[1] T ZHENG, J G WU, D Q XIAO et al. Recent development in lead-free perovskite piezoelectric bulk materials. Progress in Materials Science(2018).
[2] Z Y ZHOU, T CHEN, X L DONG. Research progress of perovskite layer structured piezoelectric ceramics with super high Curie temperature. Journal of Inorganic Materials(2018).
[3] X N JIANG, K KIM, S J ZHANG et al. High-temperature piezoelectric sensing. Sensors(2013).
[4] F Q ZHANG, Y X LI. Recent progress on bismuth layer-structured ferroelectrics. Journal of Inorganic Materials(2014).
[6] X C XIE, Z Y ZHOU, R H LIANG et al. Superior piezoelectricity in bismuth titanate-based lead-free high-temperature piezoceramics
[7] E C SUBBARAO. A family of ferroelectric bismuth compounds. Journal of Physics and Chemistry of Solids(1962).
[8] Y SHIMAKAWA, Y KUBO, Y NAKAGAWA et al. Crystal structure and ferroelectric properties of ABi2Ta2O9(A=Ca, Sr, and Ba). Physical Review B(2000).
[9] C B LONG, B WANG, W REN et al. Significantly enhanced electrical properties in CaBi2Nb2O9-based high-temperature piezoelectric ceramics. Applied Physics Letters(2020).
[10] H X YAN, H T ZHANG, R UBIC et al. A lead-free high-curie-point ferroelectric ceramic, CaBi2Nb2O9. Advanced Materials(2005).
[11] H CHEN, J ZHAI. Enhancing piezoelectric performance of CaBi2Nb2O9 ceramics through microstructure control. Journal of Electronic Materials(2012).
[12] Y G LI, Z Y ZHOU, R H LIANG et al. A simple Bi3+ self-doping strategy constructing pseudo-tetragonal phase boundary to enhance electrical properties in CaBi2Nb2O9 high-temperature piezoceramics. Journal of the European Ceramic Society(2022).
[13] Q C HOU, B YANG, C MA et al. Tailoring structure and piezoelectric properties of CaBi2Nb2O9 ceramics by W6+-doping. Ceramics International(2022).
[14] Y J WU, J CHEN, J YUAN et al. Structure refinements and the influences of A-site vacancies on properties of Na0.5Bi2.5Nb2O9- based high temperature piezoceramics. Journal of Applied Physics(2016).
[15] G LIU, D WANG, C WU et al. A realization of excellent piezoelectricity and good thermal stability in CaBi2Nb2O9: pseudo phase boundary. Journal of the American Ceramic Society(2018).
[16] E C SUBBARAO. Ferroelectricity in Bi4Ti3O12 and its solid solutions. Physical Review(1961).
[17] S M BLAKE, M J FALCONER, M MCCREEDY et al. Cation in ferroelectric Aurivillius phases of the type Bi2ANb2O9 (A=Ba, Sr, Ca). Journal of Materials Chemistry(1997).
[18] X XING, F CAO, Z PENG et al. Electrical properties and sintering characteristics of zirconium doped CaBi2Nb2O9 ceramics. Ceramics International(2018).
[19] N ZAKHAROV, V A KLYUEV, Y P TOPOROV. Phase transitions and electric characteristics of ferroelectric Ca2Nb2O7and Sr2Nb2O7. Zhurnal Fizicheskoj Khimii(1999).
[20] X D ZHANG, H X YAN, J R MICHAEL et al. Effect of A site substitution on the properties of CaBi2Nb2O9 ferroelectric ceramics. Journal of the American Ceramic Society(2008).
[21] V A ISUPOV. Two types of ABi2B2O9 layered perovskite-like ferroelectrics. Inorganic Materials(2007).
[22] B FRIT, J P MERCURIO. The crystal chemistry and dielectric properties of the Aurivillius family of complex bismuth oxides with perovskite-like layered structures. Journal of Alloys and Compounds(1992).
[23] X X ZENG, J C YANG, L ZUO et al. Li/Ce/La multidoping on crystal structure and electric properties of CaBi2Nb2O9 piezoceramics. Journal of Inorganic Materials(2019).
[24] J N CHEN, Q WANG, H T LU et al. Enhanced electrical properties and conduction mechanism of A-site rare-earth Nd-substituted CaBi2Nb2O9. Journal of Physics D: Applied Physics(2022).
[25] X H XING, F CAO, Z PENG et al. The effects of oxygen vacancies on the electrical properties of W, Ti doped CaBi2Nb2O9 piezoceramics. Current Applied Physics(2018).
[26] X C XIE, Z Y ZHOU, T CHEN et al. Enhanced electrical properties of NaBi modified CaBi2Nb2O9-based Aurivillius piezoceramics
[27] X P WANG, J G WU, D Q XIAO et al. New potassium-sodium niobate ceramics with a giant
[28] R L WITHERS, J G THOMPSON, A D RAE. The crystal chemistry underlying ferroelectricity in Bi4Ti3O12, Bi3TiNbO9, and Bi2WO6. Journal of Solid State Chemistry(1991).
[29] C QIN, Z Y SHEN, W Q LUO et al. Effect of excess Bi on the structure and electrical properties of CaBi2Nb2O9 ultrahigh temperature piezoceramics. Journal of Materials Science: Materials in Electronics(2018).
[30] A Z SIMÕES, C S RICCARDI, L S CAVALCANTE et al. Impact of oxygen atmosphere on piezoelectric properties of CaBi2Nb2O9 thin films. Acta Materialia(2007).
[31] F LI, S J ZHANG, Z XU et al. The contributions of polar nanoregions to the dielectric and piezoelectric responses in domain-engineered relaxor-PbTiO3 crystals. Advanced Functional Materials(2017).
[32] A PICININ, M H LENTE, J A EIRAS et al. Theoretical and experimental investigations of polarization switching in ferroelectric materials. Physical Review B(2004).