Electrochemical Healing of Fractured Metals

Hsain, Zakaria; Akbari, Mostafa; Prasanna, Adhokshid; Jiang, Zhimin; Akbarzadeh, Masoud

doi:10.1002/adma.202211242

Advanced Materials

2023

DOI: 10.1002/adma.202211242

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Electrochemical Healing of Fractured Metals

Zakaria Hsain

Mostafa Akbari

Adhokshid Prasanna

et al.

Abstract: Repairing fractured metals to extend their useful lifetimes advances sustainability and mitigates carbon emissions from metal mining and processing. While high‐temperature techniques are being used to repair metals, the increasing ubiquity of digital manufacturing and “unweldable” alloys, as well as the integration of metals with polymers and electronics, call for radically different repair approaches. Herein, a framework for effective room‐temperature repair of fractured metals using an area‐selective nickel … Show more

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2024

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Cited by 4 publications

References 47 publications

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Localized Electrochemical Repair (LER) of Conductive Materials

Mahmoudi,

Mehrdad,

Shafieizad

et al. 2024

Adv Eng Mater

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Circular economy models emphasize material repair, akin to nature’s healing processes. However, while polymer healing has garnered attention, repairing metals and metal matrix composites (MMCs) remains less extensively studied. Here, we introduce “Localized Electrochemical Repair (LER),” a process adept at efficiently mending conductive materials. LER involves a nozzle with electrolyte near damage, creating a small electrochemical cell that guides controlled metal ion deposition. Notably, LER’s energy efficiency, as low as 40 J/mm, significantly outperforms other methods. This energy efficiency is one‐fifth of that required for conventional bath‐based electro‐healing methods. Through the successful repair of a copper/alumina (Cu/alumina) MMC that achieved ∽100% strength recovery, we demonstrated the effectiveness of LER and assessed interface properties. LER aligns with circular economy ideals, offering precise, localized healing that is eco‐friendly and economically sound. It restores conductive materials while minimizing energy use and waste.This article is protected by copyright. All rights reserved.

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Localized Electrochemical Repair (LER) of Conductive Materials

Mahmoudi,

Mehrdad,

Shafieizad

et al. 2024

Adv Eng Mater

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Enhanced Plastic Stability: Achieving High Performance in a Al6xxx Alloy Fabricated by Additive Manufacturing

Hu,

Gao,

Mikula

et al. 2024

Advanced Materials

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Additive manufacturing (AM) facilitates the creation of materials with unique microstructural features and distinctive phenomena as compared to conventional manufacturing methods. Among the various well‐fabricated AM alloys, aluminum alloys garner substantial attention due to their extensive applications in the automotive and aerospace industries. In this work, an Al6xxx alloy is successfully fabricated with the outstanding performance. A nucleation agent is introduced to diminish the susceptibility to cracking during the AM process, thereby inducing a heterogeneous microstructure in this alloy. However, the introduction of ultrafine grains induces plastic instability, evidenced by the presence of Lüders band. This work investigates the evolution of the Lüders band and the strategy to reduce their undesirable effect. The heterogeneity destabilizes the band propagation and thus deteriorates the ductility. Through a T6 heat treatment, the local Lüders strain decreases from 10.0% to 6.2%, leading to a substantial enhancement in plastic stability. With the increase in grain growth and the enlargement of coarse grain regions, the mismatch between the local and macroscopic Lüders strain disappears. Importantly, the strength and the thermal conductivity are concurrently increased. The findings demonstrate the significance of ensuring plastic stability to achieve improved strength‐ductility trade‐off in AM alloys with heterogeneous microstructures.This article is protected by copyright. All rights reserved

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General translation of cellular to shellular polyhedral structures using reciprocity

Akbari,

Akbarzadeh

2024

Structures

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Electrochemical Healing of Fractured Metals

Cited by 4 publications

References 47 publications

Localized Electrochemical Repair (LER) of Conductive Materials

Localized Electrochemical Repair (LER) of Conductive Materials

Enhanced Plastic Stability: Achieving High Performance in a Al6xxx Alloy Fabricated by Additive Manufacturing

General translation of cellular to shellular polyhedral structures using reciprocity

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