Yang LT, Kong X, Li F, et al. Perovskite lead-free dielectrics for energy storage applications. Prog Mater Sci 2019, 102: 72-108.
Yao ZH, Song Z, Hao H, et al. Homogeneous/ inhomogeneous-structured dielectrics and their energy- storage performances. Adv Mater 2017, 29: 1601727.
Li Q, Han K, Gadinski MR, et al. High energy and power density capacitors from solution-processed ternary ferroelectric polymer nanocomposites. Adv Mater 2014, 26: 6244-6249.
Wang Y, Song Y, Xia Y. Electrochemical capacitors: Mechanism, materials, systems, characterization and applications. Chem Soc Rev 2016, 45: 5925-5950.
Bruce PG, Freunberger SA, Hardwick LJ, et al. Li-O2 and Li-S batteries with high energy storage. Nat Mater 2012, 11: 19-29.
Shao Z, Haile SM. A high-performance cathode for the next generation of solid-oxide fuel cells. Nature 2004, 431: 170-173.
Palneedi H, Peddigari M, Hwang GT, et al. High- performance dielectric ceramic films for energy storage capacitors: progress and outlook. Adv Funct Mater 2018, 28: 1803665.
Hao X. A review on the dielectric materials for high energy-storage application. J Adv Dielect 2013, 3: 1330001.
Yao FZ, Yuan Q, Wang Q, et al. Multiscale structural engineering of dielectric ceramics for energy storage applications: From bulk to thin films. Nanoscale 2020, 12: 17165-17184.
Tong S. Size and temperature effects on dielectric breakdown of ferroelectric films. J Adv Ceram 2021, 10: 181-186.
Zhao P, Wang H, Wu L, et al. High-performance relaxor ferroelectric materials for energy storage applications. Adv Energy Mater 2019, 9: 1803048.
Chen X, Zhang H, Cao F, et al. Charge-discharge properties of lead zirconate stannate titanate ceramics. J Appl Phys 2009, 106: 034105.
Yang SM, Jo JY, Kim TH, et al. AC dynamics of ferroelectric domains from an investigation of the frequency dependence of hysteresis loops. Phys Rev B 2010, 82: 174125.
Huang Y, Li F, Hao H, et al. (Bi0.51Na0.47)TiO3 based lead free ceramics with high energy density and efficiency. J Materiomics 2019, 5: 385-393.
Li J, Li F, Xu Z, et al. Multilayer lead-free ceramic capacitors with ultrahigh energy density and efficiency. Adv Mater 2018, 30: 1802155.
Lou XJ. Polarization fatigue in ferroelectric thin films and related materials. J Appl Phys 2009, 105: 024101.
Ye Y, Zhang SC, Dogan F, et al. Influence of nanocrystalline grain size on the breakdown strength of ceramic dielectrics. In: Proceedings of the 14th IEEE International Pulsed Power Conference, 2003: 719-722.
Dervos CT, Thirios, Novacovich J, et al. Permittivity properties of thermally treated TiO2. Mater Lett 2004, 58: 1502-1507.
Reddy CV, Reddy KR, Shetti NP, et al. Hetero- nanostructured metal oxide-based hybrid photocatalysts for enhanced photoelectrochemical water splitting—A review. Int J Hydrog Energy 2020, 45: 18331-18347.
Mehta A, Mishra A, Basu S, et al. Band gap tuning and surface modification of carbon dots for sustainable environmental remediation and photocatalytic hydrogen production—A review. J Environ Manag 2019, 250: 109486.
Parker R, Wasilik J. Dielectric constant and dielectric loss of TiO2 (rutile) at low frequencies. Phys Rev 1960, 120: 1631-1637.
Guo D, Ito A, Goto T, et al. Preparation of rutile TiO2 thin films by laser chemical vapor deposition method. J Adv Ceram 2013, 2: 162-166.
Hu W, Liu Y, Withers RL, et al. Electron-pinned defect-dipoles for high-performance colossal permittivity materials. Nat Mater 2013, 12: 821-826.
Li J, Li F, Li C, et al. Evidences of grain boundary capacitance effect on the colossal dielectric permittivity in (Nb + In) co-doped TiO2 ceramics. Sci Rep 2015, 5: 8295.
Li J, Li F, Zhuang Y, et al. Microstructure and dielectric properties of (Nb + In) co-doped rutile TiO2 ceramics. J Appl Phys 2014, 116: 074105.
Dong W, Hu W, Berlie A, et al. Colossal dielectric behavior of Ga+Nb co-doped rutile TiO2. ACS Appl Mater Interfaces 2015, 7: 25321-25325.
Nachaithong T, Kidkhunthod P, Thongbai P, et al. Surface barrier layer effect in (In + Nb) co-doped TiO2 ceramics: An alternative route to design low dielectric loss. J Am Ceram Soc 2017, 100: 1452-1459.
Petzelt J, Nuzhnyy D, Bovtun V, et al. Origin of the colossal permittivity of (Nb + In) co-doped rutile ceramics by wide-range dielectric spectroscopy. Phase Transitions 2018, 91: 932-941.
Chao S, Petrovsky V, Dogan F. Effects of sintering temperature on the microstructure and dielectric properties of titanium dioxide ceramics. J Mater Sci 2010, 45: 6685-6693.
Liu J, Zhang J, Wei M, et al. Dielectric properties of manganese-doped TiO2 with different alkali-free glass contents for energy storage application. J Mater Sci: Mater Electron 2016, 27: 7680-7684.
Chao S, Dogan F. Processing and dielectric properties of TiO2 thick films for high-energy density capacitor applications. Int J Appl Ceram Technol 2011, 8: 1363-1373.
Pai YY, Tylan-Tyler A, Irvin P, et al. Physics of SrTiO3-based heterostructures and nanostructures: A review. Rep Prog Phys 2018, 81: 036503.
Kumar Yadav A, Gautam CR. A review on crystallisation behaviour of perovskite glass ceramics. Adv Appl Ceram 2014, 113: 193-207.
Hu QG, Shen ZY, Li YM, et al. Enhanced energy storage properties of dysprosium doped strontium titanate ceramics. Ceram Int 2014, 40: 2529-2534.
Kong X, Yang L, Cheng Z, et al. Bi-modified SrTiO3- based ceramics for high-temperature energy storage applications. J Am Ceram Soc 2020, 103: 1722-1731.
Fergus JW. Oxide materials for high temperature thermoelectric energy conversion. J Eur Ceram Soc 2012, 32: 525-540.
Wang Y, Shen ZY, Li YM, et al. Optimization of energy storage density and efficiency in BaxSr1-xTiO3 (x ≤ 0.4) paraelectric ceramics. Ceram Int 2015, 41: 8252-8256.
Nishigaki S, Murano K, Ohkoshi A. Dielectric properties of ceramics in the system (Sr0.50Pb0.25Ca0.25)TiO3- Bi2O3·3TiO2 and their applications in a high-voltage capacitor. J Am Ceram Soc 1982, 65: 554-560.
Kong X, Yang L, Cheng Z, et al. (Ba,Sr)TiO3- Bi(Mg,Hf)O3 lead-free ceramic capacitors with high energy density and energy efficiency. ACS Appl Energy Mater 2020, 3: 12254-12262.
Fletcher NH, Hilton AD, Ricketts BW. Optimization of energy storage density in ceramic capacitors. J Phys D: Appl Phys 1996, 29: 253-258.
Ang C, Yu Z, Cross LE. Oxygen-vacancy-related low-frequency dielectric relaxation and electrical conduction in Bi: SrTiO3. Phys Rev B 2000, 62: 228-236.
Yu Z, Ang C. Dielectric relaxor and ferroelectric relaxor: Bi-doped paraelectric SrTiO3. J Appl Phys 2002, 91: 1487-1494.
Yu Z, Ang C. High capacitance-temperature sensitivity and “giant” dielectric constant in SrTiO3. Appl Phys Lett 2007, 90: 202903.
Shen ZY, Hu QG, Li YM, et al. Structure and dielectric properties of Re0.02Sr0.97TiO3 (Re = La, Sm, Gd, Er) ceramics for high-voltage capacitor applications. J Am Ceram Soc 2013, 96: 2551-2555.
Shen ZY, Li YM, Luo WQ, et al. Structure and dielectric properties of NdxSr1-xTiO3 ceramics for energy storage application. J Mater Sci: Mater Electron 2013, 24: 704-710.
Shen ZY, Luo WQ, Li YM, et al. Electrical hetero- structure of Nd0.1Sr0.9TiO3 ceramic for energy storage applications. J Mater Sci: Mater Electron 2013, 24: 607-612.
Song Z, Liu H, Zhang S, et al. Effect of grain size on the energy storage properties of (Ba0.4Sr0.6)TiO3 paraelectric ceramics. J Eur Ceram Soc 2014, 34: 1209-1217.
Wu YJ, Huang YH, Wang N, et al. Effects of phase constitution and microstructure on energy storage properties of barium strontium titanate ceramics. J Eur Ceram Soc 2017, 37: 2099-2104.
Zhang Q, Wang L, Luo J, et al. Improved energy storage density in barium strontium titanate by addition of BaO-SiO2-B2O3 glass. J Am Ceram Soc 2009, 92: 1871-1873.
Kim SH, Koh JH. ZnBO-doped (Ba,Sr)TiO3 ceramics for the low-temperature sintering process. J Eur Ceram Soc 2008, 28: 2969-2973.
Shen ZY, Wang Y, Tang YX, et al. Glass modified Barium strontium titanate ceramics for energy storage capacitor at elevated temperatures. J Materiomics 2019, 5: 641-648.
Yang X, Li W, Qiao Y, et al. High energy-storage density of lead-free (Sr1-1.5xBix)Ti0·99Mn0.01O3 thin films induced by Bi3+-VSr dipolar defects. Phys Chem Chem Phys 2019, 21: 16359-16366.
Zhang Y, Li W, Wang Z, et al. Ultrahigh energy storage and electrocaloric performance achieved in SrTiO3 amorphous thin films via polar cluster engineering. J Mater Chem A 2019, 7: 17797-17805.
Pan H, Zeng Y, Shen Y, et al. BiFeO3-SrTiO3 thin film as a new lead-free relaxor-ferroelectric capacitor with ultrahigh energy storage performance. J Mater Chem A 2017, 5: 5920-5926.
Hou C, Huang W, Zhao W, et al. Ultrahigh energy density in SrTiO3 film capacitors. ACS Appl Mater Interfaces 2017, 9: 20484-20490.
Gao W, Yao M, Yao X. Improvement of energy density in SrTiO3 film capacitor via self-repairing behavior. Ceram Int 2017, 43: 13069-13074.
Gao W, Yao M, Yao X. Achieving ultrahigh breakdown strength and energy storage performance through periodic interface modification in SrTiO3 thin film. ACS Appl Mater Interfaces 2018, 10: 28745-28753.
Chen X, Peng B, Ding M, et al. Giant energy storage density in lead-free dielectric thin films deposited on Si wafers with an artificial dead-layer. Nano Energy 2020, 78: 105390.
Cross LE. Relaxor ferroelectrics. Ferroelectrics 1987, 76: 241-267.
Pan Z, Wang P, Hou X, et al. Fatigue-free aurivillius phase ferroelectric thin films with ultrahigh energy storage performance. Adv Energy Mater 2020, 10: 2001536.
Shrout TR, Zhang SJ. Lead-free piezoelectric ceramics: Alternatives for PZT? J Electroceramics 2007, 19: 113-126.
Jaffe B, Cook WR, Jaffe H. Piezoelectric Ceramics Academic. Amsterdam: Elsevier, 1971.
Chen Y, Wang S, Zhou H, et al. A systematic analysis of the radial resonance frequency spectra of the PZT-based (Zr/Ti = 52/48) piezoceramic thin disks. J Adv Ceram 2020, 9: 380-392.
Gao J, Liu Y, Wang Y, et al. High temperature-stability of (Pb0.9La0.1)(Zr0.65Ti0.35)O3 ceramic for energy-storage applications at finite electric field strength. Scripta Mater 2017, 137: 114-118.
Zhang TF, Tang XG, Liu QX, et al. Energy-storage properties and high-temperature dielectric relaxation behaviors of relaxor ferroelectric Pb(Mg1/3Nb2/3)O3- PbTiO3 ceramics. J Phys D: Appl Phys 2016, 49: 095302.
Kumar A, Kim SH, Peddigari M, et al. High energy storage properties and electrical field stability of energy efficiency of (Pb0.89La0.11)(Zr0.70Ti0.30)0.9725O3 relaxor ferroelectric ceramics. Electron Mater Lett 2019, 15: 323-330.
Zhang T, Li W, Hou Y, et al. High-energy storage density and excellent temperature stability in antiferroelectric/ ferroelectric bilayer thin films. J Am Ceram Soc 2017, 100: 3080-3087.
Zhang T, Li W, Zhao Y, et al. High energy storage performance of opposite double-heterojunction ferroelectricity-insulators. Adv Funct Mater 2018, 28: 1706211.
Ma B, Hu Z, Koritala RE, et al. PLZT film capacitors for power electronics and energy storage applications. J Mater Sci: Mater Electron 2015, 26: 9279-9287.
Peng B, Tang S, Lu L, et al. Low-temperature-poling awakened high dielectric breakdown strength and outstanding improvement of discharge energy density of (Pb,La)(Zr,Sn,Ti)O3 relaxor thin film. Nano Energy 2020, 77: 105132.
Dai X, Viehland D. Effects of lanthanum modification on the antiferroelectric-ferroelectric stability of high zirconium-content lead zirconate titanate. J Appl Phys 1994, 76: 3701-3709.
Gupta SM, Li JF, Viehland D. Coexistence of relaxor and normal ferroelectric phases in morphotropic phase boundary compositions of lanthanum-modified lead zirconate titanate. J Am Ceram Soc 1998, 81: 557-564.
Hu Z, Ma B, Liu S, et al. Relaxor behavior and energy storage performance of ferroelectric PLZT thin films with different Zr/Ti ratios. Ceram Int 2014, 40: 557-562.
Liu Y, Hao X, An S. Significant enhancement of energy-storage performance of (Pb0.91La0.09)(Zr0.65Ti0.35)O3 relaxor ferroelectric thin films by Mn doping. J Appl Phys 2013, 114: 174102.
Peng B, Xie Z, Yue Z, et al. Improvement of the recoverable energy storage density and efficiency by utilizing the linear dielectric response in ferroelectric capacitors. Appl Phys Lett 2014, 105: 052904.
Zhang L, Hao X, Yang J, et al. Large enhancement of energy-storage properties of compositional graded (Pb1-xLax)(Zr0.65Ti0.35)O3 relaxor ferroelectric thick films. Appl Phys Lett 2013, 103: 113902.
Nguyen MD, Houwman EP, Rijnders G. Energy storage performance and electric breakdown field of thin relaxor ferroelectric PLZT films using microstructure and growth orientation control. J Phys Chem C 2018, 122: 15171-15179.
Nguyen MD, Nguyen CTQ, Vu HN, et al. Controlling microstructure and film growth of relaxor-ferroelectric thin films for high break-down strength and energy-storage performance. J Eur Ceram Soc 2018, 38: 95-103.
Smolenskii GA, Isupov VA, Agranovskaya AI, et al. New ferroelectrics of complex composition IV. J Sov Phy Solid State 1961, 2: 2651-2654.
Rao BN, Datta R, Chandrashekaran SS, et al. Local structural disorder and its influence on the average global structure and polar properties in Na0.5Bi0.5TiO3. Phys Rev B 2013, 88: 224103.
Reichmann K, Feteira A, Li M. Bismuth sodium titanate based materials for piezoelectric actuators. Materials 2015, 8: 8467-8495.
Suchanicz J, Kluczewska-Chmielarz K, Sitko D, et al. Electrical transport in lead-free Na0.5Bi0.5TiO3 ceramics. J Adv Ceram 2021, 10: 152-165.
Qiao X, Zhang F, Wu D, et al. Superior comprehensive energy storage properties in Bi0.5Na0.5TiO3-based relaxor ferroelectric ceramics. Chem Eng J 2020, 388: 124158.
Yang F, Pan Z, Ling Z, et al. Realizing high comprehensive energy storage performances of BNT-based ceramics for application in pulse power capacitors. J Eur Ceram Soc 2021, 41: 2548-2558.
Zhang X, Hu D, Pan Z, et al. Enhancement of recoverable energy density and efficiency of lead-free relaxor- ferroelectric BNT-based ceramics. Chem Eng J 2021, 406: 126818.
Zhu C, Cai Z, Luo B, et al. High temperature lead-free BNT-based ceramics with stable energy storage and dielectric properties. J Mater Chem A 2020, 8: 683-692.
Ma C, Tan X. In situ transmission electron microscopy study on the phase transitionsin lead-free (1-x)(Bi1/2Na1/2)TiO3-xBaTiO3 ceramics. J Am Ceram Soc 2011, 94: 4040-4044.
Jo W, Schaab S, Sapper E, et al. On the phase identity and its thermal evolution of lead free (Bi1/2Na1/2)TiO3-6 mol% BaTiO3. J Appl Phys 2011, 110: 074106.
Ye H, Yang F, Pan Z, et al. Significantly improvement of comprehensive energy storage performances with lead- free relaxor ferroelectric ceramics for high-temperature capacitors applications. Acta Mater 2021, 203: 116484.
Gao F, Dong X, Mao C, et al. Energy-storage properties of 0.89Bi0.5Na0.5TiO3-0.06BaTiO3-0.05K0.5Na0.5NbO3 lead-free anti-ferroelectric ceramics. J Am Ceram Soc 2011, 94: 4382-4386.
Cao W, Li W, Feng Y, et al. Defect dipole induced large recoverable strain and high energy-storage density in lead-free Na0.5Bi0.5TiO3-based systems. Appl Phys Lett 2016, 108: 202902.
Ren X. Large electric-field-induced strain in ferroelectric crystals by point-defect-mediated reversible domain switching. Nat Mater 2004, 3: 91-94.
Li F, Zhai J, Shen B, et al. Influence of structural evolution on energy storage properties in Bi0.5Na0.5TiO3-SrTiO3- NaNbO3 lead-free ferroelectric ceramics. J Appl Phys 2017, 121: 054103.
Yang L, Kong X, Cheng Z, et al. Ultra-high energy storage performance with mitigated polarization saturation in lead-free relaxors. J Mater Chem A 2019, 7: 8573-8580.
Li D, Shen ZY, Li ZP, et al. P-E hysteresis loop going slim in Ba0.3Sr0.7TiO3-modified Bi0.5Na0.5TiO3 ceramics for energy storage applications. J Adv Ceram 2020, 9: 183-192.
Li D, Shen Z-Y, Li Z, et al. Optimization of polarization behavior in (1-x)BSBNT-xNN ceramics for pulsed power capacitors. J Mater Chem C 2020, 8: 7650-7657.
Li J, Shen Z, Chen X, et al. Grain-orientation-engineered multilayer ceramic capacitors for energy storage applications. Nat Mater 2020, 19: 999-1005.
Yang H, Liu P, Yan F, et al. A novel lead-free ceramic with layered structure for high energy storage applications. J Alloys Compd 2019, 773: 244-249.
Jia W, Hou Y, Zheng M, et al. Superior temperature-stable dielectrics for MLCCs based on Bi0.5Na0.5TiO3-NaNbO3 system modified by CaZrO3. J Am Ceram Soc 2018, 101: 3468-3479.
Wang H, Zhao P, Chen L, et al. Energy storage properties of 0.87BaTiO3-0.13Bi(Zn2/3(Nb0.85Ta0.15)1/3)O3 multilayer ceramic capacitors with thin dielectric layers. J Adv Ceram 2020, 9: 292-302.
Feng C, Yang CH, Li SX, et al. Reduced leakage current and large polarization of Na0.5Bi0.5Ti0.98Mn0.02O3 thin film annealed at low temperature. Ceram Int 2015, 41: 14179-14183.
Wang J, Sun N, Li Y, et al. Effects of Mn doping on dielectric properties and energy-storage performance of Na0.5Bi0.5TiO3 thick films. Ceram Int 2017, 43: 7804-7809.
Feng C, Yang CH, Sui HT, et al. Effect of Fe doping on the crystallization and electrical properties of Na0.5Bi0.5TiO3 thin film. Ceram Int 2015, 41: 4214-4217.
Zhang YL, Li WL, Cao WP, et al. Enhanced energy-storage performance of 0.94NBT-0.06BT thin films induced by a Pb0.8La0.1Ca0.1Ti0.975O3 seed layer. Ceram Int 2016, 42: 14788-14792.
Peng B, Zhang Q, Li X, et al. Giant electric energy density in epitaxial lead-free thin films with coexistence of ferroelectrics and antiferroelectrics. Adv Electron Mater 2015, 1: 1500052.
Chen P, Wu S, Li P, et al. Great enhancement of energy storage density and power density in BNBT/xBFO multilayer thin film hetero-structures. Inorg Chem Front 2018, 5: 2300-2305.
Qian J, Han Y, Yang C, et al. Energy storage performance of flexible NKBT/NKBT-ST multilayer film capacitor by interface engineering. Nano Energy 2020, 74: 104862.
Guo Y, Li M, Zhao W, et al. Ferroelectric and pyroelectric properties of (Na0.5Bi0.5)TiO3-BaTiO3 based trilayered thin films. Thin Solid Films 2009, 517: 2974-2978.
Pan MJ, Randall CA. A brief introduction to ceramic capacitors. IEEE Electr Insul Mag 2010, 26: 44-50.
Zheng L, Yuan L, Liang G, et al. An in situ (K0.5Na0.5)NbO3-doped Barium titanate foam framework and its cyanate ester resin composites with temperature-stable dielectric properties and low dielectric loss. Mater Chem Front 2019, 3: 726-736.
Acosta M, Novak N, Rojas V, et al. BaTiO3-based piezoelectrics: Fundamentals, current status, and perspectives. Appl Phys Rev 2017, 4: 041305.
Gao WX, Zhu Y, Wang YJ, et al. A review of flexible perovskite oxide ferroelectric films and their application. J Materiomics 2020, 6: 1-16.
Zheng H, Wang J, Lofland SE, et al. Multiferroic BaTiO3-CoFe2O4 nanostructures. Science 2004, 303: 661-663.
Hu D, Pan Z, Tan X, et al. Optimization the energy density and efficiency of BaTiO3-based ceramics for capacitor applications. Chem Eng J 2021, 409: 127375.
Ogihara H, Randall CA, Trolier-Mckinstry S. High-energy density capacitors utilizing 0.7BaTiO3-0.3BiScO3 ceramics. J Am Ceram Soc 2009, 92: 1719-1724.
Wu L, Wang X, Li L. Core-shell BaTiO3@BiScO3 particles for local graded dielectric ceramics with enhanced temperature stability and energy storage capability. J Alloys Compd 2016, 688: 113-121.
Yuan Q, Li G, Yao F, et al. Simultaneously achieved temperature-insensitive high energy density and efficiency in domain engineered BaTiO3-Bi(Mg0.5Zr0.5)O3 lead-free relaxor ferroelectrics. Nano Energy 2018, 52: 203-210.
Choi DH, Baker A, Lanagan M, et al. Structural and dielectric properties in (1-x)BaTiO3-xBi(Mg1/2Ti1/2)O3 ceramics (0.1 ≤ x ≤ 0.5) and potential for high-voltage multilayer capacitors. J Am Ceram Soc 2013, 96: 2197-2202.
Li MD, Tang XG, Zeng SM, et al. Oxygen-vacancy-related dielectric relaxation behaviours and impedance spectroscopy of Bi(Mg1/2Ti1/2)O3 modified BaTiO3 ferroelectric ceramics. J Materiomics 2018, 4: 194-201.
Hanani Z, Mezzane D, Amjoud M, et al. Phase transitions, energy storage performances and electrocaloric effect of the lead-free Ba0.85Ca0.15Zr0.10Ti0.90O3 ceramic relaxor. J Mater Sci: Mater Electron 2019, 30: 6430-6438.
Wang XW, Zhang BH, Shi YC, et al. Enhanced energy storage properties in Ba0.85Ca0.15Zr0.1Ti0.9O3 ceramics with glass additives. J Appl Phys 2020, 127: 074103.
Hanani Z, Merselmiz S, Danine A, et al. Enhanced dielectric and electrocaloric properties in lead-free rod-like BCZT ceramics. J Adv Ceram 2020, 9: 210-219.
Patel S, Sharma D, Singh A, et al. Enhanced thermal energy conversion and dynamic hysteresis behavior of Sr-added Ba0.85Ca0.15Ti0.9Zr0.1O3 ferroelectric ceramics. J Materiomics 2016, 2: 75-86.
Su X, Riggs BC, Tomozawa M, et al. Preparation of BaTiO3/low melting glass core-shell nanoparticles for energy storage capacitor applications. J Mater Chem A 2014, 2: 18087-18096.
Zhang Y, Cao M, Yao Z, et al. Effects of silica coating on the microstructures and energy storage properties of BaTiO3 ceramics. Mater Res Bull 2015, 67: 70-76.
Wu L, Wang X, Gong H, et al. Core-satellite BaTiO3@SrTiO3 assemblies for a local compositionally graded relaxor ferroelectric capacitor with enhanced energy storage density and high energy efficiency. J Mater Chem C 2015, 3: 750-758.
Cheng H, Ouyang J, Zhang YX, et al. Demonstration of ultra-high recyclable energy densities in domain- engineered ferroelectric films. Nat Commun 2017, 8: 1999.
Yu Z, Ang C, Guo RY, et al. Ferroelectric-relaxor behavior of Ba(Ti0.7Zr0.3)O3 ceramics. J Appl Phys 2002, 92: 2655-2657.
Hennings D, Schnell A, Simon G. Diffuse ferroelectric phase transitions in Ba(Ti1-yZry)O3 ceramics. J Am Ceram Soc 1982, 65: 539-544.
Instan AA, Pavunny SP, Bhattarai MK, et al. Ultrahigh capacitive energy storage in highly oriented Ba(ZrxTi1-x)O3 thin films prepared by pulsed laser deposition. Appl Phys Lett 2017, 111: 142903.
Reddy SR, Prasad VVB, Bysakh S, et al. Superior energy storage performance and fatigue resistance in ferroelectric BCZT thin films grown in an oxygen-rich atmosphere. J Mater Chem C 2019, 7: 7073-7082.
Ortega N, Kumar A, Scott JF, et al. Relaxor-ferroelectric superlattices: High energy density capacitors. J Phys: Condens Matter 2012, 24: 445901.
Sun Z, Ma C, Liu M, et al. Ultrahigh energy storage performance of lead-free oxide multilayer film capacitors via interface engineering. Adv Mater 2017, 29: 1604427.
Zhang W, Gao Y, Kang L, et al. Space-charge dominated epitaxial BaTiO3 heterostructures. Acta Mater 2015, 85: 207-215.
Ru J, Min D, Lanagan M, et al. Enhanced energy storage properties of thermostable sandwich-structured BaTiO3/polyimide nanocomposites with better controlled interfaces. Mater Des 2021, 197: 109270.
Rojac T, Bencan A, Malic B, et al. BiFeO3 ceramics: Processing, electrical, and electromechanical properties. J Am Ceram Soc 2014, 97: 1993-2011.
Yang CH, Qian J, Lv P, et al. Flexible lead-free BFO-based dielectric capacitor with large energy density, superior thermal stability, and reliable bending endurance. J Materiomics 2020, 6: 200-208.
Gao X, Li Y, Chen J, et al. High energy storage performances of Bi1-xSmxFe0.95Sc0.05O3 lead-free ceramics synthesized by rapid hot press sintering. J Eur Ceram Soc 2019, 39: 2331-2338.
Yin L, Mi W. Progress in BiFeO3-based heterostructures: Materials, properties and applications. Nanoscale 2020, 12: 477-523.
Li Q, Ji S, Wang D, et al. Simultaneously enhanced energy storage density and efficiency in novel BiFeO3-based lead-free ceramic capacitors. J Eur Ceram Soc 2021, 41: 387-393.
Lee MH, Kim DJ, Park JS, et al. High-performance lead-free piezoceramics with high curie temperatures. Adv Mater 2015, 27: 6976-6982.
Wu J, Fan Z, Xiao D, et al. Multiferroic bismuth ferrite-based materials for multifunctional applications: Ceramic bulks, thin films and nanostructures. Prog Mater Sci 2016, 84: 335-402.
Hang Q, Zhou W, Zhu X, et al. Structural, spectroscopic, and dielectric characterizations of Mn-doped 0.67BiFeO3-0.33BaTiO3 multiferroic ceramics. J Adv Ceram 2013, 2: 252-259.
Liu N, Liang R, Zhou Z, et al. Designing lead-free bismuth ferrite-based ceramics learning from relaxor ferroelectric behavior for simultaneous high energy density and efficiency under low electric field. J Mater Chem C 2018, 6: 10211-10217.
Qi H, Xie A, Tian A, et al. Superior energy-storage capacitors with simultaneously giant energy density and efficiency using nanodomain engineered BiFeO3-BaTiO3- NaNbO3 lead-free bulk ferroelectrics. Adv Energy Mater 2020, 10: 1903338.
Wang G, Li J, Zhang X, et al. Ultrahigh energy storage density lead-free multilayers by controlled electrical homogeneity. Energy Environ Sci 2019, 12: 582-588.
Correia TM, McMillen M, Rokosz MK, et al. A lead-free and high-energy density ceramic for energy storage applications. J Am Ceram Soc 2013, 96: 2699-2702.
Pan H, Li F, Liu Y, et al. Ultrahigh-energy density lead-free dielectric films via polymorphic nanodomain design. Science 2019, 365: 578-582.
Kan D, Pálová L, Anbusathaiah V, et al. Universal behavior and electric-field-induced structural transition in rare-earth-substituted BiFeO3. Adv Funct Mater 2010, 20: 1108-1115.
McMillen M, Douglas AM, Correia TM, et al. Increasing recoverable energy storage in electroceramic capacitors using “dead-layer” engineering. Appl Phys Lett 2012, 101: 242909.
Hou Y, Han R, Li W, et al. Significantly enhanced energy storage performance in BiFeO3/BaTiO3/BiFeO3 sandwich- structured films through crystallinity regulation. Phys Chem Chem Phys 2018, 20: 21917-21924.
Zhu H, Liu M, Zhang Y, et al. Increasing energy storage capabilities of space-charge dominated ferroelectric thin films using interlayer coupling. Acta Mater 2017, 122: 252-258.
Li JF, Wang K, Zhu FY, et al. (K,Na)NbO3-based lead-free piezoceramics: Fundamental aspects, processing technologies, and remaining challenges. J Am Ceram Soc 2013, 96: 3677-3696.
Egerton L, Dillon DM. Piezoelectric and dielectric properties of ceramics in the system potassium-sodium niobate. J Am Ceram Soc 1959, 42: 438-442
Yang Z, Du H, Qu S, et al. Significantly enhanced recoverable energy storage density in potassium-sodium niobate-based lead free ceramics. J Mater Chem A 2016, 4: 13778-13785.
Shao T, Du H, Ma H, et al. Potassium-sodium niobate based lead-free ceramics: novel electrical energy storage materials. J Mater Chem A 2017, 5: 554-563.
Qu B, Du H, Yang Z, et al. Large recoverable energy storage density and low sintering temperature in potassium-sodium niobate-based ceramics for multilayer pulsed power capacitors. J Am Ceram Soc 2017, 100: 1517-1526.
Qu B, Du H, Yang Z, et al. Enhanced dielectric breakdown strength and energy storage density in lead-free relaxor ferroelectric ceramics prepared using transition liquid phase sintering. RSC Adv 2016, 6: 34381-34389.
Yang Y, Ji Y, Fang M, et al. Morphotropic relaxor boundary in a relaxor system showing enhancement of electrostrain and dielectric permittivity. Phys Rev Lett 2019, 123: 137601.
Won SS, Kawahara M, Kuhn L, et al. BiFeO3-doped (K0.5,Na0.5)(Mn0.005,Nb0.995)O3 ferroelectric thin film capacitors for high energy density storage applications. Appl Phys Lett 2017, 110: 152901.
Huang Y, Shu L, Zhang SW, et al. Simultaneously achieved high-energy storage density and efficiency in (K,Na)NbO3-based lead-free ferroelectric films. J Am Ceram Soc 2021, 104: 4119-4130.
Kittel C. Theory of antiferroelectric crystals. Phys Rev 1951, 82: 729-732.
Tagantsev A, Vaideeswaran K, Vakhrushev S, et al. The origin of antiferroelectricity in PbZrO3. Nat Commun 2013, 4: 2229.
Chen N, Bai G, Auciello O, et al. Properties and orientation of antiferroelectric lead zirconate thin films grown by MOCVD. MRS Online Proc Libr 1998, 541: 345-350.
Hao X, Zhai J, Yao X. Improved energy storage performance and fatigue endurance of Sr-doped PbZrO3 antiferroelectric thin films. J Am Ceram Soc 2009, 92: 1133-1135.
Parui J, Krupanidhi SB. Enhancement of charge and energy storage in sol-gel derived pure and La-modified PbZrO3 thin films. Appl Phys Lett 2008, 92: 192901.
Tani T, Li JF, Viehland D, et al. Antiferroelectric- ferroelectric switching and induced strains for sol-gel derived lead zirconate thin layers. J Appl Phys 1994, 75: 3017-3023.
Ye M, Sun Q, Chen X, et al. Electrical and energy storage performance of Eu-doped PbZrO3 thin films with different gradient sequences. J Am Ceram Soc 2012, 95: 1486-1488.
Sa T, Cao Z, Wang Y, et al. Enhancement of charge and energy storage in PbZrO3 thin films by local field engineering. Appl Phys Lett 2014, 105: 043902.
Chen MJ, Ning XK, Wang SF, et al. Significant enhancement of energy storage density and polarization in self-assembled PbZrO3:NiO nano-columnar composite films. Nanoscale 2019, 11: 1914-1920.
Ge J, Remiens D, Costecalde J, et al. Effect of residual stress on energy storage property in PbZrO3 antiferroelectric thin films with different orientations. Appl Phys Lett 2013, 103: 162903.
Ge J, Remiens D, Dong X, et al. Enhancement of energy storage in epitaxial PbZrO3 antiferroelectric films using strain engineering. Appl Phys Lett 2014, 105: 112908.
Corker DL, Glazer AM, Kaminsky W, et al. Investigation into the crystal structure of the perovskite lead hafnate, PbHfO3. Acta Crystallogr Sect B 1998, 54: 18-28.
Madigout V, Baudour JL, Bouree F, et al. Crystallographic structure of lead hafnate (PbHfO3) from neutron powder diffraction and electron microscopy. Philos Mag A 1999, 79: 847-858.
Burkovsky RG, Bronwald I, Andronikova D, et al. Triggered incommensurate transition in PbHfO3. Phys Rev B 2019, 100: 014107.
Chao W, Yang T, Li Y. Achieving high energy efficiency and energy density in PbHfO3-based antiferroelectric ceramics. J Mater Chem C 2020, 8: 17016-17024.
Huang XX, Zhang TF, Wang W, et al. Tailoring energy-storage performance in antiferroelectric PbHfO3 thin films. Mater Des 2021, 204: 109666.
Xu B, Moses P, Pai NG, et al. Charge release of lanthanum-doped lead zirconate titanate stannate antiferroelectric thin films. Appl Phys Lett 1998, 72: 593-595.
Sharifzadeh Mirshekarloo M, Yao K, Sritharan T. Large strain and high energy storage density in orthorhombic perovskite (Pb0.97La0.02)(Zr1-x-ySnxTiy)O3 antiferroelectric thin films. Appl Phys Lett 2010, 97: 142902.
Zhang AH, Wang W, Li QJ, et al. Internal-strain release and remarkably enhanced energy storage performance in PLZT-SrTiO3 multilayered films. Appl Phys Lett 2020, 117: 252901.
Dan Y, Xu H, Zou K, et al. Energy storage characteristics of (Pb,La)(Zr,Sn,Ti)O3 antiferroelectric ceramics with high Sn content. Appl Phys Lett 2018, 113: 063902.
Liu P, Fan B, Yang G, et al. High energy density at high temperature in PLZST antiferroelectric ceramics. J Mater Chem C 2019, 7: 4587-4594.
Xu B, Ye Y, Cross L. Dielectric properties and field-induced phase switching of lead zirconate titanate stannate antiferroelectric thick films on silicon substrates. J Appl Phys 2000, 87: 2507-2515.
Markowski K, Park SE, Yoshikawa S, et al. Effect of compositional variations in the lead lanthanum zirconate stannate titanate system on electrical properties. J Am Ceram Soc 1996, 79: 3297-3304.
Zheng Q, Yang T, Wei K, et al. Effect of Sn:Ti variations on electric filed induced AFE-FE phase transition in PLZST antiferroelectric ceramics. Ceram Int 2012, 38: S9-S12.
Liu Z, Bai Y, Chen X, et al. Linear composition-dependent phase transition behavior and energy storage performance of tetragonal PLZST antiferroelectric ceramics. J Alloys Compd 2017, 691: 721-725.
Zhang L, Jiang S, Fan B, et al. Enhanced energy storage performance in (Pb0.858Ba0.1La0.02Y0.008)(Zr0.65Sn0.3Ti0.05)O3- (Pb0.97La0.02)(Zr0.9Sn0.05Ti0.05)O3 anti-ferroelectric composite ceramics by Spark Plasma Sintering. J Alloys Compd 2015, 622: 162-165.
Zhang G, Zhu D, Zhang X, et al. High-energy storage performance of (Pb0.87Ba0.1La0.02)(Zr0.68Sn0.24Ti0.08)O3 antiferroelectric ceramics fabricated by the hot-press sintering method. J Am Ceram Soc 2015, 98: 1175-1181.
Zhang G, Liu S, Yu Y, et al. Microstructure and electrical properties of (Pb0.87Ba0.1La0.02)(Zr0.68Sn0.24Ti0.08)O3 anti-ferroelectric ceramics fabricated by the hot-press sintering method. J Eur Ceram Soc 2013, 33: 113-121.
Bian F, Yan S, Xu C, et al. Enhanced breakdown strength and energy density of antiferroelectric Pb,La(Zr,Sn,Ti)O3 ceramic by forming core-shell structure. J Eur Ceram Soc 2018, 38: 3170-3176.
Wang H, Liu Y, Yang T, et al. Ultrahigh energy-storage density in antiferroelectric ceramics with field-induced multiphase transitions. Adv Funct Mater 2019, 29: 1807321.
Zhang Y, Liu P, Kandula KR, et al. Achieving excellent energy storage density of Pb0.97La0.02(ZrxSn0.05Ti0.95-x)O3 ceramics by the B-site modification. J Eur Ceram Soc 2021, 41: 360-367.
Liu X, Li Y, Hao X. Ultra-high energy-storage density and fast discharge speed of (Pb0.98-xLa0.02Srx)(Zr0.9Sn0.1)0.995O3 antiferroelectric ceramics prepared via the tape-casting method. J Mater Chem A 2019, 7: 11858-11866.
Gao M, Tang X, Leung CM, et al. Phase transition and energy storage behavior of antiferroelectric PLZT thin films epitaxially deposited on SRO buffered STO single crystal substrates. J Am Ceram Soc 2019, 102: 5180-5191.
Ma B, Kwon DK, Narayanan M, et al. Dielectric properties and energy storage capability of antiferroelectric Pb0.92La0.08Zr0.95Ti0.05O3 film-on-foil capacitors. J Mater Res 2009, 24: 2993-2996.
Tong S, Ma B, Narayanan M, et al. Lead lanthanum zirconate titanate ceramic thin films for energy storage. ACS Appl Mater Interfaces 2013, 5: 1474-1480.
Lin Z, Chen Y, Liu Z, et al. Large energy storage density, low energy loss and highly stable (Pb0.97La0.02)(Zr0.66Sn0.23Ti0.11)O3 antiferroelectric thin-film capacitors. J Eur Ceram Soc 2018, 38: 3177-3181.
Ma B, Kwon DK, Narayanan M, et al. Fabrication of antiferroelectric PLZT films on metal foils. Mater Res Bull 2009, 44: 11-14.
Zhang MH, Fulanović L, Egert S, et al. Electric- field-induced antiferroelectric to ferroelectric phase transition in polycrystalline NaNbO3. Acta Mater 2020, 200: 127-135.
Chen J, Feng D. TEM study of phases and domains in NaNbO3 at room temperature. Phys Status Solidi a 1988, 109: 171-185.
Saito T, Adachi H, Wada T, et al. Pulsed-laser deposition of ferroelectric NaNbO3Thin films. Jpn J Appl Phys 2005, 44: 6969-6972.
Koruza J, Groszewicz P, Breitzke H, et al. Grain-size- induced ferroelectricity in NaNbO3. Acta Mater 2017, 126: 77-85.
Shuvaeva VA, Antipin MY, Lindeman RSV, et al. Crystal structure of the electric-fieldinduced ferroelectric phase of NaNbO3. Ferroelectrics 1993, 141: 307-311.
Shimizu H, Guo H, Reyes-Lillo SE, et al. Lead-free antiferroelectric: xCaZrO3-(1-x)NaNbO3 system (0 ≤ x ≤ 0.10). Dalton Trans 2015, 44: 10763-10772.
Guo H, Shimizu H, Mizuno Y, et al. Strategy for stabilization of the antiferroelectric phase (Pbma) over the metastable ferroelectric phase (P21ma) to establish double loop hysteresis in lead-free (1-x)NaNbO3-xSrZrO3 solid solution. J Appl Phys 2015, 117: 214103.
Gao L, Guo H, Zhang S, et al. A perovskite lead-free antiferroelectric xCaHfO3-(1-x) NaNbO3 with induced double hysteresis loops at room temperature. J Appl Phys 2016, 120: 204102.
Gao L, Guo H, Zhang S, et al. Stabilized antiferroelectricity in xBiScO3-(1-x)NaNbO3 lead-free ceramics with established double hysteresis loops. Appl Phys Lett 2018, 112: 092905.
Zhou M, Liang R, Zhou Z, et al. Superior energy storage properties and excellent stability of novel NaNbO3-based lead-free ceramics with A-site vacancy obtained via a Bi2O3 substitution strategy. J Mater Chem A 2018, 6: 17896-17904.
Ye J, Wang G, Zhou M, et al. Excellent comprehensive energy storage properties of novel lead-free NaNbO3-based ceramics for dielectric capacitor applications. J Mater Chem C 2019, 7: 5639-5645.
Dong X, Li X, Chen X, et al. High energy storage density and power density achieved simultaneously in NaNbO3-based lead-free ceramics via antiferroelectricity enhancement. J Materiomics 2021, 7: 629-639.
Fujii I, Shimasaki T, Nobe T, et al. Effects of SrTiO3 substrate orientations on crystal and domain structures and electric properties of NaNbO3-SrZrO3 films. Jpn J Appl Phys 2018, 57: 11UF13.
Beppu K, Shimasaki T, Fujii I, et al. Energy storage properties of antiferroelectric 0.92NaNbO3-0.08SrZrO3 film on (001)SrTiO3 substrate. Phys Lett A 2020, 384: 126690.
Luo B, Dong H, Wang D, et al. Large recoverable energy density with excellent thermal stability in Mn-modified NaNbO3-CaZrO3 lead-free thin films. J Am Ceram Soc 2018, 101: 3460-3467.
Kania A, Kwapulinski J. Ag1-xNaxNbO3 (ANN) solid solutions: From disordered antiferroelectric AgNbO3 to normal antiferroelectric NaNbO3. J Phys: Condens Matter 1999, 11: 8933-8946.
Wang D, Kako T, Ye J. New series of solid-solution semiconductors (AgNbO3)1-x(SrTiO3)x with modulated band structure and enhanced visible-light photocatalytic activity. J Phys Chem C 2009, 113: 3785-3792.
Fu D, Endo M, Taniguchi H, et al. AgNbO3: A lead-free material with large polarization and electromechanical response. Appl Phys Lett 2007, 90: 252907.
Tian Y, Jin L, Zhang H, et al. High energy density in silver niobate ceramics. J Mater Chem A 2016, 4: 17279-17287.
Zhao L, Liu Q, Gao J, et al. Lead-free antiferroelectric silver niobate tantalate with high energy storage performance. Adv Mater 2017, 29: 1701824.
Luo N, Han K, Cabral MJ, et al. Constructing phase boundary in AgNbO3 antiferroelectrics: Pathway simultaneously achieving high energy density and efficiency. Nat Commun 2020, 11: 4824.
Yan Z, Zhang D, Zhou X, et al. Silver niobate based lead-free ceramics with high energy storage density. J Mater Chem A 2019, 7: 10702-10711.
Luo N, Han K, Zhuo F, et al. Aliovalent A-site engineered AgNbO3 lead-free antiferroelectric ceramics toward superior energy storage density. J Mater Chem A 2019, 7: 14118-14128.
Lu Z, Bao W, Wang G, et al. Mechanism of enhanced energy storage density in AgNbO3-based lead-free antiferroelectrics. Nano Energy 2021, 79: 105423.
Zhao L, Gao J, Liu Q, et al. Silver niobate lead-free antiferroelectric ceramics: Enhancing energy storage density by B-site doping. ACS Appl Mater Interfaces 2018, 10: 819-826.
Tian Y, Jin L, Zhang H, et al. Phase transitions in bismuth-modified silver niobate ceramics for high power energy storage. J Mater Chem A 2017, 5: 17525-17531.
Luo N, Han K, Zhuo F, et al. Design for high energy storage density and temperature-insensitive lead-free antiferroelectric ceramics. J Mater Chem C 2019, 7: 4999-5008.
Gao J, Zhang Y, Zhao L, et al. Enhanced antiferroelectric phase stability in La-doped AgNbO3: Perspectives from the microstructure to energy storage properties. J Mater Chem A 2019, 7: 2225-2232.
Han K, Luo N, Mao S, et al. Realizing high low-electric-field energy storage performance in AgNbO3 ceramics by introducing relaxor behaviour. J Materiomics 2019, 5: 597-605.
Wang J, Wan X, Rao Y, et al. Hydrothermal synthesized AgNbO3 powders: Leading to greatly improved electric breakdown strength in ceramics. J Eur Ceram Soc 2020, 40: 5589-5596.