Highly reversible extrinsic electrocaloric effects over a wide temperature range in epitaxially strained SrTiO3 films.

Electrocaloric effects have been experimentally studied in ferroelectrics and incipient ferroelectrics, but not incipient ferroelectrics driven ferroelectric using strain. Here we use optimally oriented interdigitated surface electrodes to investigate extrinsic electrocaloric effects in low-loss epitaxial SrTiO3 films near the broad second-order 243 K ferroelectric phase transition created by biaxial in-plane coherent tensile strain from DyScO3 substrates. Our extrinsic electrocaloric effects are an order of magnitude larger than the corresponding effects in bulk SrTiO3 over a wide range of temperatures including room temperature, and unlike electrocaloric effects associated with first-order transitions they are highly reversible in unipolar applied fields. Additionally, the canonical Landau description for strained SrTiO3 films works well if we set the low-temperature zero-field polarization along one of the in-plane pseudocubic <100> directions. In future, similar strain engineering could be exploited for other films, multilayers and bulk samples to increase the range of electrocaloric materials for energy efficient cooling.

Description

Acknowledgements: S.Z. acknowledges financial support from the China Scholarship Council (CSC) programme and the National Natural Science Foundation of China (grant no. 12074429). G.G.G.-V. is grateful for support from the Vice-Rectory for Research (project nos B9194 and C1601) and the Office of International Affairs at the University of Costa Rica, and Churchill College at the University of Cambridge. X.M. acknowledges funding from the UK Engineering and Physical Sciences Research Council (grant no. EP/M003752/1), an ERC Starting Grant (no. 680032) and the Royal Society. X.M. and G.G.G.-V. are grateful for support from the Royal Society International Exchanges programme (IES\R3\170025). S.D. acknowledges the National Natural Science Foundation of China (grant no. 22001014) and the China National Postdoctoral Program for Innovative Talents (grant no. BX20200043). Q.J. is grateful for financial support through a Marie Skłodowska-Curie Fellowship (no. H2020-MSCA-IF-2015-702868). We thank S. X. Hu for help with XRD measurements; N. Stelmashenko for help with AFM measurements; S. Kar-Narayan, R. Raninga, C. L. Ou and C. Yun for their contribution to electrode preparation; and S. Kar-Narayan for scanning electron microscope use. We thank S. Hirose, S. Trolier-McKinstry, Y. L. Liu, D. Zhang, J. H. Qiu, R. Wu, W. W. Li, Y. S. Lin, S. S. Saxena, T. Wei, L. E. Hueso, G. Aeppli and P. Zubko for discussions. The transmission electron microscopy study was performed at the National Center for Electron Microscopy in Beijing.

Keywords

5108 Quantum Physics, 34 Chemical Sciences, 40 Engineering, 51 Physical Sciences, 4016 Materials Engineering

Journal Title

Nat Mater

Journal ISSN

1476-1122
1476-4660

Volume Title

23

Publisher

Springer Science and Business Media LLC

Publisher DOI

https://doi.org/10.1038/s41563-024-01831-1

Rights and licensing

Except where otherwised noted, this item's license is described as Attribution 4.0 International

Sponsorship

European Research Council (680032)
Royal Society (URF\R\180035)
The Royal Society (uf120210)
Engineering and Physical Sciences Research Council (EP/M003752/1)
Royal Society (RGF\EA\180293)

Royal Society, ERC.

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