Advanced Composites and Hybrid Materials","volume":"8 1","pages":""},"PeriodicalIF":23.2000,"publicationDate":"2024-12-20","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"https://link.springer.com/content/pdf/10.1007/s42114-024-01107-x.pdf","citationCount":"0","resultStr":"{\"title\":\"Expectations vs. reality in nacre-like composites: dominating role of particle packing and polymer confinement in mechanical performance\",\"authors\":\"V. Semeykina, C. Appiah, S. Rothberg, S. Heinrich, D. Giuntini, G. A. Schneider\",\"doi\":\"10.1007/s42114-024-01107-x\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"<div><p>After decades of research, mimicking the intricate structure of nacre shells with flawlessly packed blocks remains a laborious task in composite material design. For practical reasons, less ideal alternatives with reduced packing densities below 70 vol.% are often being explored. However, the extent to which the features of the nacre structure can be exploited remains unclear. This paper investigates whether mimicking nacre design in non-densely packed composites can still deliver exceptional mechanical performance. A wide range of ceramic particles (80–100 µm, including spheres and platelets) and methacrylate-based polymers was studied. All the composites exhibited little variation in strength (100–150 MPa) and E-modulus regardless of hierarchical structure, particle size, shape, or interfacial bonding, highlighting the greater importance of particle packing over these factors for ceramic loadings below 65 vol.%. In particular, the benefits of micron-sized anisotropic particles were diminished by the fundamental challenges in aligning such blocks: although these assemblies significantly enhanced fracture resistance, the elastic modulus was still lower than expected (25 GPa). A polydisperse mixture of irregularly shaped micron-sized particles surprisingly achieved a high elastic modulus of 20 GPa, suggesting that an optimized size distribution can provide benefits comparable to those of particle anisotropy. Composites loaded with small particles (< 500 nm) exhibited two key effects: the solvation shells contributed to the total organic content significantly, limiting the maximum ceramic loading, and the polymer confined within small interparticle voids exhibited increased stiffness, leading to more brittle fracture despite the abundance of organic phase. 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Expectations vs. reality in nacre-like composites: dominating role of particle packing and polymer confinement in mechanical performance
After decades of research, mimicking the intricate structure of nacre shells with flawlessly packed blocks remains a laborious task in composite material design. For practical reasons, less ideal alternatives with reduced packing densities below 70 vol.% are often being explored. However, the extent to which the features of the nacre structure can be exploited remains unclear. This paper investigates whether mimicking nacre design in non-densely packed composites can still deliver exceptional mechanical performance. A wide range of ceramic particles (80–100 µm, including spheres and platelets) and methacrylate-based polymers was studied. All the composites exhibited little variation in strength (100–150 MPa) and E-modulus regardless of hierarchical structure, particle size, shape, or interfacial bonding, highlighting the greater importance of particle packing over these factors for ceramic loadings below 65 vol.%. In particular, the benefits of micron-sized anisotropic particles were diminished by the fundamental challenges in aligning such blocks: although these assemblies significantly enhanced fracture resistance, the elastic modulus was still lower than expected (25 GPa). A polydisperse mixture of irregularly shaped micron-sized particles surprisingly achieved a high elastic modulus of 20 GPa, suggesting that an optimized size distribution can provide benefits comparable to those of particle anisotropy. Composites loaded with small particles (< 500 nm) exhibited two key effects: the solvation shells contributed to the total organic content significantly, limiting the maximum ceramic loading, and the polymer confined within small interparticle voids exhibited increased stiffness, leading to more brittle fracture despite the abundance of organic phase. Both phenomena should be accounted for in theoretical simulations and the practical design of composite materials.
期刊介绍:
Advanced Composites and Hybrid Materials is a leading international journal that promotes interdisciplinary collaboration among materials scientists, engineers, chemists, biologists, and physicists working on composites, including nanocomposites. Our aim is to facilitate rapid scientific communication in this field.
The journal publishes high-quality research on various aspects of composite materials, including materials design, surface and interface science/engineering, manufacturing, structure control, property design, device fabrication, and other applications. We also welcome simulation and modeling studies that are relevant to composites. Additionally, papers focusing on the relationship between fillers and the matrix are of particular interest.
Our scope includes polymer, metal, and ceramic matrices, with a special emphasis on reviews and meta-analyses related to materials selection. We cover a wide range of topics, including transport properties, strategies for controlling interfaces and composition distribution, bottom-up assembly of nanocomposites, highly porous and high-density composites, electronic structure design, materials synergisms, and thermoelectric materials.
Advanced Composites and Hybrid Materials follows a rigorous single-blind peer-review process to ensure the quality and integrity of the published work.
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