Impact of grain boundary segregation on piezoelectric performance of CaBi2Nb2O9 high-temperature piezoceramics

Yangyang Zhou , Yanyan Zhang , Jianfeng Huang , Runlin Liu , Zhengqian Fu , Fangfang Xu , Zhonghui Shen , Ruihong Liang , Zhiyong Zhou

Microstructures ›› 2026, Vol. 6 ›› Issue (2) -2026029.

PDF
Microstructures ›› 2026, Vol. 6 ›› Issue (2) -2026029. DOI: 10.20517/microstructures.2025.101
Research Article
Impact of grain boundary segregation on piezoelectric performance of CaBi2Nb2O9 high-temperature piezoceramics
Author information +
History +
PDF

Abstract

Grain boundary segregation plays a critical role in determining the properties of polycrystalline materials, yet its influence on piezoelectric performance remains underexplored. In this work, bismuth layer-structured piezoceramic W6+-doped CaBi2Nb2O9 (WCBN) was chosen to investigate the effect of grain boundary segregation on the piezoelectric properties through multiscale structural characterization and phase-field simulations. The results reveal that improper grain boundary segregation can induce internal stress fields that restrict domain switching dynamics, leading to deterioration of the piezoelectric response. Therefore, a novel poling process was developed, which effectively alleviated the segregation-induced stress constraints and enhanced the piezoelectric coefficients by 180%. More importantly, optimizing the preparation process significantly enhances the mechanical properties, particularly increasing the fracture toughness of WCBN ceramics to 2.73 MPa m1/2, which is more than twice that of traditional Pb(Zr, Ti)O3 piezoceramics. These findings establish direct correlations between grain boundary segregation, internal stress, and domain switching behavior, providing fundamental insights for the design of piezoelectric materials that integrate both high piezoelectric and mechanical properties, which could be greatly beneficial to long-term stable operation in harsh environments with high temperatures and complex vibrations for bismuth layer-structured piezoceramics.

Keywords

High-temperature piezoelectric ceramics / grain boundary segregation / domain switching / internal stress / fracture toughness

Cite this article

Download citation ▾
Yangyang Zhou, Yanyan Zhang, Jianfeng Huang, Runlin Liu, Zhengqian Fu, Fangfang Xu, Zhonghui Shen, Ruihong Liang, Zhiyong Zhou. Impact of grain boundary segregation on piezoelectric performance of CaBi2Nb2O9 high-temperature piezoceramics. Microstructures, 2026, 6(2): -2026029 DOI:10.20517/microstructures.2025.101

登录浏览全文

4963

注册一个新账户 忘记密码

References

Publishing order | Descend order by publishing year | Descend order by cited within
[1]

Desu SB.Interfacial segregation in perovskites: IV, internal boundary layer devices.J Am Ceram Soc1990;73:3416-21

[2]

Yan MF.Preparation and properties of TiO2 varistors.Appl Phys Lett1982;40:536-7

[3]

Seaton J.Direct measurement of electrical and compositional inhomogeneities in PTC thermistors.J Eur Ceram Soc2004;24:1217-20

[4]

Sepehri-Amin H,Shima T.Grain boundary and interface chemistry of an Nd-Fe-B-based sintered magnet.Acta Mater2012;60:819-30

[5]

Li W,Hono K.Effect of post-sinter annealing on the coercivity and microstructure of Nd-Fe-B permanent magnets.Acta Mater2009;57:1337-46

[6]

Zhang G,Panwisawas C.First-principles study of oxygen segregation and its effect on the embrittlement of molybdenum symmetrical tilt grain boundaries.Acta Mater2023;261:119387

[7]

Kinoshita T.Effect of grain boundary segregation on thermal conductivity of hot-pressed silicon carbide.Acta Mater1997;45:2001-12

[8]

Hu J,Wang L.A new insect-scale piezoelectric robot with asymmetric structure.IEEE Trans Ind Electron2023;70:8194-202

[9]

Yin Y,Xu X.Piezoelectric analgesia blocks cancer-induced bone pain.Adv Mater2024;36:e2403979

[10]

Cao W,Liu Y.Shear stress-triggered theranostic nanoparticles for piezoelectric-fenton-photodynamic thrombolysis and endogenous thrombus imaging.Adv Funct Mater2024;34:2312866

[11]

Zheng T,Xiao D.Recent development in lead-free perovskite piezoelectric bulk materials.Prog Mater Sci2018;98:552-624

[12]

Wei H,Xia Y.An overview of lead-free piezoelectric materials and devices.J Mater Chem C2018;6:12446-67

[13]

Xie S,Chen Q,Wang Q.Realizing super-high piezoelectricity and excellent fatigue resistance in domain-engineered bismuth titanate ferroelectrics.Adv Funct Mater2024;34:2312645

[14]

Li F,Chen Z.Ultrahigh piezoelectricity in ferroelectric ceramics by design.Nat Mater2018;17:349-54

[15]

Song A,Feng T.Simultaneous enhancement of piezoelectricity and temperature stability in KNN-based lead-free ceramics via layered distribution of dopants.Adv Funct Mater2022;32:2204385

[16]

Zou J,Zhou X.Enhancing piezoelectric coefficient and thermal stability in lead-free piezoceramics: insights at the atomic-scale.Nat Commun2024;15:8591 PMCID:PMC11452656
[17]

Xiao W,Liu X.Well-balanced performance achieved in PZT piezoceramics via a multiscale regulation strategy.Mater Horiz2024;11:5285-94

[18]

Zheng M,Ge H,Yan H.Effect of NiO additive on microstructure, mechanical behavior and electrical properties of 0.2PZN-0.8PZT ceramics.J Eur Ceram Soc2013;33:1447-56

[19]

Fang W,Qi H.Synergy ascension of Piezoresponse and curie temperature in bismuth-layered ceramics via defect engineering.Acta Mater2025;293:121108

[20]

Wu J,Zhou D.High-entropy high-temperature high-piezoelectricity ceramics.Adv Mater2025;37:e2419134

[21]

Subbarao EC.Crystal chemistry of mixed bismuth oxides with layer-type structure.J Am Ceram Soc1962;45:166-9

[22]

Li Y,Öchsner P.Temperature dependent fracture toughness of KNN-based lead-free piezoelectric ceramics.Acta Mater2019;174:369-78

[23]

Yilmaz ED,Özcoban H,Schneider GA.Investigation of fracture toughness of modified (KxNa1−x)NbO3 lead-free piezoelectric ceramics.J Eur Ceram Soc2012;32:3339-44

[24]

Xi K,Yu X,Zhu M.Excellent power generation and enhanced mechanical properties in PPT-structured Pb-free piezoceramics with ZrO2 inclusions.J Mater Chem C2022;10:12359-66

[25]

Huang J,Lin J.Enhanced mechanical properties and excellent electrical properties of PZT piezoelectric ceramics modified by YSZ.Mater Lett2022;307:131006

[26]

Zhang Z,Gu W.Significantly toughened PZT-based piezoelectric ceramics simultaneously keeping excellent electrical properties via incorporating trace amount of yttria-partially-stabilized zirconia.Ceram Int2022;48:35614-20

[27]

Wang D,Yuan J.Enhanced piezoelectric and ferroelectric properties of Nb2O5 modified lead zirconate titanate-based composites.J Am Ceram Soc2011;94:647-50

[28]

Chen Y,Xie S.Fracture behaviors and ferroelastic deformation in W/Cr Co-Doped Bi4Ti3O12 ceramics.J Am Ceram Soc2016;99:2103-9

[29]

Jones JL.R-curve and stress-strain behavior of ferroelastic ceramics.J Am Ceram Soc2006;89:3721-7

[30]

Luo X,Yuan X.Piezoelectricity in excess of 30 pC N-1 with a high Curie temperature of 950 °C in strongly textured CaBi2Nb2O9 ceramics.J Mater Chem A2025;13:2121-30

[31]

Long C,Su Z,Liu L.Achieving outstanding comprehensive performance with high piezoelectricity in CaBi2Nb2O9-based high-temperature piezoelectric ceramics via multi-field coupling strategy.J Materiomics2025;11:100990

[32]

Chen N,Yang X.Improved piezoelectric performance in CBN-based ceramic through triple-doping (Li, Bi, Ce) strategy.J Eur Ceram Soc2024;44:116788

[33]

Chen JN,Liu HT.Superior piezoelectric performance in textured CaBi2Nb2O9 ferroelectric ceramics through rare-earth gadolinium doping and spark plasma sintering.ACS Appl Mater Interfaces2024;16:60511-20

[34]

Wang J,Shimada T,Zhang T.Role of grain orientation distribution in the ferroelectric and ferroelastic domain switching of ferroelectric polycrystals.Acta Mater2013;61:6037-49

[35]

Li H,Lin C.Microscopic origin and relevant grain size effect of discontinuous grain growth in BaTiO3-based ferroelectric ceramics.J Mater Sci Technol2023;164:119-28

[36]

Xie X,Gao B,Liang R.Ion-pair engineering-induced high piezoelectricity in Bi4Ti3O12-based high-temperature piezoceramics.ACS Appl Mater Interfaces2022;14:14321-30

[37]

Zhu K,Ge G.Construction of multi-domain coexistence enhanced piezoelectric properties of Bi0.5Na0.5TiO3-based thin films.J Eur Ceram Soc2021;41:6456-64

[38]

Zhang R,Yang B.Inhibition of oxygen vacancy derived from donor doping in relaxor ferroelectric films for improving dielectric energy storage.J Phys Chem C2024;128:4395-403

[39]

Zhang J,Hao M.Enhanced properties of KNLN-BZ lead-free piezoelectric ceramics via three-step sintering.J Mater Sci Mater Electron2021;32:19778-85

[40]

Zhang Y,Lewis R.Understanding the effect of porosity on the polarisation-field response of ferroelectric materials.Acta Mater2018;154:100-12

[41]

Xia F.Postsintering annealing induced extrinsic dielectric and piezoelectric responses in lead-zinc-niobate-based ferroelectric ceramics.J Appl Phys2002;92:2709-16

[42]

Achuthan A.Domain switching in ferroelectric ceramic materials under combined loads.J Appl Phys2005;97:114103

[43]

Liu Y,Qi X,Zhang R.Adaptive ferroelectric states in KNN-based piezoceramics: Unveiling the mechanism of enhancing piezoelectric properties through multiple phase boundary engineering.Nano Energy2024;128:109972

[44]

Groppi C,Asa M.Spontaneous pattern of orthogonal ferroelectric domains in epitaxial KNN films.J Appl Phys2023;134:204102

[45]

Zhao C,Bai P,Dai X.Quantitative measurement of deformation field around low-angle grain boundaries by electron microscopy.Phys B Condens Matter2008;403:1838-42

[46]

Xie K,Li Y.Poling lead zirconate titanate ceramics with the assistance of stress.Ceram Int2023;49:13339-46

[47]

Kikuchi T.Stability of layered bismuth compounds in relation to the structural mismatch.Mater Res Bull1979;14:1561-9

[48]

Rao CNR.Intergrowth structures in inorganic solids: a new class of materials.Bull Mater Sci1985;7:155-78

PDF

0

Accesses

0

Citation

Detail
Sections
Recommended

/