Balancing degradability and mechanical strength in keto modified polyethylene through hydrogen bonds
Enhancing the degradability of polyethylene (PE) through keto group incorporation stands as a rising research frontier. The overall impact of these functional groups on PE’s degradability and mechanical properties at the atomic scale is not fully understood. Employing computer simulations, we invest...
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sg-ntu-dr.10356-1792642024-07-24T00:50:00Z Balancing degradability and mechanical strength in keto modified polyethylene through hydrogen bonds Li, Ke Chen, Xi Pan, Yuqing Min, Benzhi Ye, Enyi Li, Shuzhou Li, Zibiao Loh, Xian Jun School of Materials Science and Engineering Engineering Degradability Keto groups Enhancing the degradability of polyethylene (PE) through keto group incorporation stands as a rising research frontier. The overall impact of these functional groups on PE’s degradability and mechanical properties at the atomic scale is not fully understood. Employing computer simulations, we investigate the degradability and mechanical properties of keto-modified PE (KMPE). Adding keto groups to the PE chain decreases its photostability, our findings reveal that increase in keto group concentration further amplifies degradation, albeit with minimal impact on photostability. Increasing the keto content (up to 5% in our simulations) leads to reduced polymer crystallinity, while the associated loss in mechanical strength is limited. This study shows that hydrogen bonding plays a compensatory role in KMPE by mitigating the reduction in mechanical properties due to keto group addition, effectively counterbalancing structural alterations to maintain mechanical integrity. These insights deepen our understanding of KMPE’s structure-property relationship, guiding the design of degradable materials. Agency for Science, Technology and Research (A*STAR) Ministry of Education (MOE) This project is supported by A*STAR under RIE2025 Manufacturing, Trade and Connectivity (MTC) Programmatic Funding (M22K9b0049). S. L. acknowledges support from the Ministry of Education (MOE) Singapore Tier 1 (RG5/22). 2024-07-24T00:50:00Z 2024-07-24T00:50:00Z 2024 Journal Article Li, K., Chen, X., Pan, Y., Min, B., Ye, E., Li, S., Li, Z. & Loh, X. J. (2024). Balancing degradability and mechanical strength in keto modified polyethylene through hydrogen bonds. ACS Materials Letters, 6(6), 2259-2266. https://dx.doi.org/10.1021/acsmaterialslett.4c00461 2639-4979 https://hdl.handle.net/10356/179264 10.1021/acsmaterialslett.4c00461 2-s2.0-85192858070 6 6 2259 2266 en M22K9b0049 RG5/22 ACS Materials Letters © 2024 American Chemical Society. All rights reserved. |
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Engineering Degradability Keto groups |
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Engineering Degradability Keto groups Li, Ke Chen, Xi Pan, Yuqing Min, Benzhi Ye, Enyi Li, Shuzhou Li, Zibiao Loh, Xian Jun Balancing degradability and mechanical strength in keto modified polyethylene through hydrogen bonds |
| description |
Enhancing the degradability of polyethylene (PE) through keto group incorporation stands as a rising research frontier. The overall impact of these functional groups on PE’s degradability and mechanical properties at the atomic scale is not fully understood. Employing computer simulations, we investigate the degradability and mechanical properties of keto-modified PE (KMPE). Adding keto groups to the PE chain decreases its photostability, our findings reveal that increase in keto group concentration further amplifies degradation, albeit with minimal impact on photostability. Increasing the keto content (up to 5% in our simulations) leads to reduced polymer crystallinity, while the associated loss in mechanical strength is limited. This study shows that hydrogen bonding plays a compensatory role in KMPE by mitigating the reduction in mechanical properties due to keto group addition, effectively counterbalancing structural alterations to maintain mechanical integrity. These insights deepen our understanding of KMPE’s structure-property relationship, guiding the design of degradable materials. |
| author2 |
School of Materials Science and Engineering |
| author_facet |
School of Materials Science and Engineering Li, Ke Chen, Xi Pan, Yuqing Min, Benzhi Ye, Enyi Li, Shuzhou Li, Zibiao Loh, Xian Jun |
| format |
Article |
| author |
Li, Ke Chen, Xi Pan, Yuqing Min, Benzhi Ye, Enyi Li, Shuzhou Li, Zibiao Loh, Xian Jun |
| author_sort |
Li, Ke |
| title |
Balancing degradability and mechanical strength in keto modified polyethylene through hydrogen bonds |
| title_short |
Balancing degradability and mechanical strength in keto modified polyethylene through hydrogen bonds |
| title_full |
Balancing degradability and mechanical strength in keto modified polyethylene through hydrogen bonds |
| title_fullStr |
Balancing degradability and mechanical strength in keto modified polyethylene through hydrogen bonds |
| title_full_unstemmed |
Balancing degradability and mechanical strength in keto modified polyethylene through hydrogen bonds |
| title_sort |
balancing degradability and mechanical strength in keto modified polyethylene through hydrogen bonds |
| publishDate |
2024 |
| url |
https://hdl.handle.net/10356/179264 |
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1814047202805284864 |