Synergistic mechanism of ASP on growth and corrosion protection of Mg-Al-Ca-LDH film on Mg-Li alloy

Abstract

The Mg-Al-Ca-LDH film was prepared on Mg-Li alloy by means of the in-situ hydrothermal method, with aspartic acid (ASP) acting both as a growth regulator and a corrosion inhibitor. The microstructure of the film was characterized by means of SEM, EDS, XRD and FT-IR. The corrosion resistance of the samples was evaluated using electrochemical impedance spectroscopy and a hydrogen evolution test. The results demonstrated that: at a concentration of 0.1 M aspartic acid, the film exhibits a needle-like structure. The charge transfer resistance of the film is measured at 926.9 ohm·cm². This value is two orders of magnitude higher than that of the substrate and higher than that of Mg-Al-Ca LDH film. Furthermore, the self-corrosion current density of the film is the lowest in comparison with other concentration films. Following an immersion period of 216 h, the presence of the LDH peak on the (003) crystal plane, both prior to and following corrosion. It indicates the persistence of a substantial film layer on the surface. Aspartic acid has been demonstrated to facilitate the self-healing of metal matrix through the regulation of the orientation of LDH nanosheets within the film, ion exchange with Cl⁻ in the etching solution and the promotion of recrystallization of cations released from the damaged film.

Keywords

LA103Z Mg-Li alloy Mg-Al-Ca-LDH films aspartic acid LDH corrosion resistance

Get full access to this article

View all access options for this article.

References

Wang

Luan

, et al. Research progress on the corrosion behavior of magnesium-lithium-based alloys: a review. Acta Metall Sin (Engl Lett) 2019; 32: 1–9.

Kuc

Hadasik

Mizera

, et al. Plasticity and microstructure of magnesium-lithium alloys. S S P 2013; 212: 11–14.

Wang

Guan

, et al. A new approach to improving the macrosegregation in zirconium-containing magnesium-lithium alloy. Materialwiss Werkstofftech 2018; 49: 1125–1134.

Song

Shan

Chen

, et al. Investigation of surface oxide film on magnesium lithium alloy. J Alloys Compd 2009; 484: 585–590.

Liu

Gao

. The effect of substrate on the electroless nickel plating of Mg and Mg alloys. Surf Coat Technol 2007; 200: 3553–3560.

Cui

Zeng

Guan

, et al. Degradation mechanism of micro-arc oxidation coatings on biodegradable Mg-Ca alloys: the influence of porosity. J Alloys Compd 2017; 695: 2464–2476.

Ding

Zheng

, et al. Fabrication and characterization of an actively protective Mg-Al LDHs/Al₂O₃ composite coating on magnesium alloy AZ31. Appl Surf Sci 2019; 487: 558–568.

Zhang

Meng

, et al. Investigation of anti-corrosion performance of ZIF-8/Zn(OH)F composite films on Zn-Al coating. Corros Eng Sci Technol 2025; 60: 667–675.

Zhang

Song

, et al. Corrosion resistance of a super-hydrophobic dodecyltrimethoxysilane-based polypropylene coating on magnesium alloy AZ31. Corros Eng Sci Technol 2025; 60: 676–688.

10.

Geetanjali

Barsha

Sony

. Layered double hydroxides: a brief review from fundamentals to application as evolving biomaterials. Appl Clay Sci 2018; 153: 172–186.

11.

Iqbal

Sun

LaChance

, et al. In situ growth of a CaAl-NO³⁻-layered double hydroxide film directly on an aluminum alloy for corrosion resistance. Dalton Trans 2020; 49: 3956–3964.

12.

Asl

Zhao

Anjum

, et al. The effect of cerium cation on the microstructure and anti-corrosion performance of LDH conversion coatings on AZ31 magnesium alloy. J Alloys Compd 2020; 821: 153248–153248.

13.

Liang

Peng

, et al. Electrochemical deposition and characterization of Zn-Al layered double hydroxides (LDHs) films on magnesium alloy. Appl Surf Sci 2014; 313: 834–840.

14.

Zhang

Sun

, et al. Fabrication of oriented layered double hydroxide films by spin coating and their use in corrosion protection. Chem Eng J 2008; 141: 362–367.

15.

Alias

. Synthesis of layered double hydroxides for anti-corrosion coatings on magnesium alloys: A review. Corros Eng Sci Technol 2025; 60: 1–14.

16.

Zhang

Hou

, et al. Improvement of anticorrosion properties of LA103Z Mg-Li alloy based on fabricated Mg-Al layered double hydroxide films. J Mater Eng Perform 2023; 33: 6328–6340.

17.

Sovík

Hadzima

Papenberg

, et al. Investigations of electrochemical characteristics of Mg-Al-Ca alloys. Crystals (Basel) 2023; 13: 1684.

18.

Sui

Liu

Bai

, et al. Phosphate loaded layered double hydroxides for active corrosion protection of carbon steel. Corros Eng Sci Technol 2022; 57: 7–14.

19.

Zhang

Zahedi Asl

, et al. Investigation of the corrosion inhibition performances of various inhibitors for carbon steel in CO₂ and CO₂/H₂S environments. Corros Eng Sci Technol 2020; 55: 531–538.

20.

Tedim

Poznyak

Kuznetsova

, et al. Enhancement of active corrosion protection via combination of inhibitor-loaded nanocontainers. ACS Appl Mater Interfaces 2010; 5: 1528–1535.

21.

Hou

Sun

, et al. Enhancement corrosion resistance of MgAl layered double hydroxides films by anion-exchange mechanism on magnesium alloys. Appl Surf Sci 2019; 487: 101–108.

22.

Zhang

Tang

, et al. Active corrosion protection by a smart coating based on a MgAl-layered double hydroxide on a cerium-modified plasma electrolytic oxidation coating on Mg alloy AZ31. Corros Sci 2018; 139: 370–382.

23.

Chen

Fang

, et al. Corrosion resistance of a self-healing rose-like MgAl-LDH coating intercalated with aspartic acid on AZ31 Mg alloy. Prog Org Coat 2019; 136: 225–234.

24.

Zhang

Luo

Pan

, et al. Self-healing Li-Al layered double hydroxide conversion coating modified with aspartic acid for 6N01 Al alloy. Appl Surf Sci 2017; 394: 275–281.

25.

Zhang

Yin

Liu

, et al. Doubly doped Mg-Al-V₂O₇⁴⁻ layered double hydroxide/Mo₂CT_x MXene nanosheet composites for wear and corrosion-resistant coatings. ACS Appl Nano Mater 2023; 6: 14308–14321.

26.

Phillips

Vandeperre

. Anion capture with calcium, aluminium and iron containing layered double hydroxides. J Nucl Mater 2011; 416: 225–229.

27.

Guo

Zhang

, et al. Preparation of layered double hydroxide films with different orientations on the opposite sides of a glass substrate by in situ hydrothermal crystallization. Chem Commun 2009; 44: 6836–6838.

28.

Anjum

Zhao

Asl

, et al. In-situ intercalation of 8-hydroxyquinoline in Mg-Al LDH coating to improve the corrosion resistance of AZ31. Corros Sci 2019; 157: 1–10.