Enhancing corrosion resistance of anodized aluminum alloy 6061 via multicomponent silica sol-gel sealing

Chengxuan Lu; Sanchen Xu; Peikun Wang; Xuefei Li; Haijun Ma; Hua Tong; Xinyi Zhou; Jiamin Zhao; Chengxuan Lu; Sanchen Xu; Peikun Wang; Xuefei Li; Haijun Ma; Hua Tong; Xinyi Zhou; Jiamin Zhao

doi:10.3934/matersci.2026007

AIMS Materials Science

2026, Volume 13, Issue 1: 120-140. doi: 10.3934/matersci.2026007

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Enhancing corrosion resistance of anodized aluminum alloy 6061 via multicomponent silica sol-gel sealing

School of Materials Science and Engineering, Shandong Jianzhu University, Jinan 250101, China

Received: 13 November 2025 Revised: 31 December 2025 Accepted: 14 January 2026 Published: 26 January 2026

To mitigate ionic transport through connected pores in anodic aluminum oxide (AAO), a multicomponent silica sol-gel sealing process was applied to AA6061. By varying concentrations of nano-silicon dioxide (SiO₂)—specifically, 0, 2, 4, and 8 g·L^-1—the relationships among coating microstructure, electrochemical response, and corrosion resistance were systematically evaluated. The results indicate that the response to a SiO₂ concentration of 2 g·L^-1 is the most favorable among the tested concentrations. The number of open pores decreased, pore apertures narrowed, and cross-sectional densification was enhanced by this concentration. The total resistance, contributed by both porous and barrier layers, was 191 kΩ·cm². The corrosion current density decreased to 0.61 μA·cm^-2. The sealed coating showed a lower corrosion rate in phosphoric acid immersion and maintained surface integrity after 720 h of neutral salt spray exposure. These findings indicate that silica is incorporated within the pores, effectively filling and extending diffusion pathways. As a result, the pores become less accessible, and the connectivity of the pore network is reduced. The results indicate an effective range of SiO₂ concentration for anodized AA6061, where improved corrosion resistance and enhanced protective characteristics of the anodic oxide layer contribute to greater material durability in corrosive environments.
- AA6061,
- AAO,
- sol-gel,
- corrosion resistance,
- nano-silicon dioxide
Citation: Chengxuan Lu, Sanchen Xu, Peikun Wang, Xuefei Li, Haijun Ma, Hua Tong, Xinyi Zhou, Jiamin Zhao. Enhancing corrosion resistance of anodized aluminum alloy 6061 via multicomponent silica sol-gel sealing[J]. AIMS Materials Science, 2026, 13(1): 120-140. doi: 10.3934/matersci.2026007

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Abstract

To mitigate ionic transport through connected pores in anodic aluminum oxide (AAO), a multicomponent silica sol-gel sealing process was applied to AA6061. By varying concentrations of nano-silicon dioxide (SiO₂)—specifically, 0, 2, 4, and 8 g·L^-1—the relationships among coating microstructure, electrochemical response, and corrosion resistance were systematically evaluated. The results indicate that the response to a SiO₂ concentration of 2 g·L^-1 is the most favorable among the tested concentrations. The number of open pores decreased, pore apertures narrowed, and cross-sectional densification was enhanced by this concentration. The total resistance, contributed by both porous and barrier layers, was 191 kΩ·cm². The corrosion current density decreased to 0.61 μA·cm^-2. The sealed coating showed a lower corrosion rate in phosphoric acid immersion and maintained surface integrity after 720 h of neutral salt spray exposure. These findings indicate that silica is incorporated within the pores, effectively filling and extending diffusion pathways. As a result, the pores become less accessible, and the connectivity of the pore network is reduced. The results indicate an effective range of SiO₂ concentration for anodized AA6061, where improved corrosion resistance and enhanced protective characteristics of the anodic oxide layer contribute to greater material durability in corrosive environments.

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