Ibn-Mohammed T, Randall CA, Mustapha KB, et al. Decarbonising ceramic manufacturing: A techno-economic analysis of energy efficient sintering technologies in the functional materials sector. J Eur Ceram Soc 2019, 39: 5213–5235.
Wang G, Lu ZL, Li Y, et al. Electroceramics for high-energy density capacitors: Current status and future perspectives. Chem Rev 2021, 121: 6124–6172.
Sherrill SA, Banerjee P, Rubloff GW, et al. High to ultra-high power electrical energy storage. Phys Chem Chem Phys 2011, 13: 20714–20723.
Liu C, Li F, Ma LP, et al. Advanced materials for energy storage. Adv Mater 2010, 22: E28–E62.
Li JL, Li F, Xu Z, et al. Multilayer lead-free ceramic capacitors with ultrahigh energy density and efficiency. Adv Mater 2018, 30: 1802155.
Lee H, Kim JR, Lanagan MJ, et al. High-energy density dielectrics and capacitors for elevated temperatures: Ca(Zr,Ti)O3. J Am Ceram Soc 2013, 96: 1209–1213.
Prateek, Thakur VK, Gupta RK. Recent progress on ferroelectric polymer-based nanocomposites for high energy density capacitors: Synthesis, dielectric properties, and future aspects. Chem Rev 2016, 116: 4260–4317.
Yao ZH, Song Z, Hao H, et al. Homogeneous/ inhomogeneous-structured dielectrics and their energy-storage performances. Adv Mater 2017, 29: 1601727.
Han FM, Meng GW, Zhou F, et al. Dielectric capacitors with three-dimensional nanoscale interdigital electrodes for energy storage. Sci Adv 2015, 1: e1500605.
Dang ZM, Yuan JK, Yao SH, et al. Flexible nanodielectric materials with high permittivity for power energy storage. Adv Mater 2013, 25: 6334–6365.
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.
Ibrahim H, Ilinca A, Perron J. Energy storage systems— Characteristics and comparisons. Renew Sust Energ Rev 2008, 12: 1221–1250.
Pan H, Lan S, Xu SQ, et al. Ultrahigh energy storage in superparaelectric relaxor ferroelectrics. Science 2021, 374: 100–104.
Pan H, Li F, Liu Y, et al. Ultrahigh-energy density lead-free dielectric films via polymorphic nanodomain design. Science 2019, 365: 578–582.
Burn I, Smyth DM. Energy storage in ceramic dielectrics. J Mater Sci 1972, 7: 339–343.
Chauhan A, Patel S, Vaish R, et al. Anti-ferroelectric ceramics for high energy density capacitors. Materials 2015, 8: 8009–8031.
Zhao PY, Cai ZM, Wu LW, et al. Perspectives and challenges for lead-free energy-storage multilayer ceramic capacitors. J Adv Ceram 2021, 10: 1153–1193.
Li B, Liu QX, Tang XG, et al. Antiferroelectric to relaxor ferroelectric phase transition in PbO modified (Pb0.97La0.02) (Zr0.95Ti0.05)O3 ceramics with a large energy-density for dielectric energy storage. RSC Adv 2017, 7: 43327–43333.
Jiang J, Li XJ, Li L, et al. Novel lead-free NaNbO3-based relaxor antiferroelectric ceramics with ultrahigh energy storage density and high efficiency. J Materiomics 2022, 8: 295–301.
Li DX, Zeng XJ, Li ZP, et al. Progress and perspectives in dielectric energy storage ceramics. J Adv Ceram 2021, 10: 675–703.
Wang J, Rao Y, Fan XH, et al. Synergic modulation of over-stoichiometrical MnO2 and SiO2-coated particles on the energy storage properties of silver niobate-based ceramics. Ceram Int 2021, 47: 19595–19604.
Wang J, Wan XH, 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.
Zhu LF, Zhao L, Yan YK, et al. Composition and strain engineered AgNbO3-based multilayer capacitors for ultra-high energy storage capacity. J Mater Chem A 2021, 9: 9655–9664.
Qi H, Xie AW, 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.
Yang LT, Kong X, Li F, et al. Perovskite lead-free dielectrics for energy storage applications. Prog Mater Sci 2019, 102: 72–108.
Ma JJ, Zhang J, Guo J, et al. Achieving ultrahigh energy storage density in lead-free sodium niobate-based ceramics by modulating the antiferroelectric phase. Chem Mater 2022, 34: 7313–7322.
Fan XH, Wang J, Yuan H, et al. Synergic enhancement of energy storage density and efficiency in MnO2-doped AgNbO3@SiO2 ceramics via A/B-site substitutions. ACS Appl Mater Interfaces 2022, 14: 7052–7062.
Yuan QB, Yao FZ, Cheng SD, et al. Bioinspired hierarchically structured all-inorganic nanocomposites with significantly improved capacitive performance. Adv Funct Mater 2020, 30: 2000191.
Chen L, Long FX, Qi H, et al. Outstanding energy storage performance in high-hardness (Bi0.5K0.5)TiO3-based lead-free relaxors via multi-scale synergistic design. Adv Funct Mater 2022, 32: 2110478.
Fan XH, Wang J, Rao Y, et al. Simultaneous improved polarization and breakdown strength in Mn/W co-doped silver niobate ceramics. J Mater Sci 2021, 56: 19155–19164.
Lu ZL, Bao WC, Wang G, et al. Mechanism of enhanced energy storage density in AgNbO3-based lead-free antiferroelectrics. Nano Energy 2021, 79: 105423.
Yuan QB, Li G, Yao FZ, 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.
Chen L, Deng SQ, Liu H, et al. Giant energy-storage density with ultrahigh efficiency in lead-free relaxors via high-entropy design. Nat Commun 2022, 13: 3089.
Zhao L, Liu Q, Gao J, et al. Lead-free antiferroelectric silver niobate tantalate with high energy storage performance. Adv Mater 2017, 29: 1701824.
Cui T, Zhang J, Guo J, et al. Simultaneous achievement of ultrahigh energy storage density and high efficiency in BiFeO3-based relaxor ferroelectric ceramics via a highly disordered multicomponent design. J Mater Chem A 2022, 10: 14316–14325.
Hanzig J, Zschornak M, Nentwich M, et al. Strontium titanate: An all-in-one rechargeable energy storage material. J Power Sources 2014, 267: 700–705.
Bartkowiak M, Mahan GD. Nonlinear currents in Voronoi networks. Phys Rev B 1995, 51: 10825–10832.
Shay DP, Podraza NJ, Donnelly NJ, et al. High energy density, high temperature capacitors utilizing Mn-doped 0.8CaTiO3–0.2CaHfO3 ceramics. J Am Ceram Soc 2012, 95: 1348–1355.
Shende RV, Krueger DS, Rossetti GA, et al. Strontium zirconate and strontium titanate ceramics for high-voltage applications: Synthesis, processing, and dielectric properties. J Am Ceram Soc 2001, 84: 1648–1650.
Song Z, Liu HX, Zhang SJ, 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.
Li JJ, Claude J, Norena-Franco LE, et al. Electrical energy storage in ferroelectric polymer nanocomposites containing surface-functionalized BaTiO3 nanoparticles. Chem Mater 2008, 20: 6304–6306.
Tang HX, Zhou Z, Sodano HA. Large-scale synthesis of BaxSr1−xTiO3 nanowires with controlled stoichiometry. Appl Phys Lett 2014, 104: 142905.
Zhou Z, Tang HX, Sodano HA. Scalable synthesis of morphotropic phase boundary lead zirconium titanate nanowires for energy harvesting. Adv Mater 2014, 26: 7547–7554.
Cui T, Yu AN, Zhang YY, et al. Energy storage performance of BiFeO3–SrTiO3–BaTiO3 relaxor ferroelectric ceramics. J Am Ceram Soc 2022, 105: 6252–6261.
Randall CA, Fan ZM, Reaney I, et al. Antiferroelectrics: History, fundamentals, crystal chemistry, crystal structures, size effects, and applications. J Am Ceram Soc 2021, 104: 3775–3810.
Jaffe B. Antiferroelectric ceramics with field-enforced transitions: A new nonlinear circuit element. Proc IRE 1961, 49: 1264–1267.
Ji HF, Wang DW, Bao WC, et al. Ultrahigh energy density in short-range tilted NBT-based lead-free multilayer ceramic capacitors by nanodomain percolation. Energy Storage Mater 2021, 38: 113–120.
Wang HS, Liu YC, Yang TQ, et al. Ultrahigh energy-storage density in antiferroelectric ceramics with field-induced multiphase transitions. Adv Funct Mater 2019, 29: 1807321.
Ma JJ, Zhang DH, Ying F, et al. Ultrahigh energy storage density and high efficiency in lead-free (Bi0.9Na0.1) (Fe0.8Ti0.2)O3-modified NaNbO3 ceramics via stabilizing the antiferroelectric phase and enhancing relaxor behavior. ACS Appl Mater Interfaces 2022, 14: 19704–19713.
Zhang MH, Hadaeghi N, Egert S, et al. Design of lead-free antiferroelectric (1−x)NaNbO3–xSrSnO3 compositions guided by first-principles calculations. Chem Mater 2021, 33: 266–274.
Dong XY, Li X, Chen HY, et al. Realizing enhanced energy storage and hardness performances in 0.90NaNbO3–0.10Bi(Zn0.5Sn0.5)O3 ceramics. J Adv Ceram 2022, 11: 729–741.
Luo NN, 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.
Qi H, Zuo RZ. Linear-like lead-free relaxor antiferroelectric (Bi0.5Na0.5)TiO3–NaNbO3 with giant energy-storage density/efficiency and super stability against temperature and frequency. J Mater Chem A 2019, 7: 3971–3978.
Jiang J, Meng XJ, Li L, et al. Ultrahigh energy storage density in lead-free relaxor antiferroelectric ceramics via domain engineering. Energy Storage Mater 2021, 43: 383–390.
Fu DS, Endo M, Taniguchi H, et al. AgNbO3: A lead-free material with large polarization and electromechanical response. Appl Phys Lett 2007, 90: 252907.
Gallagher JA, Jo HR, Lynch CS. Large-field dielectric loss in relaxor ferroelectric PLZT. Smart Mater Struct 2014, 23: 035007.
Li JL, Shen ZH, Chen XH, et al. Grain-orientation-engineered multilayer ceramic capacitors for energy storage applications. Nat Mater 2020, 19: 999–1005.
Zhao PY, Cai ZM, Chen LL, et al. Ultra-high energy storage performance in lead-free multilayer ceramic capacitors via a multiscale optimization strategy. Energy Environ Sci 2020, 13: 4882–4890.
Zhao PY, Chen LL, Li LT, et al. Ultrahigh energy density with excellent thermal stability in lead-free multilayer ceramic capacitors via composite strategy design. J Mater Chem A 2021, 9: 25914–25921.
Kim C, Pilania G, Ramprasad R. Machine learning assisted predictions of intrinsic dielectric breakdown strength of ABX3 perovskites. J Phys Chem C 2016, 120: 14575–14580.
Xu YH, Yang ZD, Xu K, et al. Modulated band structure and phase transitions in calcium hafnate titanate modified silver niobate ceramics for energy storage. Chem Eng J 2021, 426: 131047.
Luo CY, Feng Q, Luo NN, et al. Effect of Ca2+/Hf4+ modification at A/B sites on energy-storage density of Bi0.47Na0.47Ba0.06TiO3 ceramics. Chem Eng J 2021, 420: 129861.
Li S, Hu TF, Nie HC, et al. Giant energy density and high efficiency achieved in silver niobate-based lead-free antiferroelectric ceramic capacitors via domain engineering. Energy Storage Mater 2021, 34: 417–426.
Dai ZH, Xie JL, Chen ZB, et al. Improved energy storage density and efficiency of (1−x)Ba0.85Ca0.15Zr0.1Ti0.9O3–xBiMg2/3Nb1/3O3 lead-free ceramics. Chem Eng J 2021, 410: 128341.
Luo NN, Han K, Zhuo FP, et al. Aliovalent A-site engineered AgNbO3 lead-free antiferroelectric ceramics toward superior energy storage density. J Mater Chem A 2019, 7: 14118–14128.
Jin Q, Zhao LL, Cui B, et al. Enhanced energy storage properties in lead-free BaTiO3@Na0.5K0.5NbO3 nano-ceramics with nanodomains via a core–shell structural design. J Mater Chem C 2020, 8: 5248–5258.
Fan PY, Zhang ST, Xu JW, et al. Relaxor/antiferroelectric composites: A solution to achieve high energy storage performance in lead-free dielectric ceramics. J Mater Chem C 2020, 8: 5681–5691.
You D, Tan H, Yan ZL, et al. Enhanced dielectric energy storage performance of 0.45Na0.5Bi0.5TiO3–0.55Sr0.7Bi0.2TiO3/ AlN 0–3 type lead-free composite ceramics. ACS Appl Mater Interfaces 2022, 14: 17652–17661.
Li F, Hou X, Wang J, et al. Structure-design strategy of 0–3 type (Bi0.32Sr0.42Na0.20)TiO3/MgO composite to boost energy storage density, efficiency and charge–discharge performance. J Eur Ceram Soc 2019, 39: 2889–2898.
Tao CW, Geng XY, Zhang J, et al. Bi0.5Na0.5TiO3–BaTiO3–K0.5Na0.5NbO3:ZnO relaxor ferroelectric composites with high breakdown electric field and large energy storage properties. J Eur Ceram Soc 2018, 38: 4946–4952.
Zhang YM, Cao MH, Yao ZH, et al. Effects of silica coating on the microstructures and energy storage properties of BaTiO3 ceramics. Mater Res Bull 2015, 67: 70–76.
Huang YH, Wu YJ, Qiu WJ, et al. Enhanced energy storage density of Ba0.4Sr0.6TiO3–MgO composite prepared by spark plasma sintering. J Eur Ceram Soc 2015, 35: 1469–1476.
Yu Z, Zeng JT, Zheng LY, et al. Microstructure effects on the energy storage density in BiFeO3-based ferroelectric ceramics. Ceram Int 2021, 47: 12735–12741.
Ding JX, Liu YF, Lu YN, et al. Enhanced energy-storage properties of 0.89Bi0.5Na0.5TiO3–0.06BaTiO3–0.05K0.5Na0.5NbO3 lead-free anti-ferroelectric ceramics by two-step sintering method. Mater Lett 2014, 114: 107–110.
Huang J, Hou X, Gao SB, et al. Greatly enhanced energy storage and discharge properties of AgNbO3 ceramics with a stable antiferroelectric phase and high breakdown strength using hydrothermally synthesized powders. J Mater Chem A 2022, 10: 16337–16350.
Borkar H, Singh VN, Singh BP, et al. Room temperature lead-free relaxor-antiferroelectric electroceramics for energy storage applications. RSC Adv 2014, 4: 22840–22847.
Wang XC, Yang TQ, Shen J. High-energy storage performance in (Pb0.98La0.02)(Zr0.45Sn0.55)0.995O3 AFE thick films fabricated via a rolling process. J Am Ceram Soc 2016, 99: 3569–3572.
Su B, Button TW. A comparative study of viscous polymer processed ceramics based on aqueous and non-aqueous binder systems. J Mater Process Technol 2009, 209: 153–157.
Jiang J, Meng XJ, Li L, et al. Enhanced energy storage properties of lead-free NaNbO3-based ceramics via A/B-site substitution. Chem Eng J 2021, 422: 130130.
Li DX, 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.
Jo HR, Lynch CS. A high energy density relaxor antiferroelectric pulsed capacitor dielectric. J Appl Phys 2016, 119: 024104.
Liu Z, Lu T, Ye JM, et al. Antiferroelectrics for energy storage applications: A review. Adv Mater Technol 2018, 3: 1800111.
Pan WY, Zhang QM, Bhalla A, et al. Field-forced antiferroelectric-to-ferroelectric switching in modified lead zirconate titanate stannate ceramics. J Am Ceram Soc 1989, 72: 571–578.
Liu ZG, Li MD, Tang ZH, et al. Enhanced energy storage density and efficiency in lead-free Bi(Mg1/2Hf1/2)O3-modified BaTiO3 ceramics. Chem Eng J 2021, 418: 129379.
Cui T, Zhang J, Guo J, et al. Outstanding comprehensive energy storage performance in lead-free BiFeO3-based relaxor ferroelectric ceramics by multiple optimization design. Acta Mater 2022, 240: 118286.
Shrout TR, Zhang SJ. Lead-free piezoelectric ceramics: Alternatives for PZT? J Electroceram 2007, 19: 185.
Gao JH, Liu YB, 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.
Li B, Liu QX, Tang XG, et al. High energy storage density and impedance response of PLZT2/95/5 antiferroelectric ceramics. Materials 2017, 10: 143.
Qiao PX, Zhang YF, Chen XF, et al. Enhanced energy storage properties and stability in (Pb0.895La0.07)(ZrxTi1−x)O3 antiferroelectric ceramics. Ceram Int 2019, 45: 15898–15905.
Chen SC, Wang XC, Yang TQ, et al. Composition-dependent dielectric properties and energy storage performance of (Pb,La)(Zr,Sn,Ti)O3 antiferroelectric ceramics. J Electroceram 2014, 32: 307–310.
Wang XC, Shen J, Yang TQ, et al. High energy-storage performance and dielectric properties of antiferroelectric (Pb0.97La0.02)(Zr0.5Sn0.5−xTix)O3 ceramic. J Alloys Compd 2016, 655: 309–313.
Shen J, Wang XC, Yang TQ, et al. High discharge energy density and fast release speed of (Pb,La)(Zr,Sn,Ti)O3 antiferroelectric ceramics for pulsed capacitors. J Alloys Compd 2017, 721: 191–198.
Dan Y, Xu HJ, Zou KL, 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 XH, Li Y, Hao XH. 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.
Zhang QF, Tong HF, Chen J, et al. High recoverable energy density over a wide temperature range in Sr modified (Pb,La)(Zr,Sn,Ti)O3 antiferroelectric ceramics with an orthorhombic phase. Appl Phys Lett 2016, 109: 262901.
Dai XH, Xu Z, Li JF, et al. Effects of lanthanum modification on rhombohedral Pb(Zr1−xTix)O3 ceramics: Part II. Relaxor behavior versus enhanced antiferroelectric stability. J Mater Res 1996, 11: 626–638.
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.
Peláiz-Barranco A, Guerra JDS, García-Zaldívar O, et al. Effects of lanthanum modification on dielectric properties of Pb(Zr0.90,Ti0.10)O3 ceramics: Enhanced antiferroelectric stability. J Mater Sci 2008, 43: 6087–6093.
Zhuo FP, Li Q, Li YY, et al. Effect of A-site La3+ modified on dielectric and energy storage properties in lead zironate stannate titanate ceramics. Mater Res Express 2014, 1: 045501.
Liu Z, Bai Y, Chen XF, et al. Linear composition-dependent phase transition behavior and energy storage performance of tetragonal PLZST antiferroelectric ceramics. J Alloys Compd 2017, 691: 721–725.
Chen SC, Yang TQ, Wang JF, et al. Effects of glass additions on the dielectric properties and energy storage performance of Pb0.97La0.02(Zr0.56Sn0.35Ti0.09)O3 antiferroelectric ceramics. J Mater Sci-Mater El 2013, 24: 4764–4768.
Tian Y, Jin L, Zhang HF, et al. Phase transitions in bismuth-modified silver niobate ceramics for high power energy storage. J Mater Chem A 2017, 5: 17525–17531.
Tian Y, Jin L, Zhang HF, et al. High energy density in silver niobate ceramics. J Mater Chem A 2016, 4: 17279–17287.
Pawełczyk M. Phase transitions in AgTaxNb1−xO3 solid solutions. Phase Transit 1987, 8: 273–292.
Luo NN, Han K, Liu LJ, et al. Lead-free Ag1−3xLaxNbO3 antiferroelectric ceramics with high-energy storage density and efficiency. J Am Ceram Soc 2019, 102: 4640–4647.
Shi P, Wang XJ, Lou XJ, et al. Significantly enhanced energy storage properties of Nd3+ doped AgNbO3 lead-free antiferroelectric ceramics. J Alloys Compd 2021, 877: 160162.
Li S, Nie HC, Wang GS, et al. Significantly enhanced energy storage performance of rare-earth-modified silver niobate lead-free antiferroelectric ceramics via local chemical pressure tailoring. J Mater Chem C 2019, 7: 1551–1560.
Han K, Luo NN, Mao SF, et al. Realizing high low-electric-field energy storage performance in AgNbO3 ceramics by introducing relaxor behaviour. J Materiomics 2019, 5: 597–605.
Gao J, Zhang YC, 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.
Mao SF, Luo NN, Han K, et al. Effect of Lu doping on the structure, electrical properties and energy storage performance of AgNbO3 antiferroelectric ceramics. J Mater Sci-Mater El 2020, 31: 7731–7741.
Yang ZT, Gao F, Du HL, et al. Grain size engineered lead-free ceramics with both large energy storage density and ultrahigh mechanical properties. Nano Energy 2019, 58: 768–777.
Shao TQ, Du HL, Ma H, et al. Potassium-sodium niobate based lead-free ceramics: Novel electrical energy storage materials. J Mater Chem A 2017, 5: 554–563.
Tao H, Wu HJ, Liu Y, et al. Ultrahigh performance in lead-free piezoceramics utilizing a relaxor slush polar state with multiphase coexistence. J Am Chem Soc 2019, 141: 13987–13994.
Gao XL, Li Y, Chen JW, 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.
Wang DW, Fan ZM, Zhou D, et al. Bismuth ferrite-based lead-free ceramics and multilayers with high recoverable energy density. J Mater Chem A 2018, 6: 4133–4144.
Qi H, Zuo RZ, Xie AW, et al. Ultrahigh energy-storage density in NaNbO3-based lead-free relaxor antiferroelectric ceramics with nanoscale domains. Adv Funct Mater 2019, 29: 1903877.
Xu CH, Fu ZQ, Liu Z, et al. La/Mn codoped AgNbO3 lead-free antiferroelectric ceramics with large energy density and power density. ACS Sustainable Chem Eng 2018, 6: 16151–16159.
Gao J, Liu Q, Dong JF, et al. Local structure heterogeneity in Sm-doped AgNbO3 for improved energy-storage performance. ACS Appl Mater Interfaces 2020, 12: 6097–6104.
Yan ZN, Zhang D, Zhou XF, et al. Silver niobate based lead-free ceramics with high energy storage density. J Mater Chem A 2019, 7: 10702–10711.
Zhu XP, Gao YF, Shi P, et al. Ultrahigh energy storage density in (Bi0.5Na0.5)0.65Sr0.35TiO3-based lead-free relaxor ceramics with excellent temperature stability. Nano Energy 2022, 98: 107276.
Chu BJ, Zhou X, Ren KL, et al. A dielectric polymer with high electric energy density and fast discharge speed. Science 2006, 313: 334–336.
Love GR. Energy storage in ceramic dielectrics. J Am Ceram Soc 1990, 73: 323–328.
Shen Y, Zhang X, Li M, et al. Polymer nanocomposite dielectrics for electrical energy storage. Natl Sci Rev 2017, 4: 23–25.
Tanaka T, Greenwood A. Effects of charge injection and extraction on tree initiation in polyethylene. IEEE T Power Ap Syst 1978, PAS-97: 1749–1759.
Neudeck PG, Okojie RS, Chen LY. High-temperature electronics—A role for wide bandgap semiconductors? Proc IEEE 2002, 90: 1065–1076.
Dyalsingh HM, Kakalios J. Thermopower and conductivity activation energies in hydrogenated amorphous silicon. Phys Rev B 1996, 54: 7630–7633.
Li F, Jiang T, Zhai JW, et al. Exploring novel bismuth-based materials for energy storage applications. J Mater Chem C 2018, 6: 7976–7981.
Huang W, Chen Y, Li X, et al. Ultrahigh recoverable energy storage density and efficiency in barium strontium titanate-based lead-free relaxor ferroelectric ceramics. Appl Phys Lett 2018, 113: 203902.
Yang HB, Yan F, Lin Y, et al. Enhanced recoverable energy storage density and high efficiency of SrTiO3-based lead-free ceramics. Appl Phys Lett 2017, 111: 253903.
Yang HG, Qi H, Zuo RZ. Enhanced breakdown strength and energy storage density in a new BiFeO3-based ternary lead-free relaxor ferroelectric ceramic. J Eur Ceram Soc 2019, 39: 2673–2679.
Dai ZH, Li DY, Zhou ZJ, et al. A strategy for high performance of energy storage and transparency in KNN-based ferroelectric ceramics. Chem Eng J 2022, 427: 131959.
Wang T, Jin L, Li CC, et al. Relaxor ferroelectric BaTiO3–Bi(Mg2/3Nb1/3)O3 ceramics for energy storage application. J Am Ceram Soc 2015, 98: 559–566.
Xiong B, Hao H, Zhang SJ, et al. Structure, dielectric properties and temperature stability of BaTiO3–Bi(Mg1/2Ti1/2)O3 perovskite solid solutions. J Am Ceram Soc 2011, 94: 3412–3417.
Wu LW, Wang XH, Li LT. Lead-free BaTiO3–Bi(Zn2/3Nb1/3)O3 weakly coupled relaxor ferroelectric materials for energy storage. RSC Adv 2016, 6: 14273–14282.
Hu QY, Jin L, Wang T, et al. Dielectric and temperature stable energy storage properties of 0.88BaTiO3–0.12Bi(Mg1/2Ti1/2)O3 bulk ceramics. J Alloys Compd 2015, 640: 416–420.
Kong X, Yang LT, Cheng ZX, et al. Bi-modified SrTiO3-based ceramics for high-temperature energy storage applications. J Am Ceram Soc 2020, 103: 1722–1731.
Zhou MX, Liang RH, Zhou ZY, et al. Combining high energy efficiency and fast charge–discharge capability in novel BaTiO3-based relaxor ferroelectric ceramic for energy-storage. Ceram Int 2019, 45: 3582–3590.
Li WB, Zhou D, Liu WF, et al. High-temperature BaTiO3-based ternary dielectric multilayers for energy storage applications with high efficiency. Chem Eng J 2021, 414: 128760.
Dai ZH, Xie JL, Liu WG, et al. Effective strategy to achieve excellent energy storage properties in lead-free BaTiO3-based bulk ceramics. ACS Appl Mater Interfaces 2020, 12: 30289–30296.
Hu QY, Tian Y, Zhu QS, et al. Achieve ultrahigh energy storage performance in BaTiO3–Bi(Mg1/2Ti1/2)O3 relaxor ferroelectric ceramics via nano-scale polarization mismatch and reconstruction. Nano Energy 2020, 67: 104264.
Ji SS, Li QJ, Wang DD, et al. Enhanced energy storage performance and thermal stability in relaxor ferroelectric (1−x)BiFeO3–x(0.85BaTiO3–0.15Bi(Sn0.5Zn0.5)O3) ceramics. J Am Ceram Soc 2021, 104: 2646–2654.
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.
Sa TL, Qin N, Yang GW, et al. W-doping induced antiferroelectric to ferroelectric phase transition in PbZrO3 thin films prepared by chemical solution deposition. Appl Phys Lett 2013, 102: 172906.
Wang ZP, Zhang LX, Kang RR, et al. (Bi0.5Na0.5)TiO3-based relaxor ferroelectrics with enhanced energy-storage density and efficiency under low/moderate-fields via average ionic polarizability design. Chem Eng J 2022, 431: 133716.
Gao YF, Zhu XP, Yang B, et al. Grain size modulated (Na0.5Bi0.5)0.65Sr0.35TiO3-based ceramics with enhanced energy storage properties. Chem Eng J 2022, 433: 133584.
Zhang M, Yang HB, Li D, et al. Excellent energy density and power density achieved in K0.5Na0.5NbO3-based ceramics with high optical transparency. J Alloys Compd 2020, 829: 154565.
Prakash D, Sharma BP, Rama Mohan TR, et al. Flux additions in barium titanate: Overview and prospects. J Solid State Chem 2000, 155: 86–95.
Wu T, Pu YP, Chen K. Dielectric relaxation behavior and energy storage properties in Ba0.4Sr0.6Zr0.15Ti0.85O3 ceramics with glass additives. Ceram Int 2013, 39: 6787–6793.
Wu LW, Wang XH, Gong HL, 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.
Lee HY, Cho KH, Nam HD. Grain size and temperature dependence of electrical breakdown in BaTiO3 ceramic. Ferroelectrics 2006, 334: 165–169.
Wang HY, Cao MH, Tao C, et al. Tuning the microstructure of BaTiO3@FeO core–shell nanoparticles with low temperatures sintering dense nanocrystalline ceramics for high energy storage capability and stability. J Alloys Compd 2021, 864: 158644.
Wang HY, Cao MH, Huang R, et al. Preparation of BaTiO3@NiO core–shell nanoparticles with antiferroelectric-like characteristic and high energy storage capability. J Eur Ceram Soc 2021, 41: 4129–4137.
Chen LL, Wang HX, Zhao PY, et al. High permittivity and excellent high-temperature energy storage properties of X9R BaTiO3–(Bi0.5Na0.5)TiO3 ceramics. J Am Ceram Soc 2020, 103: 1113–1120.
Zhang XT, Zhao LL, Liu LW, et al. Interface and defect modulation via a core–shell design in (Na0.5Bi0.5TiO3@La2O3)–(SrSn0.2Ti0.8O3@La2O3)–Bi2O3–B2O3–SiO2 composite ceramics for wide-temperature energy storage capacitors. Chem Eng J 2022, 435: 135061.
Wu YC, Fan YZ, Liu NT, et al. Enhanced energy storage properties in sodium bismuth titanate-based ceramics for dielectric capacitor applications. J Mater Chem C 2019, 7: 6222–6230.
Xie JY, Yao MW, Gao WB, et al. Ultrahigh breakdown strength and energy density in PLZST@PBSAZM antiferroelectric ceramics based on core–shell structure. J Eur Ceram Soc 2019, 39: 1050–1056.
Bian F, Yan SG, Xu CH, 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.
Chu BJ, Lin MR, Neese B, et al. Large enhancement in polarization response and energy density of poly (vinylidene fluoride–trifluoroethylene–chlorofluoroethylene) by interface effect in nanocomposites. Appl Phys Lett 2007, 91: 122909.
Song Z, Liu HX, Hao H, et al. The effect of grain boundary on the energy storage properties of (Ba0.4Sr0.6M)TiO3 paraelectric ceramics by varying grain sizes. IEEE T Ultrason Ferr 2015, 62: 609–616.
Tunkasiri T, Rujijanagul G. Dielectric strength of fine grained barium titanate ceramics. J Mater Sci Lett 1996, 15: 1767–1769.
Beauchamp EK. Effect of microstructure on pulse electrical strength of MgO. J Am Ceram Soc 1971, 54: 484–487.
Liebault J, Vallayer J, Goueriot D, et al. How the trapping of charges can explain the dielectric breakdown performance of alumina ceramics. J Eur Ceram Soc 2001, 21: 389–397.
Chen IW, Wang XH. Sintering dense nanocrystalline ceramics without final-stage grain growth. Nature 2000, 404: 168–171.
Wang XZ, Huan Y, Zhao PY, et al. Optimizing the grain size and grain boundary morphology of (K,Na)NbO3-based ceramics: Paving the way for ultrahigh energy storage capacitors. J Materiomics 2021, 7: 780–789.
Yang ZT, Du HL, Jin L, et al. A new family of sodium niobate-based dielectrics for electrical energy storage applications. J Eur Ceram Soc 2019, 39: 2899–2907.
Peng HF, Fan ZX, Liang YF, et al. Mechanochemical synthesis of superionic conducting materials. Chin J Inorg Chem 2006, 22: 779–784. (in Chinese)
Arlt G, Hennings D, de With G. Dielectric properties of fine-grained barium titanate ceramics. J Appl Phys 1985, 58: 1619–1625.
Li JM, Wang FF, Qin XM, et al. Large electrostrictive strain in lead-free Bi0.5Na0.5TiO3–BaTiO3–KNbO3 ceramics. Appl Phys A 2011, 104: 117–122.
Tan SB, Liu EQ, Zhang QP, et al. Controlled hydrogenation of P(VDF-co-CTFE) to prepare P(VDF-co-TrFE-co-CTFE) in the presence of CuX (X = Cl, Br) complexes. Chem Commun 2011, 47: 4544–4546.
Xie AW, Qi H, Zuo RZ. Achieving remarkable amplification of energy-storage density in two-step sintered NaNbO3–SrTiO3 antiferroelectric capacitors through dual adjustment of local heterogeneity and grain scale. ACS Appl Mater Interfaces 2020, 12: 19467–19475.
Yan F, Bai HR, Ge GL, et al. Composition and structure optimized BiFeO3–SrTiO3 lead-free ceramics with ultrahigh energy storage performance. Small 2022, 18: 2106515.
Zhang L, Jiang SL, Fan BY, 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.
Ceja-Cárdenas L, Lemus-Ruíz J, Jaramillo-Vigueras D, et al. Spark plasma sintering of α-Si3N4 ceramics with Al2O3 and Y2O3 as additives and its morphology transformation. J Alloys Compd 2010, 501: 345–351.
Shim SH, Yoon JW, Shim KB, et al. Low temperature synthesis of the microwave dielectric Bi2O3–MgO–Nb2O5 nano powders by metal–citrate method. J Alloys Compd 2006, 415: 234–238.
Zhang GZ, Zhu DY, Zhang XS, 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 GZ, Chen M, Fan BY, et al. High electrocaloric effect in hot-pressed Pb0.85La0.1(Zr0.65Ti0.35)O3 ceramics with a wide operating temperature range. J Am Ceram Soc 2017, 100: 4581–4589.
Li F, Hou X, Li TY, et al. Fine-grain induced outstanding energy storage performance in novel Bi0.5K0.5TiO3–Ba(Mg1/3Nb2/3)O3 ceramics via a hot-pressing strategy. J Mater Chem C 2019, 7: 12127–12138.
Clavier N, Podor R, Dacheux N. Crystal chemistry of the monazite structure. J Eur Ceram Soc 2011, 31: 941–976.
Urek S, Drofenik M. The hydrothermal synthesis of BaTiO3 fine particles from hydroxide–alkoxide precursors. J Eur Ceram Soc 1998, 18: 279–286.
Wang XC, Cai WQ, Xiao Z, et al. High energy-storage performance of lead-free AgNbO3 antiferroelectric ceramics fabricated via a facile approach. J Eur Ceram Soc 2021, 41: 5163–5169.
Ren PR, Ren D, Sun L, et al. Grain size tailoring and enhanced energy storage properties of two-step sintered Nd3+-doped AgNbO3. J Eur Ceram Soc 2020, 40: 4495–4502.
Luo C, Zhu CH, Liang YH, et al. Promoting energy storage performance of Sr0.7Ba0.3Nb2O6 tetragonal tungsten bronze ceramic by a two-step sintering technique. ACS Appl Electron Mater 2022, 4: 452–460.
Jin Y, Wang JF, Jiang L, et al. Boosting up the capacitive energy storage performances of lead-free ceramics via grain engineering for pulse power applications. Ceram Int 2021, 47: 2869–2873.
Jain A, Wang YG, Guo H. Microstructure induced ultra-high energy storage density coupled with rapid discharge properties in lead-free Ba0.9Ca0.1Ti0.9Zr0.1O3–SrNb2O6 ceramics. Ceram Int 2021, 47: 487–499.
Luo NN, Han K, Zhuo FP, et al. Design for high energy storage density and temperature-insensitive lead-free antiferroelectric ceramics. J Mater Chem C 2019, 7: 4999–5008.
Li Y, Liu Y, Tang MY, et al. Energy storage performance of BaTiO3-based relaxor ferroelectric ceramics prepared through a two-step process. Chem Eng J 2021, 419: 129673.
Hong K, Lee TH, Suh JM, et al. Perspectives and challenges in multilayer ceramic capacitors for next generation electronics. J Mate Chem C 2019, 7: 9782–9802.
Wang HX, Zhao PY, Chen LL, 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.
Li F, Wang LH, Jin L, et al. Achieving single domain relaxor–PT crystals by high temperature poling. CrystEngComm 2014, 16: 2892–2897.
Li F, Jin L, Xu Z, et al. Electrostrictive effect in ferroelectrics: An alternative approach to improve piezoelectricity. Appl Phys Rev 2014, 1: 011103.
Chen LM, Sun NN, Li Y, et al. Multifunctional antiferroelectric MLCC with high-energy-storage properties and large field-induced strain. J Am Ceram Soc 2018, 101: 2313–2320.
Cai ZM, Wang HX, Zhao PY, et al. Significantly enhanced dielectric breakdown strength and energy density of multilayer ceramic capacitors with high efficiency by electrodes structure design. Appl Phys Lett 2019, 115: 023901.
Zhao PY, Wang HX, Wu LW, et al. High-performance relaxor ferroelectric materials for energy storage applications. Adv Energy Mater 2019, 9: 1803048.
Liu XH, Zhu JY, Li Y, et al. High-performance PbZrO3-based antiferroelectric multilayer capacitors based on multiple enhancement strategy. Chem Eng J 2022, 446: 136729.
Cai ZM, Zhu CQ, Wang HX, et al. High-temperature lead-free multilayer ceramic capacitors with ultrahigh energy density and efficiency fabricated via two-step sintering. J Mater Chem A 2019, 7: 14575–14582.
Wang HX, Zeng CY, Liu BB, et al. Energy storage properties of surface-modified BaTiO3 ceramic films for multilayer capacitors applications. J Adv Dielectr 2019, 9: 1950027.
Jiang SL, Zhang L, Zhang GZ, et al. Effect of Zr : Sn ratio in the lead lanthanum zirconate stannate titanate anti-ferroelectric ceramics on energy storage properties. Ceram Int 2013, 39: 5571–5575.
Xie AW, Zuo RZ, Qiao ZL, et al. NaNbO3–(Bi0.5Li0.5)TiO3 lead-free relaxor ferroelectric capacitors with superior energy-storage performances via multiple synergistic design. Adv Energy Mater 2021, 11: 2101378.
hang L, Jiang SL, Zeng YK, et al. Y doping and grain size co-effects on the electrical energy storage performance of (Pb0.87Ba0.1La0.02)(Zr0.65Sn0.3Ti0.05)O3 anti-ferroelectric ceramics. Ceram Int 2014, 40: 5455–5460.
Jiang ZH, Yang ZY, Yuan Y, et al. High energy storage properties and dielectric temperature stability of (1−x) (0.8Bi0.5Na0.5TiO3–0.2Ba3Sr0.4TiO3)–xNaNbO3 lead-free ceramics. J Alloys Compd 2021, 851: 156821.
Han K, Luo NN, Mao SF, et al. Ultrahigh energy-storage density in A-/B-site co-doped AgNbO3 lead-free antiferroelectric ceramics: Insight into the origin of antiferroelectricity. J Mater Chem A 2019, 7: 26293–26301.
Sun HN, Wang XJ, Sun QZ, et al. Large energy storage density in BiFeO3–BaTiO3–AgNbO3 lead-free relaxor ceramics. J Eur Ceram Soc 2020, 40: 2929–2935.
Yan F, Shi YJ, Zhou XF, et al. Optimization of polarization and electric field of bismuth ferrite-based ceramics for capacitor applications. Chem Eng J 2021, 417: 127945.
Wang G, Lu ZL, Li JL, et al. Lead-free (Ba,Sr)TiO3–BiFeO3 based multilayer ceramic capacitors with high energy density. J Eur Ceram Soc 2020, 40: 1779–1783.
Zhao Y, Meng XJ, Hao XH. Synergistically achieving ultrahigh energy-storage density and efficiency in linear-like lead-based multilayer ceramic capacitor. Scripta Mater 2021, 195: 113723.
Chao WN, Yang TQ, Li YX. Achieving high energy efficiency and energy density in PbHfO3-based antiferroelectric ceramics. J Mater Chem C 2020, 8: 17016–17024.
Zhang M, Yang HB, Yu YW, et al. Energy storage performance of K0.5Na0.5NbO3-based ceramics modified by Bi(Zn2/3(Nb0.85Ta0.15)1/3)O3. Chem Eng J 2021, 425: 131465.
Zuo CY, Yang SL, Cao ZQ, et al. Excellent energy storage and hardness performance of Sr0.7Bi0.2TiO3 ceramics fabricated by solution combustion-synthesized nanopowders. Chem Eng J 2022, 442: 136330.
Zhang M, Yang HB, Li D, et al. Giant energy storage efficiency and high recoverable energy storage density achieved in K0.5Na0.5NbO3–Bi(Zn0.5Zr0.5)O3 ceramics. J Mater Chem C 2020, 8: 8777–8785.
Sun CC, Chen XL, Shi JP, et al. Simultaneously with large energy density and high efficiency achieved in NaNbO3-based relaxor ferroelectric ceramics. J Eur Ceram Soc 2021, 41: 1891–1903.
Zhou MX, Liang RH, Zhou ZY, 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.
Li CW, Xiao YM, Fu TY, et al. High capacitive performance achieved in NaNbO3-based ceramics via grain refinement and relaxation enhancement. Energy Technol 2022, 10: 2100777.