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Al2O3/Al hybrid nanolaminates with superior toughness, strength and ductility

Author

Listed:
  • Paul Baral

    (Centre SMS
    UCLouvain)

  • Sahar Jaddi

    (UCLouvain)

  • Hui Wang

    (UCLouvain)

  • Andrey Orekhov

    (University of Antwerp)

  • Nicolas Gauquelin

    (University of Antwerp)

  • Alireza Bagherpour

    (University of Namur)

  • Frederik Loock

    (Groene Loper)

  • Michaël Coulombier

    (UCLouvain)

  • Audrey Favache

    (UCLouvain)

  • Morgan Rusinowicz

    (Centre SMS
    UCLouvain)

  • Johan Verbeeck

    (University of Antwerp)

  • Stéphane Lucas

    (University of Namur)

  • Jean-Pierre Raskin

    (UCLouvain)

  • Hosni Idrissi

    (UCLouvain)

  • Thomas Pardoen

    (UCLouvain
    WEL Research Institute)

Abstract

Amorphous alumina is hard but brittle like all ceramic type materials which affects durability under impact or scratch. Here we show that alumina layers below 100 nm thickness when stacked with aluminum interlayers exhibit exceptional performances including toughness equal to 300 J.m−2 determined by on chip nanomechanics. This is almost two orders of magnitude higher than bulk alumina and higher than any other thin hard coatings. In addition, a hardness above 8 GPa combines with a fracture strain above 5%. The origin of this superior set of properties is unravelled via in-situ TEM and mechanical models. The combination of constrained alumina layers with ductile behavior, strong “accommodating” interfaces, giant shear deformability of Al layers, and plasticity-controlled crack shielding cooperate to stabilize deformation, dissipate energy and arrest cracks. These performances unlock several options of applications of Al2O3 in which brittleness under contacts prevents benefiting from remarkable functional properties and chemical stability.

Suggested Citation

  • Paul Baral & Sahar Jaddi & Hui Wang & Andrey Orekhov & Nicolas Gauquelin & Alireza Bagherpour & Frederik Loock & Michaël Coulombier & Audrey Favache & Morgan Rusinowicz & Johan Verbeeck & Stéphane Luc, 2025. "Al2O3/Al hybrid nanolaminates with superior toughness, strength and ductility," Nature Communications, Nature, vol. 16(1), pages 1-9, December.
    • Handle: RePEc:nat:natcom:v:16:y:2025:i:1:d:10.1038_s41467-025-56512-7
    DOI: 10.1038/s41467-025-56512-7
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    References listed on IDEAS

    as
    1. Vahid Samaee & Maxime Dupraz & Thomas Pardoen & Helena Swygenhoven & Dominique Schryvers & Hosni Idrissi, 2021. "Deciphering the interactions between single arm dislocation sources and coherent twin boundary in nickel bi-crystal," Nature Communications, Nature, vol. 12(1), pages 1-8, December.
    2. Yinmin Wang & Mingwei Chen & Fenghua Zhou & En Ma, 2002. "High tensile ductility in a nanostructured metal," Nature, Nature, vol. 419(6910), pages 912-915, October.
    3. Kun Zheng & Chengcai Wang & Yong-Qiang Cheng & Yonghai Yue & Xiaodong Han & Ze Zhang & Zhiwei Shan & Scott X Mao & Miaomiao Ye & Yadong Yin & Evan Ma, 2010. "Electron-beam-assisted superplastic shaping of nanoscale amorphous silica," Nature Communications, Nature, vol. 1(1), pages 1-8, December.
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