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Autonomous healing of fatigue cracks via cold welding

Author

Listed:
  • Christopher M. Barr

    (Sandia National Laboratories
    Sandia National Laboratories)

  • Ta Duong

    (Texas A&M University)

  • Daniel C. Bufford

    (Sandia National Laboratories)

  • Zachary Milne

    (Sandia National Laboratories
    Sandia National Laboratories)

  • Abhilash Molkeri

    (Texas A&M University)

  • Nathan M. Heckman

    (Sandia National Laboratories
    Sandia National Laboratories)

  • David P. Adams

    (Sandia National Laboratories)

  • Ankit Srivastava

    (Texas A&M University)

  • Khalid Hattar

    (Sandia National Laboratories
    Sandia National Laboratories
    University of Tennessee)

  • Michael J. Demkowicz

    (Texas A&M University)

  • Brad L. Boyce

    (Sandia National Laboratories
    Sandia National Laboratories)

Abstract

Fatigue in metals involves gradual failure through incremental propagation of cracks under repetitive mechanical load. In structural applications, fatigue accounts for up to 90% of in-service failure1,2. Prevention of fatigue relies on implementation of large safety factors and inefficient overdesign3. In traditional metallurgical design for fatigue resistance, microstructures are developed to either arrest or slow the progression of cracks. Crack growth is assumed to be irreversible. By contrast, in other material classes, there is a compelling alternative based on latent healing mechanisms and damage reversal4–9. Here, we report that fatigue cracks in pure metals can undergo intrinsic self-healing. We directly observe the early progression of nanoscale fatigue cracks, and as expected, the cracks advance, deflect and arrest at local microstructural barriers. However, unexpectedly, cracks were also observed to heal by a process that can be described as crack flank cold welding induced by a combination of local stress state and grain boundary migration. The premise that fatigue cracks can autonomously heal in metals through local interaction with microstructural features challenges the most fundamental theories on how engineers design and evaluate fatigue life in structural materials. We discuss the implications for fatigue in a variety of service environments.

Suggested Citation

  • Christopher M. Barr & Ta Duong & Daniel C. Bufford & Zachary Milne & Abhilash Molkeri & Nathan M. Heckman & David P. Adams & Ankit Srivastava & Khalid Hattar & Michael J. Demkowicz & Brad L. Boyce, 2023. "Autonomous healing of fatigue cracks via cold welding," Nature, Nature, vol. 620(7974), pages 552-556, August.
    • Handle: RePEc:nat:nature:v:620:y:2023:i:7974:d:10.1038_s41586-023-06223-0
    DOI: 10.1038/s41586-023-06223-0
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    Cited by:

    1. Saikat Mondal & Pratap Tanari & Samrat Roy & Surojit Bhunia & Rituparno Chowdhury & Arun K. Pal & Ayan Datta & Bipul Pal & C. Malla Reddy, 2023. "Autonomous self-healing organic crystals for nonlinear optics," Nature Communications, Nature, vol. 14(1), pages 1-12, December.

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