Suppressed Size Effect in Nanopillars with Hierarchical Microstructures Enabled by Nanoscale Additive Manufacturing
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1.
California Institute of Technology
Abstract
Studies on mechanical size effects in nanosized metals unanimously highlight both intrinsic microstructures and extrinsic dimensions for understanding size-dependent properties, commonly focusing on strengths of uniform microstructures, e.g., single-crystalline/nanocrystalline and nanoporous, as a function of pillar diameters, D. We developed a hydrogel infusion-based additive manufacturing (AM) technique using two-photon lithography to produce metals in prescribed 3D-shapes with ∼100 nm feature resolution. We demonstrate hierarchical microstructures of as-AM-fabricated Ni nanopillars (D ∼ 130–330 nm) to be nanoporous and nanocrystalline, with d ∼ 30–50 nm nanograins subtending each ligament in bamboo-like arrangements and pores with critical dimensions comparable to d. In situ nanocompression experiments unveil their yield strengths, σ, to be ∼1–3 GPa, above single-crystalline/nanocrystalline counterparts in the D range, a weak size dependence, σ ∝ D^(–0.2), and localized-to-homogenized transition in deformation modes mediated by nanoporosity, uncovered by molecular dynamics simulations. This work highlights hierarchical microstructures on mechanical response in nanosized metals and suggests small-scale engineering opportunities through AM-enabled microstructures.
Copyright and License
© 2023 American Chemical Society.
Acknowledgement
J.R.G. gratefully acknowledges the financial support from the U.S. Department of Energy, Office of Science, Basic Energy Sciences (Grant DE-SC0016945) and the critical infrastructure of the Kavli Nanoscience Institute at Caltech. T.T.T. acknowledges the National Science Foundation Graduate Research Fellowship (Grant DGE-1745301). H.G. acknowledges a research start-up grant (Grant 002479-00001) from Nanyang Technological University and the Agency for Science, Technology and Research (A*STAR). The authors acknowledge the assistance from Dr. Mingjie Xu and Dr. Toshihiro Aoki as well as the use of facilities and instrumentation at the UC Irvine Materials Research Institute (IMRI), which is supported in part by the National Science Foundation through the UC Irvine Materials Research Science and Engineering Center (Grant DMR-2011967). This research used computational resources of the supercomputer Fugaku provided by the RIKEN Center for Computational Science (Project hp220157).
Contributions
W.Z. and Z.L. contributed equally to this work. W.Z., Z.L., R.A.G., H.G., and J.R.G. contributed to conceptualization and methodology design. W.Z. and Z.L. performed the investigation, analyzed the data, and wrote the manuscript. R.D., T.T.T., and R.A.G. contributed to data analysis and edited the manuscript. H.G. and J.R.G. supervised the study and edited the manuscript. W.Z., Z.L., and R.A.G. revised the manuscript.
Conflict of Interest
The authors declare no competing financial interest.
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Additional details
- ISSN
- 1530-6992
- United States Department of Energy
- DE-SC0016945
- National Science Foundation
- DGE-1745301
- Nanyang Technological University
- 002479-00001
- Agency for Science, Technology and Research
- National Science Foundation
- DMR-2011967
- RIKEN Center for Computational Science
- hp220157
- Caltech groups
- Kavli Nanoscience Institute