Designing novel multilayered nanocomposites for high-performance coating materials with online strain monitoring capability
Multilayered nanocomposites, known for its mechanical properties of very high flow strength, ultra-light weight and stable plastic flow to large strains, represent a class of novel composite nanomaterials in which there arises rare opportunities to design new materials from the ground up and to tail...
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sg-ntu-dr.10356-1506332021-08-03T14:08:04Z Designing novel multilayered nanocomposites for high-performance coating materials with online strain monitoring capability Anwar Ali, Hashina Parveen Radchenko, Ihor Zhou, Jiahui Qing, Liu Budiman, Arief Temasek Laboratories @ NTU Engineering::Chemical engineering Nanolayer Dislocation Density Multilayered nanocomposites, known for its mechanical properties of very high flow strength, ultra-light weight and stable plastic flow to large strains, represent a class of novel composite nanomaterials in which there arises rare opportunities to design new materials from the ground up and to tailor their properties to suit exactly their performance requirements. These materials can withstand very high strains in the elastic regime without any inelastic relaxation due to plasticity or fracture compared to its bulk counterparts. This extended elastic regime opens up new possibilities for tuning the physical and chemical properties of materials as well as bringing novel functionalities, such as high performance coating materials with online strain monitoring capability. Our resistivity measurements during ex situ uniaxial micropillar compression in this article suggests basic feasibility of a Cu–Nb multilayered nanocomposite with 20 nm layer thickness having a novel functionality for online strain monitoring capability, in addition to its more known application as a high performance coating materials due to its extraordinary strength and deformability. A linear trend of resistivity with respect to true strain for strains in excess of 3.5% was observed and suggests a significant regime for use for strain sensor/detection/monitoring capability. The authors gratefully acknowledge Dr Nan Li of Los Alamos National Laboratories and Dr Douglas Stauffer, Senior Staff Scientist of Hysitron Inc. for the samples and support provided for the experiments. Critical support and infrastructure provided by Singapore University of Technology and Design (SUTD) during the manuscript preparation is highly appreciated. 2021-08-03T14:08:03Z 2021-08-03T14:08:03Z 2019 Journal Article Anwar Ali, H. P., Radchenko, I., Zhou, J., Qing, L. & Budiman, A. (2019). Designing novel multilayered nanocomposites for high-performance coating materials with online strain monitoring capability. Proceedings of the Institution of Mechanical Engineers, Part L: Journal of Materials: Design and Applications, 233(4), 664-675. https://dx.doi.org/10.1177/1464420717695354 1464-4207 https://hdl.handle.net/10356/150633 10.1177/1464420717695354 2-s2.0-85064150080 4 233 664 675 en Proceedings of the Institution of Mechanical Engineers, Part L: Journal of Materials: Design and Applications © 2017 IMechE. All rights reserved. |
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Engineering::Chemical engineering Nanolayer Dislocation Density Anwar Ali, Hashina Parveen Radchenko, Ihor Zhou, Jiahui Qing, Liu Budiman, Arief Designing novel multilayered nanocomposites for high-performance coating materials with online strain monitoring capability |
| description |
Multilayered nanocomposites, known for its mechanical properties of very high flow strength, ultra-light weight and stable plastic flow to large strains, represent a class of novel composite nanomaterials in which there arises rare opportunities to design new materials from the ground up and to tailor their properties to suit exactly their performance requirements. These materials can withstand very high strains in the elastic regime without any inelastic relaxation due to plasticity or fracture compared to its bulk counterparts. This extended elastic regime opens up new possibilities for tuning the physical and chemical properties of materials as well as bringing novel functionalities, such as high performance coating materials with online strain monitoring capability. Our resistivity measurements during ex situ uniaxial micropillar compression in this article suggests basic feasibility of a Cu–Nb multilayered nanocomposite with 20 nm layer thickness having a novel functionality for online strain monitoring capability, in addition to its more known application as a high performance coating materials due to its extraordinary strength and deformability. A linear trend of resistivity with respect to true strain for strains in excess of 3.5% was observed and suggests a significant regime for use for strain sensor/detection/monitoring capability. |
| author2 |
Temasek Laboratories @ NTU |
| author_facet |
Temasek Laboratories @ NTU Anwar Ali, Hashina Parveen Radchenko, Ihor Zhou, Jiahui Qing, Liu Budiman, Arief |
| format |
Article |
| author |
Anwar Ali, Hashina Parveen Radchenko, Ihor Zhou, Jiahui Qing, Liu Budiman, Arief |
| author_sort |
Anwar Ali, Hashina Parveen |
| title |
Designing novel multilayered nanocomposites for high-performance coating materials with online strain monitoring capability |
| title_short |
Designing novel multilayered nanocomposites for high-performance coating materials with online strain monitoring capability |
| title_full |
Designing novel multilayered nanocomposites for high-performance coating materials with online strain monitoring capability |
| title_fullStr |
Designing novel multilayered nanocomposites for high-performance coating materials with online strain monitoring capability |
| title_full_unstemmed |
Designing novel multilayered nanocomposites for high-performance coating materials with online strain monitoring capability |
| title_sort |
designing novel multilayered nanocomposites for high-performance coating materials with online strain monitoring capability |
| publishDate |
2021 |
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https://hdl.handle.net/10356/150633 |
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1707774601983950848 |