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电子工业发展使多层陶瓷电容器的需求大增,为降低成本,适用于贱金属电极的介质陶瓷成为研究热点。选择MnO2掺杂0.95Ba Ti O3–0.05Bi Co O3陶瓷,经调整掺杂比例,其抗还原与介电性能大幅提升。结果表明:还原气氛下Mn离子变价使晶胞体积膨胀,形成不均匀结构使Curie峰分裂并展宽,介温稳定性提高,x=0.5时性能最佳,ε(25℃)=2354,tanδ=0.007 5,稳定性符合X8R。同时,元素变价的过程有助于降低电子浓度,电阻率提高至1.84×1013Ω·cm,最大耐压达到210 k V/cm。热激励退极化漏电流测试表明Co、Mn结合氧空位形成缺陷偶极,进一步增强抗还原性能。
Abstract:Introduction Multi-layer ceramic capacitor (MLCC) is a highly promising dielectric capacitor due to its high capacitance,favorable dielectric temperature stability,and high breakdown strength.The conventional MLCC uses expensive silver and palladium metals as inner electrode materials.In recent years,base metals such as nickel or copper are employed as inner electrodes to reduce the related costs.However,these metals must be co-fired with the dielectric layer in a reducing atmosphere.BaTiO3 ceramics are the principal dielectric materials used in the manufacture of MLCC.The sintering of Ba Ti O3 ceramics in a reducing atmosphere generates a significant number of oxygen vacancies and free electrons,which significantly impair the insulation performance and reduce the insulating properties.Also,the pronounced dielectric peak of BaTiO3 ceramics occurs at the elevated temperature end (i.e.,125℃),leading to an inadequate temperature stability.Recent research focus on the relaxation properties and dielectric properties of BaTiO3-Bi(Me)O3(Me=Fe3+,Co3+,Y3+,etc.) solid solutions.The co-substitution of the A and B sites via introducing cations with different ion radius and valence states is shown to disrupt the long-range ferroelectric ordering,induce diffusive phase transitions,and broaden the dielectric temperature profile.Furthermore,Zn2+,Mg2+,Mn4+,Co3+,and other rare-earth element ions are introduced into Ba Ti O3-based ceramics as host-accepted dopants with the objective of forming defective dipoles with oxygen vacancies,which can bind the free charge movement.Among these,multivalent ions can bind electrons,thereby modifying the valence and regulating the electron concentration within the ceramics.This reduces the likelihood of conversion of Ti4+to Ti3+.In this paper,0.95 BaTiO3-0.05Bi Co O3 dielectric ceramics were used as a matrix.A small amount of Mn O2 was selected for doping and modification,and subsequently sintered in a reducing atmosphere.The structure,micro-morphology,dielectric,and insulating properties were characterized,and the mechanism of anti-reduction was investigated.Methods In the preparation of the ceramics with a composition of 0.95 BaTiO3–0.05Bi Co O3–x%(in mass) MnO2 (x=0.1,0.2,0.3,0.4,and 0.5),the materials were sintered at 1275℃ for 2 h under a reducing atmosphere (99.5%N_2+0.5%H2,in volume fraction),forming dense ceramic samples.Subsequently,the ceramic samples were thinned and polished,and silver paste electrodes were applied to the both sides to measure their electrical properties.The physical structure of the samples was analyzed using a model X'Pert Pro X-ray diffractometer (XRD,PANalytical Co.,the Netherlands).The microscopic morphology of the sample section was determined by a model 450 FEG field emission scanning electron microscope (FE-SEM,FEI Quanta Co.,USA).The dielectric properties of the samples were measured by a model Poly K PK-CPT1705 low temperature dielectric tester.The resistivity of the ceramic samples was tested by a model Concept 80 low frequency module (Novocontrol Co.,Germany).The ferroelectric properties of the samples were analyzed by a model PK-CPE1801 ferroelectric polarisation return and dielectric breakdown test system (Poly K Co.,USA).The elemental valence analysis was conducted by a model 250Xi X-ray photoelectron spectrometer (XPS,Esca Lab Co.,USA).The thermally stimulated depolarization currents (TSDC) of the samples were carried out by a model Concept 80 TSDC (Novocontrol Co.,Germany).Results and discussion All the ceramic samples exhibit a pseudo-cubic perovskite structure.The crystal surface spacing of the ceramics increases as the amount of Mn O2 doping increases.This indicates that Mn4+is reduced to Mn3+or Mn2+during sintering in a reducing atmosphere.The radius of Mn3+or Mn2+is larger than that of Ti4+(i.e.,0.060 5 nm,CN=6) ionic radius,leading to the crystal lattice distortion and increased cell volume.The cross section of the ceramics reveals fine grains (i.e.,0.24–0.32μm),clear grain boundaries,and a close arrangement between grains.The change in valence of Mn effectively inhibits the concentration of free electrons.When x=0.5,the insulation resistivity increases to 1.84×1013Ω·cm,the breakdown voltage reaches 210 k V/cm,thus improving the anti-reduction performance of ceramics.The introduction of Mn reduces the dielectric loss of the ceramics and improves their dielectric temperature stability.The optimum dielectric properties are achieved when x=0.5 (i.e.,a dielectric constant of 2354,a dielectric loss of 0.0075,and ΔC/C(25℃)≤±15% at–55 to 154℃).The XPS spectra reveal the presence of both divalent and trivalent Co ions in the ceramics.The result of TSDC test shows a TSDC peak associated with trapped charge,which is related to the change in valence states of the variable valency acceptor ions Co and Mn.Two TSDC peaks are also related to defect dipoles,which are formed by Co and Mn with oxygen vacancies in the ceramic sample.Conclusions The effect of Mn O2 doping on the phase structure,microstructure,and electrical properties of 0.95BT–0.05BC ceramics was investigated.The results demonstrated that Mn4+ions underwent a conversion to Mn3+or Mn2+ions during sintering process in a reducing atmosphere,having the larger ionic radius.This transformation led to an expansion of the cell volume.Mn doping significantly impacted the broadening of the Curie peak and enhanced the dielectric temperature stability of 0.95BT–0.05BC ceramics.Specifically,as x=0.5,the dielectric constant at 25℃ was 2354,and the dielectric loss was 0.007 5.Furthermore,at–55 to 154℃,ΔC/C(25℃)≤±15%.The resistivity at room temperature increased to 1.84×1013Ω·cm,and the breakdown voltage increased to 210 k V/cm.The XPS spectra revealed the presence of both divalent and trivalent Co ions in the ceramic,indicating that Co ions could capture free electrons and reduce their valence state.The result of TSDC test further demonstrated the existence of two types of defective dipoles,which were associated with the acceptor substitution of Co and Mn.The combination of these two factors reduced the carrier concentration in the ceramics,thereby hindering the migration of oxygen vacancies and free electrons and improving the anti-reduction performance.
[1] ZHEN Y C, XIAO M J, CHENG X, et al. Defect control of Yb-doped dielectric ceramics on improving the reliability for MLCC application[J].Ceram Int, 2023, 49(8):12097–12104.
[2] ALKATHY M S, MILTON F P, GATASHEH M K, et al. Enhancing dielectric properties and thermal stability in microwave-synthesized Nd-modified Barium titanate nanoceramics for possible MLCC applications[J]. Appl Phys A, 2024, 130(6):402.
[3] YUILE A, WISS E, BARTH D, et al. Simulation of mechanical stresses in BaTiO3 multilayer ceramic capacitors during desoldering in the rework of electronic assemblies using a framework of computational fluid dynamics and thermomechanical models[J]. Materials, 2024,17(11):2702.
[4]李波,张树人,周晓华,等.纳米掺杂剂中Mn离子对BaTiO3基多层陶瓷电容器瓷料的影响[J].硅酸盐学报, 2006, 34(3):293–298.LI Bo, ZHANG Shuren, ZHOU Xiaohua, et al. J Chin Ceram Soc, 2006,34(3):293–298.
[5] SUZUKI S, YAMAGUCHI S, DOI A, et al. Effect of alloying Ni inner electrodes on the leakage current degradation of BaTiO3-based multilayer ceramic capacitors[J]. Appl Phys Lett, 2020, 116(13):132903.
[6] ZHANG J M, HAO Y N, LI H H, et al. Coating of crystalline BaTiO3layer on Ni nanoparticles for multilayer ceramic capacitor electrode[J].Adv Eng Mater, 2020, 22(10):1901483.
[7] LI Z Q, WANG J X, YAN S G, et al. Preparation of X5R type Ni-MLCCs and capacitance response to combined out-field variations[J].Ceram Int, 2023, 49(11):17766–17775.
[8] HUANG X, WANG P F, ZHAO J W, et al. Significantly enhanced dielectric properties of BaTiO3-based ceramics via synergetic grain size and defect engineering[J]. Ceram Int, 2024, 50(9):15202–15208.
[9] XU H F, WANG P F, LUAN S W, et al. Vacancy engineering for high tetragonal BaTiO3 synthesized by solid-state approaches[J]. Powder Technol, 2024, 444:119955.
[10] LIU Q, HAO H, GUO Q H, et al. Enhanced breakdown strength of Ba Ti O3-based multilayer ceramic capacitor by structural optimization[J].Rare Met, 2023, 42(8):2552–2561.
[11] WANG M L, XUE K Y, ZHANG K, et al. Dielectric properties of BaTiO3-based ceramics are tuned by defect dipoles and oxygen vacancies under a reducing atmosphere[J]. Ceram Int, 2022, 48(15):22212–22220.
[12] XU K, ZHU G S, XU H R, et al. The colossal permittivity effect on BaTiO3 induced by different sinter atmosphere[J]. Appl Phys A, 2022,128(12):1044.
[13] MURAKAMI S, AHMED N T A F, WANG D W, et al. Optimising dopants and properties in Bi MeO3(Me=Al, Ga, Sc, Y, Mg2/3Nb1/3,Zn2/3Nb1/3, Zn1/2Ti1/2)lead-free BaTiO3–BiFeO3 based ceramics for actuator applications[J]. J Eur Ceram Soc, 2018, 38(12):4220–4231.
[14] LUO Z P, HAO H, CHEN C, et al. Dielectric and anti-reduction properties of(1–x)BaTiO3–x Bi(Zn0.5Y0.5)O2.75 ceramics for BMEMLCC application[J]. J Alloys Compd, 2019, 794:358–364.
[15] ZHANG J, HAO H, GUO Q H, et al. Dielectric and anti-reduction properties of BaTiO3-based ceramics for MLCC application[J]. Ceram Int, 2023, 49(15):24941–24947.
[16] LI D, GUO Q, CAO M, et al. The influence of A/B-sites doping on antiferroelectricity of PZO energy storage films[J]. Microstructures,2023, 3(1):2023007.
[17]王鑫,郝华,李东旭,等. Sr0.7Bi0.2TiO3改性Bi0.5Na0.5TiO3基薄膜电储能特性的优化[J].硅酸盐学报, 2024, 52(4):1374–1383.WANG Xin, HAO Hua, LI Dongxu, et al. J Chin Ceram Soc, 2024,52(4):1374–1383.
[18] WANG Z, HAO H, PENG F, et al. Defect evolution and effect on structure and electric properties of A/B site Sm doped BaTiO3 sintered in different atmospheres[J]. J Alloys Compd, 2023, 945:169211.
[19] WANG X H, CHEN R Z, ZHOU H, et al. Dielectric properties of BaTiO3-based ceramics sintered in reducing atmospheres prepared from nano-powders[J]. Ceram Int, 2004, 30(7):1895–1898.
[20]黄咏安,路标,唐振华,等.化学包覆法制备Ho3+掺杂钛酸钡基X8R细晶陶瓷[J].硅酸盐学报, 2017, 45(9):1265–1270.HUANG Yongan, LU Biao, TANG Zhenhua, et al. J Chin Ceram Soc,2017, 45(9):1265–1270.
[21]李波,周晓华,张树人.稀土掺杂对还原烧结钛酸钡陶瓷微结构和电性能的影响[J].硅酸盐学报, 2008, 36(3):277–282.LI Bo, ZHOU Xiaohua, ZHANG Shuren. J Chin Ceram Soc, 2008,36(3):277–282.
[22] SASIKUMAR S, RAJARAM M, NATARAJAN A, et al. Architecting B-site Ni doped BaTiO3 photocatalyst for environmental remediation:Enhanced photodegradation performance[J]. Mater Sci Semicond Process, 2024, 174:108222.
[23] ZHANG F, TAN J H, WANG P F, et al. Defect dipole engineering enhanced the dielectric performance and reliability of Mn-doped BaTiO3-based multilayer ceramic capacitor[J]. Ceram Int, 2024, 50(20):38263–38273.
[24] ZHANG Z R, HUANG X, YANG J, et al. Investigation of coherent interface on relaxation behavior and reliability of Mg-doped BaTiO3dielectric ceramics:Experiments and first-principle calculations[J]. J Eur Ceram Soc, 2024, 44(13):7630–7641.
[25]樊慧庆,张培凤.镁掺杂钛酸钡陶瓷的固相法制备及介电性能[J].硅酸盐学报, 2010, 38(8):1379–1382.FAN Huiqing, ZHANG Peifeng. J Chin Ceram Soc, 2010, 38(8):1379–1382.
[26] XUE K Y, XIE J L, WANG M L, et al. Defect structure and dielectric properties of Mn-doped X8R BaTiO3-based ceramics with high permittivity:Experiments and first-principle calculations[J]. Ceram Int,2023, 49(11):16514–16523.
[27] SHEN Z B, WANG X H, GONG H L, et al. Effect of MnO2 on the electrical and dielectric properties of Y-doped Ba0.95Ca0.05Ti0.85Zr0.15O3ceramics in reducing atmosphere[J]. Ceram Int, 2014, 40(9):13833–13839.
[28] ZHU H, LI K, CHEN M L, et al. A melamine formaldehyderesin route to in situ encapsulate Co2O3 into carbon black for enhanced oxygen reduction in alkaline media[J]. Int J Hydrog Energy, 2017, 42(41):25960–25968.
[29] SOMPALLI N K, LI Y, LI J, et al. An innovative triple interface reinforced photocatalytic system based on BiOCl/BaTiO3@Co-BDC-MOF composite for the simultaneous detoxification of Cr(VI)and sulfamethoxazole[J]. Environ Res, 2024, 259:119532.
[30] GU Y, ZHANG F Q, WU W H, et al. Microstructure regulation and failure mechanism study of BaTiO3-based dielectrics for MLCC application[J]. J Adv Dielect, 2023, 13(2):2350002.
[31] SONG H, GOUD J P, YE J, et al. Review of the thermally stimulated depolarization current(TSDC)technique for characterizing dielectric materials[J]. J Korean Ceram Soc, 2023, 60(5):747–759.
[32] BISHOP S, BLEA M, PERETTI A, et al. Oxygen vacancy migration and impact on high voltage DC polarization in BaTiO3–Bi(Zn,Ti)O3[C]//ACerS EMA 2023-Orlando, Florida, United States of America-January-2023. US DOE, 2023:6192–6203.
基本信息:
DOI:10.14062/j.issn.0454-5648.20240752
中图分类号:TM534.1
引用信息:
[1]王震,郝华,蒋松松,等.用于多层陶瓷电容器的抗还原BaTiO_3基介质陶瓷[J].硅酸盐学报,2025,53(04):808-815.DOI:10.14062/j.issn.0454-5648.20240752.
基金信息:
国家重点研发计划项目(2023YFB3812200); 国家自然科学基金(52472135); 广东省基础与应用基础研究基金区域联合基金重点项目(2022B1515120041)
2025-02-20
2025-02-20
2025-02-20