Dispersion hardening using amorphous nanoparticles deployed via additive manufacturing

Wang, Ge; Zhang, Yin; Liu, Jian; Chen, Wen; Wang, Kang; Cui, Bo; Zou, Bingkun; Ouyang, Qiubao; Zhang, Yanming; Hu, Zhaoyang; Wang, Lu; Yan, Wentao; Jin, Shenbao; Ding, Jun; Wang, Y. Morris; Zhu, Ting; Li, Zan; Zhang, Di; Ma, Evan

Dispersion hardening using amorphous nanoparticles deployed via additive manufacturing

Ge Wang, Yin Zhang, Jian Liu, Wen Chen, Kang Wang, Bo Cui, Bingkun Zou, Qiubao Ouyang, Yanming Zhang, Zhaoyang Hu, Lu Wang, Wentao Yan, Shenbao Jin, Jun Ding, Y. Morris Wang, Ting Zhu, Zan Li (), Di Zhang () and Evan Ma ()
Additional contact information
Ge Wang: Shanghai Jiao Tong University
Yin Zhang: Peking University
Jian Liu: University of Massachusetts
Wen Chen: University of Massachusetts
Kang Wang: Shanghai Jiao Tong University
Bo Cui: Shanghai Jiao Tong University
Bingkun Zou: Shanghai Jiao Tong University
Qiubao Ouyang: Shanghai Jiao Tong University
Yanming Zhang: National University of Singapore
Zhaoyang Hu: National University of Singapore
Lu Wang: National University of Singapore
Wentao Yan: National University of Singapore
Shenbao Jin: Hebei University of Technology
Jun Ding: Xi’an Jiaotong University
Y. Morris Wang: University of California
Ting Zhu: Georgia Institute of Technology
Zan Li: Shanghai Jiao Tong University
Di Zhang: Shanghai Jiao Tong University
Evan Ma: Xi’an Jiaotong University

Nature Communications, 2025, vol. 16, issue 1, 1-13

Abstract: Abstract Nanoparticles or precipitates are long used to block dislocations to strengthen metals. However, this strengthening mechanism unavoidably adds stress concentrations at the obstacles, instigating crack initiation that hampers ductility. Here, we demonstrate a strategy that replaces the traditional crystalline dispersions with dense amorphous nanoparticles, which is made possible via laser powder bed fusion. Porosity-free copper-based nanocomposites are demonstrated as a prototype, consisting of densely and uniformly distributed amorphous boron–carbide nanoparticles (~47 nm in average diameter, up to 12% volume fraction) via an in situ nanofragmentation and melt-quench process. The amorphous nanoparticles act as dislocation sinks, thereby alleviating local stress concentration. They also self-harden along with tensile deformation, promoting strain hardening and therefore homogeneous plastic flow. The as-built composite achieves a tensile strength of more than one gigapascal and a total elongation of approximately 10%, more than twice that of its crystalline dispersion counterpart. Defect accumulation is also suppressed upon cyclic deformation of the as-built bulk nanocomposites, delivering a fatigue strength limit (at > 107 cycles) of more than 70% of the tensile strength. Our results demonstrate an effective strategy for additive manufacturing of metallic materials with superior properties.

Date: 2025
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DOI: 10.1038/s41467-025-58893-1

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