Near-zero-wear with super-hard WB4 and a self-repairing tribo-chemical layer

Guixin Hou; Shengyu Zhu; Hui Tan; Wenyuan Chen; Jiao Chen; Qichun Sun; Juanjuan Chen; Jun Cheng; Peixuan Li; William Yi Wang; Jun Yang; Weimin Liu

doi:10.1038/s43246-024-00667-1

Near-zero-wear with super-hard WB₄ and a self-repairing tribo-chemical layer

Guixin Hou, Shengyu Zhu, Hui Tan, Wenyuan Chen, Jiao Chen, Qichun Sun, Juanjuan Chen, Jun Cheng, Peixuan Li, William Yi Wang, Jun Yang, Weimin Liu

School of Materials Sience and Engineering

Research output: Contribution to journal › Article › peer-review

2 Scopus citations

Abstract

Achieving near-zero-wear remains a major challenge in mechanical engineering and material science. Current ultra-low wear materials are typically developed based on the self-consumption strategy. Here, we demonstrate a new self-repairing approach to achieve near-zero-wear. We find that the WB₄-βB/WC tribo-pair has a low wear rate of 10⁻⁸ mm³ N⁻¹ m⁻¹ in low vacuum conditions, under a maximum Hertzian contact stress of 2.23 GPa over 1 × 10⁵ friction cycles. Additionally, we observe an abnormal wear phenomenon after 5 × 10⁴ friction cycles, characterized by an increase in the dimensions of the tribo-pair. This near-zero-wear mechanism is attributed to the synergistic action of the super-hard WB₄-βB substrate and the self-repairing tribo-oxide layer. This research provides a new approach for advancing wear-resistant materials and enhancing material longevity.

Original language	English
Article number	222
Journal	Communications Materials
Volume	5
Issue number	1
DOIs	https://doi.org/10.1038/s43246-024-00667-1
State	Published - Dec 2024

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title = "Near-zero-wear with super-hard WB4 and a self-repairing tribo-chemical layer",

abstract = "Achieving near-zero-wear remains a major challenge in mechanical engineering and material science. Current ultra-low wear materials are typically developed based on the self-consumption strategy. Here, we demonstrate a new self-repairing approach to achieve near-zero-wear. We find that the WB4-βB/WC tribo-pair has a low wear rate of 10−8 mm3 N−1 m−1 in low vacuum conditions, under a maximum Hertzian contact stress of 2.23 GPa over 1 × 105 friction cycles. Additionally, we observe an abnormal wear phenomenon after 5 × 104 friction cycles, characterized by an increase in the dimensions of the tribo-pair. This near-zero-wear mechanism is attributed to the synergistic action of the super-hard WB4-βB substrate and the self-repairing tribo-oxide layer. This research provides a new approach for advancing wear-resistant materials and enhancing material longevity.",

author = "Guixin Hou and Shengyu Zhu and Hui Tan and Wenyuan Chen and Jiao Chen and Qichun Sun and Juanjuan Chen and Jun Cheng and Peixuan Li and Wang, {William Yi} and Jun Yang and Weimin Liu",

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doi = "10.1038/s43246-024-00667-1",

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T1 - Near-zero-wear with super-hard WB4 and a self-repairing tribo-chemical layer

AU - Hou, Guixin

AU - Zhu, Shengyu

AU - Tan, Hui

AU - Chen, Wenyuan

AU - Chen, Jiao

AU - Sun, Qichun

AU - Chen, Juanjuan

AU - Cheng, Jun

AU - Li, Peixuan

AU - Wang, William Yi

AU - Yang, Jun

AU - Liu, Weimin

PY - 2024/12

Y1 - 2024/12

N2 - Achieving near-zero-wear remains a major challenge in mechanical engineering and material science. Current ultra-low wear materials are typically developed based on the self-consumption strategy. Here, we demonstrate a new self-repairing approach to achieve near-zero-wear. We find that the WB4-βB/WC tribo-pair has a low wear rate of 10−8 mm3 N−1 m−1 in low vacuum conditions, under a maximum Hertzian contact stress of 2.23 GPa over 1 × 105 friction cycles. Additionally, we observe an abnormal wear phenomenon after 5 × 104 friction cycles, characterized by an increase in the dimensions of the tribo-pair. This near-zero-wear mechanism is attributed to the synergistic action of the super-hard WB4-βB substrate and the self-repairing tribo-oxide layer. This research provides a new approach for advancing wear-resistant materials and enhancing material longevity.

AB - Achieving near-zero-wear remains a major challenge in mechanical engineering and material science. Current ultra-low wear materials are typically developed based on the self-consumption strategy. Here, we demonstrate a new self-repairing approach to achieve near-zero-wear. We find that the WB4-βB/WC tribo-pair has a low wear rate of 10−8 mm3 N−1 m−1 in low vacuum conditions, under a maximum Hertzian contact stress of 2.23 GPa over 1 × 105 friction cycles. Additionally, we observe an abnormal wear phenomenon after 5 × 104 friction cycles, characterized by an increase in the dimensions of the tribo-pair. This near-zero-wear mechanism is attributed to the synergistic action of the super-hard WB4-βB substrate and the self-repairing tribo-oxide layer. This research provides a new approach for advancing wear-resistant materials and enhancing material longevity.

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SN - 2662-4443

VL - 5

JO - Communications Materials

JF - Communications Materials

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M1 - 222

ER -

Near-zero-wear with super-hard WB₄ and a self-repairing tribo-chemical layer

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