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The classical-to-quantum crossover in the strain-induced ferroelectric transition in SrTiO3 membranes

Jiarui Li, Yonghun Lee, Yongseong Choi, Jong-Woo Kim, Paul Thompson, Kevin J. Crust, Ruijuan Xu, Harold Y. Hwang (), Philip J. Ryan () and Wei-Sheng Lee ()
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Jiarui Li: SLAC National Accelerator Laboratory
Yonghun Lee: SLAC National Accelerator Laboratory
Yongseong Choi: Argonne National Laboratory
Jong-Woo Kim: Argonne National Laboratory
Paul Thompson: University of Liverpool
Kevin J. Crust: SLAC National Accelerator Laboratory
Ruijuan Xu: North Carolina State University
Harold Y. Hwang: SLAC National Accelerator Laboratory
Philip J. Ryan: Argonne National Laboratory
Wei-Sheng Lee: SLAC National Accelerator Laboratory

Nature Communications, 2025, vol. 16, issue 1, 1-7

Abstract: Abstract Mechanical strain presents an effective control over symmetry-breaking phase transitions. In quantum paraelectric SrTiO3, strain can induce ferroelectric order via modification of the local Ti potential energy landscape. However, brittle bulk materials can only withstand limited strain range (~0.1%). Taking advantage of nanoscopically-thin freestanding membranes, we demonstrate an in-situ strain-induced reversible ferroelectric transition in freestanding SrTiO3 membranes. We measure the ferroelectric order by detecting the local anisotropy of the Ti 3d orbital signature using X-ray linear dichroism at the Ti-K pre-edge, while the strain is determined by X-ray diffraction. With reduced thickness, the SrTiO3 membranes remain elastic with >1% tensile strain cycles. A robust displacive ferroelectricity appears beyond a temperature-dependent critical strain. Interestingly, we discover a crossover from a classical ferroelectric transition to a quantum regime at low temperatures, which enhances strain-induced ferroelectricity. Our results offer new opportunities to strain engineer functional properties in low dimensional quantum materials and provide new insights into the role of ferroelectric fluctuations in quantum paraelectric SrTiO3.

Date: 2025
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DOI: 10.1038/s41467-025-59517-4

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