Abstract
Thin-film solid-state metal dealloying (thin-film SSMD) is a promising method for fabricating nanostructures with controlled morphology and efficiency, offering advantages over conventional bulk materials processing methods for integration into practical applications. Although machine learning (ML) has facilitated the design of dealloying systems, the selection of key thermal treatment parameters for nanostructure formation remains largely unknown and dependent on experimental trial and error. To overcome this challenge, a workflow enabling high-throughput characterization of thermal treatment parameters is demonstrated using a laser-based thermal treatment to create temperature gradients on single thin-film samples of Nb-Al/Sc and Nb-Al/Cu. This continuous thermal space enables observation of dealloying transitions and the resulting nanostructures of interest. Through synchrotron X-ray multimodal and high-throughput characterization, critical transitions and nanostructures can be rapidly captured and subsequently verified using electron microscopy. The key temperatures driving chemical reactions and morphological evolutions are clearly identified. While the oxidation may influence nanostructure formation during thin-film treatment, the dealloying process at the dealloying front involves interactions solely between the dealloying elements, highlighting the availability and viability of the selected systems. This approach enables efficient exploration of the dealloying process and validation of ML predictions, thereby accelerating the discovery of thin-film SSMD systems with targeted nanostructures.
| Original language | English |
|---|---|
| Journal | Small |
| DOIs | |
| State | Accepted/In press - 2025 |
Funding
This work was supported by the National Science Foundation under Grant No. DMR\u20101752839. The authors acknowledge the support provided via the Faculty Early Career Development Program (CAREER) and the Metals and Metallic Nanostructures (MMN) Program of the National Science Foundation. A portion of this work (GMV \u2013 film growth) was supported by the U.S. Department of Energy's Energy Efficiency and Renewable Energy program, Vehicle Technologies Office, as part of the U.S.\u2010Germany Consortium. This research used resources, Beamline for Materials Measurement (BMM, 6\u2010BM) and Complex Materials Scattering Beamline (CMS, 11\u2010BM) of the National Synchrotron Light Source II (NSLS\u2010II), a U.S. Department of Energy (DOE) Office of Science User Facility operated for the DOE Office of Science by Brookhaven National Laboratory (BNL) under Contract No. DE\u2010SC0012704. This research used Electron Microscopy, Nanofabrication, and Materials Synthesis and Characterization Facilities of the Center for Functional Nanomaterials (CFN), which is a U.S. DOE Office of Science Facility, at Brookhaven National Laboratory under Contract No. DE\u2010SC0012704. The authors are grateful to Dr. Bruce Ravel (National Institute of Standards and Technology), Lead Beamline Scientist at the BMM beamline, for his expertise and support on XAS characterization as well as his insights into data analysis and scientific interpretation. C.\u2010C. Chung acknowledges the support of student fellowship from Joint Photon Sciences Institute (JPSI). The authors thank Dr. Pawel W. Majewski (University of Warsaw) for the design and fabrication of the photothermal annealer (PTA).
Keywords
- machine-learning
- metal dealloying
- nanostructure
- synchrotron X-ray
- thin film