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Main Authors: Jinzhan Guo, Lihua Zhan, Bolin Ma, Guangming Dai, Yisa Fan, Dechao Zhang, Xin Hu, Min Xie, Zheng Cao
Format: Artículo Open Access
Published: Wiley 2024
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Online Access:https://4spepublications.onlinelibrary.wiley.com/doi/10.1002/pc.29310
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author Jinzhan Guo
Lihua Zhan
Bolin Ma
Guangming Dai
Yisa Fan
Dechao Zhang
Xin Hu
Min Xie
Zheng Cao
author_facet Jinzhan Guo
Lihua Zhan
Bolin Ma
Guangming Dai
Yisa Fan
Dechao Zhang
Xin Hu
Min Xie
Zheng Cao
Jinzhan Guo
Lihua Zhan
Bolin Ma
Guangming Dai
Yisa Fan
Dechao Zhang
Xin Hu
Min Xie
Zheng Cao
collection Wiley Open Access
contents Surface modification of nano‐ SiO 2 and its interaction mechanism in the interface of fiber metal laminates: Experimental and MD simulation analysis Jinzhan Guo Lihua Zhan Bolin Ma Guangming Dai Yisa Fan Dechao Zhang Xin Hu Min Xie Zheng Cao Polymer Composites Abstract In order to optimize the reinforcing effect of nano‐SiO 2 on the interface of fiber metal laminates (FMLs), the nano‐SiO 2 was treated by ultraviolet irradiation and silane coupling agent for different surface properties. The interaction mechanisms of nano‐SiO 2 were studied by mechanical test, chemical analysis, morphology observation, and molecular dynamics (MD) simulation. The results showed that the average failure strength of FMLs with untreated, hydrophilic and lipophilic nano‐SiO 2 increases by 31.80%, 48.77%, and 51.38% compared to the FMLs without SiO 2 , respectively, and the interface fracture energy for those increases by 31.50%, 74.82%, and 21.47%, respectively. The disparity among the properties is primarily attributed to the surface polarity. The surface group of untreated and hydrophilic SiO 2 is hydroxyl, which shows stronger attraction to resin but also easy to agglomerate, while the lipophilic is silane group that shows lower polarity, resulting in weaker attraction to resin but easier dispersion within the resin. Specifically, the surface polarity was verified by characterizing the particle center distance and the number of atoms surrounded by the particle in the two‐particle model. Moreover, the simulation revealed that nano‐SiO 2 and resin molecules are mainly connected by chemical bond and hydrogen bond to transfer the load. Highlights The mechanism was explored by experiment and molecular dynamic simulation. The addition of lipophilic SiO 2 increased the failure strength by 51.38%. The incorporation of hydrophilic SiO 2 enhanced fracture energy by 74.82%. The polarity of the surface group of SiO 2 affected the agglomeration/dispersion. The SiO 2 and resin were mainly connected by chemical bond and hydrogen bond. 10.1002/pc.29310 http://onlinelibrary.wiley.com/termsAndConditions#vor
doi_str_mv 10.1002/pc.29310
format Artículo Open Access
id wiley_oa_10_1002_pc_29310
institution Wiley Open Access
license_str_mv http://onlinelibrary.wiley.com/termsAndConditions#vor
publishDate 2024
publisher Wiley
record_format wiley_oa
spellingShingle Surface modification of nano‐ SiO 2 and its interaction mechanism in the interface of fiber metal laminates: Experimental and MD simulation analysis
Jinzhan Guo
Lihua Zhan
Bolin Ma
Guangming Dai
Yisa Fan
Dechao Zhang
Xin Hu
Min Xie
Zheng Cao
Polymer Composites
Surface modification of nano‐ SiO 2 and its interaction mechanism in the interface of fiber metal laminates: Experimental and MD simulation analysis Jinzhan Guo Lihua Zhan Bolin Ma Guangming Dai Yisa Fan Dechao Zhang Xin Hu Min Xie Zheng Cao Polymer Composites Abstract In order to optimize the reinforcing effect of nano‐SiO 2 on the interface of fiber metal laminates (FMLs), the nano‐SiO 2 was treated by ultraviolet irradiation and silane coupling agent for different surface properties. The interaction mechanisms of nano‐SiO 2 were studied by mechanical test, chemical analysis, morphology observation, and molecular dynamics (MD) simulation. The results showed that the average failure strength of FMLs with untreated, hydrophilic and lipophilic nano‐SiO 2 increases by 31.80%, 48.77%, and 51.38% compared to the FMLs without SiO 2 , respectively, and the interface fracture energy for those increases by 31.50%, 74.82%, and 21.47%, respectively. The disparity among the properties is primarily attributed to the surface polarity. The surface group of untreated and hydrophilic SiO 2 is hydroxyl, which shows stronger attraction to resin but also easy to agglomerate, while the lipophilic is silane group that shows lower polarity, resulting in weaker attraction to resin but easier dispersion within the resin. Specifically, the surface polarity was verified by characterizing the particle center distance and the number of atoms surrounded by the particle in the two‐particle model. Moreover, the simulation revealed that nano‐SiO 2 and resin molecules are mainly connected by chemical bond and hydrogen bond to transfer the load. Highlights The mechanism was explored by experiment and molecular dynamic simulation. The addition of lipophilic SiO 2 increased the failure strength by 51.38%. The incorporation of hydrophilic SiO 2 enhanced fracture energy by 74.82%. The polarity of the surface group of SiO 2 affected the agglomeration/dispersion. The SiO 2 and resin were mainly connected by chemical bond and hydrogen bond. 10.1002/pc.29310 http://onlinelibrary.wiley.com/termsAndConditions#vor
title Surface modification of nano‐ SiO 2 and its interaction mechanism in the interface of fiber metal laminates: Experimental and MD simulation analysis
topic Polymer Composites
url https://4spepublications.onlinelibrary.wiley.com/doi/10.1002/pc.29310