Litcius/Paper detail

Ultrahigh electromechanical response from competing ferroic orders

Baichen Lin, Khuong P. Ong, Tiannan Yang, Qibin Zeng, Hui Kim Hui, Zhen Ye, Celine Sim, Zhihao Yen, Ping Yang, Yanxin Dou, Xiaolong Li, Xingyu Gao, Chee Kiang Ivan Tan, Zhi Shiuh Lim, Shengwei Zeng, T. Luo, Jinlong Xu, Xin Tong, Patrick Wen Feng Li, Minqin Ren, Kaiyang Zeng, Chengliang Sun, Seeram Ramakrishna, Mark B. H. Breese, Chris Boothroyd, Chengkuo Lee, David J. Singh, Yeng Ming Lam, Huajun Liu

2024Nature54 citationsDOIOpen Access PDF

Abstract

Abstract Materials with electromechanical coupling are essential for transducers and acoustic devices as reversible converters between mechanical and electrical energy 1–6 . High electromechanical responses are typically found in materials with strong structural instabilities, conventionally achieved by two strategies—morphotropic phase boundaries 7 and nanoscale structural heterogeneity 8 . Here we demonstrate a different strategy to accomplish ultrahigh electromechanical response by inducing extreme structural instability from competing antiferroelectric and ferroelectric orders. Guided by the phase diagram and theoretical calculations, we designed the coexistence of antiferroelectric orthorhombic and ferroelectric rhombohedral phases in sodium niobate thin films. These films show effective piezoelectric coefficients above 5,000 pm V −1 because of electric-field-induced antiferroelectric–ferroelectric phase transitions. Our results provide a general approach to design and exploit antiferroelectric materials for electromechanical devices.

Topics & Concepts

AntiferroelectricityPiezoelectricityFerroelectricityMaterials scienceCondensed matter physicsPhase diagramOrthorhombic crystal systemPhase (matter)Nanoscopic scaleElectric fieldInstabilityOptoelectronicsDielectricDiffractionNanotechnologyComposite materialOpticsPhysicsQuantum mechanicsMechanicsFerroelectric and Piezoelectric MaterialsMultiferroics and related materialsAcoustic Wave Resonator Technologies