TY - JOUR
T1 - Colossal Strain Tuning of Ferroelectric Transitions in KNbO3 Thin Films
AU - Hazra, Sankalpa
AU - Schwaigert, Tobias
AU - Ross, Aiden
AU - Lu, Haidong
AU - Saha, Utkarsh
AU - Trinquet, Victor
AU - Akkopru-Akgun, Betul
AU - Gregory, Benjamin Z.
AU - Mangu, Anudeep
AU - Sarker, Suchismita
AU - Kuznetsova, Tatiana
AU - Sarker, Saugata
AU - Li, Xin
AU - Barone, Matthew R.
AU - Xu, Xiaoshan
AU - Freeland, John W.
AU - Engel-Herbert, Roman
AU - Lindenberg, Aaron M.
AU - Singer, Andrej
AU - Trolier-McKinstry, Susan
AU - Muller, David A.
AU - Rignanese, Gian Marco
AU - Salmani-Rezaie, Salva
AU - Stoica, Vladimir A.
AU - Gruverman, Alexei
AU - Chen, Long Qing
AU - Schlom, Darrell G.
AU - Gopalan, Venkatraman
N1 - Publisher Copyright:
© 2024 The Author(s). Advanced Materials published by Wiley-VCH GmbH.
PY - 2024/12/27
Y1 - 2024/12/27
N2 - Strong coupling between polarization (P) and strain (ɛ) in ferroelectric complex oxides offers unique opportunities to dramatically tune their properties. Here colossal strain tuning of ferroelectricity in epitaxial KNbO3 thin films grown by sub-oxide molecular beam epitaxy is demonstrated. While bulk KNbO3 exhibits three ferroelectric transitions and a Curie temperature (Tc) of ≈676 K, phase-field modeling predicts that a biaxial strain of as little as −0.6% pushes its Tc > 975 K, its decomposition temperature in air, and for −1.4% strain, to Tc > 1325 K, its melting point. Furthermore, a strain of −1.5% can stabilize a single phase throughout the entire temperature range of its stability. A combination of temperature-dependent second harmonic generation measurements, synchrotron-based X-ray reciprocal space mapping, ferroelectric measurements, and transmission electron microscopy reveal a single tetragonal phase from 10 K to 975 K, an enhancement of ≈46% in the tetragonal phase remanent polarization (Pr), and a ≈200% enhancement in its optical second harmonic generation coefficients over bulk values. These properties in a lead-free system, but with properties comparable or superior to lead-based systems, make it an attractive candidate for applications ranging from high-temperature ferroelectric memory to cryogenic temperature quantum computing.
AB - Strong coupling between polarization (P) and strain (ɛ) in ferroelectric complex oxides offers unique opportunities to dramatically tune their properties. Here colossal strain tuning of ferroelectricity in epitaxial KNbO3 thin films grown by sub-oxide molecular beam epitaxy is demonstrated. While bulk KNbO3 exhibits three ferroelectric transitions and a Curie temperature (Tc) of ≈676 K, phase-field modeling predicts that a biaxial strain of as little as −0.6% pushes its Tc > 975 K, its decomposition temperature in air, and for −1.4% strain, to Tc > 1325 K, its melting point. Furthermore, a strain of −1.5% can stabilize a single phase throughout the entire temperature range of its stability. A combination of temperature-dependent second harmonic generation measurements, synchrotron-based X-ray reciprocal space mapping, ferroelectric measurements, and transmission electron microscopy reveal a single tetragonal phase from 10 K to 975 K, an enhancement of ≈46% in the tetragonal phase remanent polarization (Pr), and a ≈200% enhancement in its optical second harmonic generation coefficients over bulk values. These properties in a lead-free system, but with properties comparable or superior to lead-based systems, make it an attractive candidate for applications ranging from high-temperature ferroelectric memory to cryogenic temperature quantum computing.
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U2 - 10.1002/adma.202408664
DO - 10.1002/adma.202408664
M3 - Article
C2 - 39533481
AN - SCOPUS:85208798798
SN - 0935-9648
VL - 36
JO - Advanced Materials
JF - Advanced Materials
IS - 52
M1 - 2408664
ER -