Nanomaterials by severe plastic deformation: review of historical developments and recent advances
Research output: Contribution to journal › Review article › peer-review
Authors
Organisational units
External Organisational units
- Kyushu University
- Erich Schmid Institute of Materials Science
- National Academy of Sciences of Ukraine
- Technological Institute for Superhard and Novel Carbon Materials
- Federal University of São Carlos
- Faculty of Mechanical Engineering
- Charles University
- Westfälische Wilhelms-Universität Münster
- Ufa State Aviation Technical University
- Department of Mechanical Engineering
- Monash University
- University of Tehran
- Department of Metallurgical and Materials Engineering
- Nagoya Institute of Technology
- Toyota Central R&D Laboratories Inc
- Eötvös University Budapest
- Kumamoto University, Japan
- Saga University
- Université du Québec à Trois-Rivières
- Oregon State University
- Institute of Physics of Materials of the Academy of Sciences of the Czech Republic
- Ibaraki University
- University of Southampton
- Department of Mechanical and Industrial Engineering
- Institute of Solid State Physics
- Karlsruhe Institute of Technology, Campus North
- Department of Mechanical Engineering
- Department of Electrical Engineering
- Institute of Geology and Geochemistry Ural Division of Russian Academy of Sciences
- Department of Mechanical Engineering
- Normandie University
- TU Dresden
- Indian Institute of Science
- MTA-ME Materials Science Research Group
- Department of Materials Science and Engineering
- Universität Wien
- Kunming University of Science and Technology
- Université de Lorraine, Metz
- Departamento de Engenharia de Materiais
- Kyushu Institute of Technology
- University Nancy, CNRS, CREGU
- Saint-Petersburg State University
Abstract
Severe plastic deformation (SPD) is effective in producing bulk ultrafine-grained and nanostructured materials with large densities of lattice defects. This field, also known as NanoSPD, experienced a significant progress within the past two decades. Beside classic SPD methods such as high-pressure torsion, equal-channel angular pressing, accumulative roll-bonding, twist extrusion, and multi-directional forging, various continuous techniques were introduced to produce upscaled samples. Moreover, numerous alloys, glasses, semiconductors, ceramics, polymers, and their composites were processed. The SPD methods were used to synthesize new materials or to stabilize metastable phases with advanced mechanical and functional properties. High strength combined with high ductility, low/room-temperature superplasticity, creep resistance, hydrogen storage, photocatalytic hydrogen production, photocatalytic CO2 conversion, superconductivity, thermoelectric performance, radiation resistance, corrosion resistance, and biocompatibility are some highlighted properties of SPD-processed materials. This article reviews recent advances in the NanoSPD field and provides a brief history regarding its progress from the ancient times to modernity. Abbreviations: ARB: Accumulative Roll-Bonding; BCC: Body-Centered Cubic; DAC: Diamond Anvil Cell; EBSD: Electron Backscatter Diffraction; ECAP: Equal-Channel Angular Pressing (Extrusion); FCC: Face-Centered Cubic; FEM: Finite Element Method; FSP: Friction Stir Processing; HCP: Hexagonal Close-Packed; HPT: High-Pressure Torsion; HPTT: High-Pressure Tube Twisting; MDF: Multi-Directional (-Axial) Forging; NanoSPD: Nanomaterials by Severe Plastic Deformation; SDAC: Shear (Rotational) Diamond Anvil Cell; SEM: Scanning Electron Microscopy; SMAT: Surface Mechanical Attrition Treatment; SPD: Severe Plastic Deformation; TE: Twist Extrusion; TEM: Transmission Electron Microscopy; UFG: Ultrafine Grained.
Details
Original language | English |
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Pages (from-to) | 163-256 |
Number of pages | 94 |
Journal | Materials Research Letters |
Volume | 10.2022 |
Issue number | 4 |
DOIs | |
Publication status | E-pub ahead of print - 17 Feb 2022 |