A nanoscale shape memory oxide
Copyright policy )A nanoscale shape memory oxide
Stimulus-responsive shape memory materials have attracted tremendous research interests recently, with much effort focused on improving their mechanical actuation. Driven by the needs of nanoelectromechnical devices, materials with large mechanical strain particularly at nanoscale are therefore desired. Here we report on the discovery of a large shape memory effect in BiFeO3 at the nanoscale. A maximum strain of up to ~14% and a large volumetric work density can be achieved in association with a martensitic-like phase transformation. With a single step, control of the phase transformation by thermal activation or electric field has been reversibly achieved without the assistance of external recovery stress. Although aspects such as hysteresis, micro-cracking etc. have to be taken into consideration for real devices, the large shape memory effect in this oxide surpasses most alloys and therefore demonstrates itself as an extraordinary material for potential use in state-of-art nano-systems.
Accepted by Nature Communications
- University of Science and Technology of China China (People's Republic of)
- Beijing Normal University China (People's Republic of)
- UNSW Sydney Australia
- University of Antwerp Belgium
- Lawrence Berkeley National Laboratory United States
anzsrc-for: 4016 Materials Engineering, Condensed Matter - Materials Science, 34 Chemical Sciences, 610, Materials Science (cond-mat.mtrl-sci), FOS: Physical sciences, Bioengineering, 540, 4016 Materials Engineering, anzsrc-for: 34 Chemical Sciences, anzsrc-for: 40 Engineering, 40 Engineering
anzsrc-for: 4016 Materials Engineering, Condensed Matter - Materials Science, 34 Chemical Sciences, 610, Materials Science (cond-mat.mtrl-sci), FOS: Physical sciences, Bioengineering, 540, 4016 Materials Engineering, anzsrc-for: 34 Chemical Sciences, anzsrc-for: 40 Engineering, 40 Engineering
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