金屬氧化物壓敏電阻—從微觀結構到巨觀特性(Metal Oxide Varistors-F

金屬氧化物壓敏電阻是電力和電子系統的關鍵保護器件，直接決定系統運行的安全可靠性。本書系統介紹了氧化鋅等壓敏電阻的基礎研究、製備工藝、性能調控及套用進展，包括導電及老化機理、微結構電特性、微結構測試及微結構仿真分析、高梯度低殘壓氧化壓敏陶瓷、氧化鈦及氧化錫等其他體系壓敏陶瓷的研究進展等，構建了壓敏電阻微結構特性與巨觀特性之間的關聯性。

本書可供高校和科研院所電氣工程、微電子、材料等專業的師生以及電力傳輸、電氣設備製造等行業的工程技術人員閱讀和參考。

1 Introduction of Varistor Ceramics 1

1.1 ZnOVaristors 1

1.2 FabricationofZnOVaristors 3

1.2.1 PreparationofRawMaterials 4

1.2.2 SinteringofZnOVaristors 5

1.3 Microstructure 6

1.4 TypicalParametersofZnOVaristors 7

1.5 HistoryofZnOVaristors 9

1.6 ApplicationsofZnOVaristors 12

1.7 AlternativeVaristorCeramics 17

1.8 Ceramic–PolymerCompositeVaristors 18 References 22

2 Conduction Mechanisms of ZnO Varistors 31

2.1 Introduction 31

2.2 BasicConceptsinSolid-StatePhysics 33

2.2.1 AtomicEnergyLevelandEnergyBandofCrystal 33

2.2.2 Metal,Semiconductor,andInsulator 35

2.2.3 CharacteristicsofFermi–DiracFunction 37

2.2.4 ImpurityandDefectEnergyLevel 38

2.3 EnergyBandStructureofaZnOVaristor 39

2.3.1 EnergyBandStructureofaZnOGrain 39

2.3.2 DSBofaZnOVaristor 40

2.3.3 MicroscopicOriginofDSB 41

2.3.4 Asymmetric I–V CharacteristicsoftheDSB 43

2.4 ConductionMechanismofaZnOVaristor 45

2.4.1 ConductionModelBasedonThermionicEmissionProcess 46

2.4.2 MinorityCarrierGenerationProcess 49

2.4.3 TheBypassE?ectModel 51

2.5 DielectricCharacteristicsofaZnOVaristor 51

2.5.1 ExplanationtoDielectricPropertiesofaZnOVaristor 52

2.5.2 E?ectofInterfacialChargeRelaxationonConductingBehaviorofZnOVaristorsUnderTime-VaryingElectricFields 54

2.5.3 DeterminationofBarrierHeightandRelatedParameters 58

2.5.4 DeterminationofDeepDonorLevelintheZnOVaristor 59

2.5.5 DeterminationofGrainandGrainBoundaryConductivity 60 References 62

3 Tuning Electrical Characteristics of ZnO Varistors 67

3.1 Introduction 67

3.2 Liquid-PhaseFabrication 68

3.2.1 MicrostructureofZnOVaristor 68

3.2.2 PolymorphofBismuthOxide 71

3.2.3 In?uenceofBi2O3Concentration 72

3.2.4 VolatilizationofBismuthOxide 72

3.3 PreparingandSinteringTechniques 74

3.3.1 Fabrication 74

3.3.2 FabricationStages 75

3.3.3 E?ectofPores 76

3.4 RoleofOxygenattheGrainBoundary 78

3.5 DopantE?ects 79

3.5.1 E?ectsofAdditives 79

3.5.2 DonorDopants 82

3.5.3 AcceptorDopants 86

3.5.4 AmphotericDopants 87

3.5.4.1 MonovalentDopants 88

3.5.4.2 TrivalentDopants 89

3.5.5 E?ectsofRareEarthOxides 92

3.5.6 DopantsforImprovingtheStability 93

3.5.7 EvidenceforHydrogenasaShallowDonor 95

3.6 RoleofInversionBoundaries 95

3.7 HighVoltageGradientZnOVaristor 98

3.8 LowResidualVoltageZnOVaristor 101

3.8.1 ResidualVoltageRatio 101

3.8.2 LowResidualVoltageZnOVaristorsbyDopingAl 103

3.8.3 LowResidualVoltageZnOVaristorsbyDopingGa 106

3.8.4 LowResidualVoltageZnOVaristorswithHighVoltageGradient 108 References 110

4 Microstructural Electrical Characteristics of ZnO Varistors 125

4.1 Introduction 125

4.2 MethodstoDetermineGrainBoundaryParameters 126

4.2.1 TheIndirectMethod 126

4.2.2 TheDirectMicrocontactMethods 126

4.3 StatisticalCharacteristicsofGrainBoundaryParameters 129

4.3.1 NonuniformityofBarrierVoltages 129

4.3.2 DistributionofBarrierVoltage 131

4.3.3 DistributionofNonlinearCoe?cient 132

Contents

4.3.4 DistributionofLeakageCurrentThroughGrainBoundary 133

4.3.5 DiscussiononMicrocontactMeasurement 133

4.4 Classi?cationofGrainBoundaries 134

4.5 OtherTechniquestoDetectMicrostructurallyElectricalPropertiesofZnOVaristors 137

4.5.1 ScanningProbeMicroscopy-BasedTechniques 137

4.5.2 GalvanicDeterminationofConductiveAreasonaVaristor Surface 139

4.5.3 LineScanDeterminationofDi?erencesinBreakdownVoltageWithinaVaristor 141

4.5.4 CurrentImagesinSEM 141

4.6 TestonFabricatedIndividualGrainBoundary 142

4.6.1 ThinFilmApproach 143

4.6.2 SurfaceIn-Di?usionApproach 143

4.6.3 BicrystalApproach 143 References 145

5 Simulation on Varistor Ceramics 149

5.1 Introduction 149

5.2 GrainBoundaryModel 151

5.2.1 I–V CharacteristicModelofGrainBoundary 151

5.2.2 GBModelConsideringConductionMechanism 154

5.3 SimulationModelof I–V Characteristics 159

5.3.1 Simple2DSimulationModel 159

5.3.2 2DSimulationModelsBasedontheVoronoiNetwork 161

5.3.3 ConsiderationonPoresandSpinels 164

5.3.4 AlgorithmtoSolveEquivalentCircuit 165

5.3.5 ModelVeri?cation 169

5.4 SimulationModelforThermalCharacteristics 170

5.4.1 ThermalConductionAnalysis 171

5.4.2 Pulse-InducedFractureAnalysis 173

5.5 SimulationsonDi?erentPhenomena 174

5.5.1 SimulationonMicrostructuralNonuniformity 174

5.5.2 SimulationonCurrentLocalizationPhenomenon 175

5.5.3 In?uenceofMicrostructuralParametersonBulkCharacteristics 179

5.5.3.1 In?uenceofZnOGrainParameters 180

5.5.3.2 In?uenceofGrainBoundaryParameters 183

5.5.4 In?uentialFactorsonResidualVoltageRatio 186 References 188

6 Breakdown Mechanism and Energy Absorption Capability of ZnO Varistor 193

6.1 Introduction 193

6.2 ImpulseFailureModesofZnOVaristors 194

6.3 MechanismsofPunctureandFractureFailures 197

6.3.1 MechanismsofPunctureFailure 197

6.3.2 MechanismofFractureFailure 201

6.4 SimulationofPunctureandFractureFailures 204

6.4.1 PunctureDestructionSimulation 204

6.4.1.1 PunctureSimulationinMicrostructure 206

6.4.2 CrackingFailureSimulationinMicrostructure 208

6.5 Thermal Runaway 209

6.5.1 PowerLossofZnOVaristor 210

6.5.2 ThermalRunawayMechanism 210

6.5.3 TeststoEnsuretheThermalStabilityCharacteristics 213

6.6 In?uencesofDi?erentFactorsonFailuresofZnOVaristors 213

6.6.1 In?uenceofMicrostructuralNonuniformity 213

6.6.2 In?uenceofElectricalNonuniformityinMicrostructure 216

6.6.3 SimulationAnalysisonBreakdownModes 217

6.7 In?uentialFactorsonEnergyAbsorptionCapability 218

6.7.1 In?uenceoftheAppliedCurrent 218

6.7.2 In?uenceofVaristorCross-sectionalArea 221

6.7.3 SimulationAnalysisonSurgeEnergyAbsorptionCapability 221

6.8 DiscussionsonEnergyAbsorptionCapability 225

6.8.1 EnergyAbsorptionCapabilityDeterminedbyFractureFailure 225

6.8.2 EnergyAbsorptionCapabilityDeterminedbyPunctureFailure 226

6.8.3 DiscussiononNonuniformityofEnergyAbsorptionCapability 228

6.8.4 AdditivesE?ectonEnergyAbsorptionCapability 229

6.8.5 OtherMeasurestoImproveEnergyAbsorptionCapability 230 References 230

7 Electrical Degradation of ZnO Varistors 235

7.1 Introduction 235

7.2 DegradationPhenomenaofZnOVaristors 237

7.2.1 DegradationPhenomenaoftheVaristorBulk 237

7.2.2 DegradationofGrainBoundary 242

7.2.3 PulseDegradationCharacteristics 245

7.2.4 TopographicInformationforDegradationAnalysis 247

7.3 MigrationIonsfortheDegradationofZnOVaristors 249

7.3.1 GrainBoundaryDefectModel 249

7.3.2 ExperimentalProofofIonMigration 251

7.3.3 Identi?cationofDominantMobileIons 252

7.3.4 Three-DimensionalExtension 256

7.4 DegradationMechanismofZnOVaristors 257

7.4.1 DCDegradationMechanism 258

7.4.2 ACDegradationMechanism 258

7.4.3 NonuniformDegradationMechanism 260

7.4.4 PulseDegradationofZnOVaristors 262

7.4.4.1 DegradationMechanismUnderImpulseCurrent 263

7.4.4.2 SuperimposingDegradation 264

7.5 RoleofInteriorMicrocracksonDegradation 266

7.6 AntidegradationMeasures 267

7.6.1 Speci?cPreparationProcedures 268

7.6.2 OptimizationofFormula 269

Contents

7.6.2.1 DopantE?ectsonImprovingACDegradationCharacteristics 270

7.6.2.2 DopantE?ectsonImprovingImpulseDegradationProperty 271 References 272

8 Praseodymium/Vanadium/Barium-Based ZnO Varistor Systems 281

8.1 PraseodymiumSystem 281

8.1.1 DopingE?ects 281

8.1.2 E?ectofSinteringProcesses 285

8.1.3 High-VoltageApplications 288

8.1.4 Low-VoltageApplications 288

8.2 VanadiumSystem 289

8.2.1 DopingE?ects 290

8.2.2 ElectricalCharacteristics 291

8.2.3 MicrostructuralCharacteristics 292

8.2.4 E?ectsofVanadiumOxideonGrainGrowth 294

8.3 BariumSystem 295

8.3.1 PreparationandElectricalCharacteristics 295

8.3.2 MicrostructuralCharacteristics 296

8.3.3 ImprovingStabilityAgainstMoisture 298

8.4 ZnO–GlassVaristor 298 References 300

9 Fabrications of Low-Voltage ZnO Varistors 307

9.1 Introduction 307

9.2 ExaggeratingGrainGrowthbySeedGrains 308

9.3 SynthesisofNanocrystallineZnOVaristorPowders 309

9.3.1 Gas-PhaseProcessingMethods 309

9.3.2 CombustionSynthesis 311

9.3.3 Sol–GelMethods 311

9.3.4 Solution-CoatingMethod 315

9.4 Nano?llersinZnOVaristorCeramics 320

9.5 SinteringTechniquestoControlGrainGrowth 321

9.5.1 Step-sinteringApproach 321

9.5.2 MicrowaveSinteringMethod 322

9.5.3 SparkPlasmaSinteringTechnique 324 References 327

10 Titanium-Based Dual-function Varistor Ceramics 335

10.1 SrTiO3 Varistors 335

10.1.1 Introduction 335

10.1.2 MicrostructureofSrTiO3Varistors 336

10.1.3 PreparationofSrTiO3Varistors 336

10.1.4 PerformanceofSrTiO3 338

10.1.5 ConductionMechanismofSrTiO3 339

10.2 TiO2-BasedVaristors 341

10.2.1 Introduction 341

10.2.2 PreparationofTiO2-BasedVaristors 342

10.2.3 MechanismofTiO2Capacitor–VaristorCeramics 342

10.2.4 DopingofTiO2-BasedVaristors 343

10.2.4.1 Acceptor-DopedTiO2-BasedVaristors 343

10.2.4.2 Donor-DopedTiO2-BasedVaristors 344

10.2.4.3 CodopingE?ectsofAcceptorandDonorDopants 345

10.2.4.4 SinteringAdditivesinTiO2-BasedVaristors 347

10.2.5 DevelopmentofTiO2-BasedVaristors 348

10.3 CaCu3Ti4O12 Ceramics 348

10.3.1 Introduction 348

10.3.2 StructureofCCTO 349

10.3.2.1 CrystalStructure 349

10.3.2.2 PhaseandMicrostructure 350

10.3.3 PerformancesofCCTOCeramics 352

10.3.3.1 NonohmicCurrent–VoltageCharacteristic 352

10.3.3.2 ColossalPermittivity 354

10.3.3.3 DielectricLoss 357

10.3.4 Mechanism 358

10.3.4.1 IBLCModel 358

10.3.4.2 ConductingMechanism 362

10.3.4.3 PolarizationMechanismofGrains 364

10.3.4.4 APolaronicStackingFaultDefectModel 365

10.3.5 RoleofDopants 366

10.3.5.1 RoleofDopingCuO 366

10.3.5.2 DopingMechanismstoTuneCCTOPerformances 368

10.4 BaTiO3VaristorsofPTCRE?ect 375

10.4.1 Introduction 375

10.4.2 DopingE?ects 377

10.4.3 PreparationofBaTiO3Ceramics 379

10.4.4 PTCRE?ectofBaTiO3Ceramics 381

10.4.5 VaristorCharacteristicsofBaTiO3Ceramics 384 References 386

11 Tin Oxide Varistor Ceramics of High Thermal Conductivity 407

11.1 PreparationofSnO2-BasedVaristors 407

11.2 ElectricalPerformancesofSnO2-BasedVaristors 410

11.3 MechanismofSnO2-BasedVaristors 414

11.3.1 FormationofGrainBoundaryPotentialBarrier 414

11.3.2 AtomicDefectModel 415

11.3.3 AdmittanceSpectroscopyAnalysis 417

11.3.4 Capacitance–VoltageAnalysis 420

11.3.5 E?ectofThermalTreatment 421

11.4 RoleofDopantsinTuningSnO2-BasedVaristors 423

11.4.1 DopantsforDensifyingSnO2-BasedVaristors 423

11.4.2 AcceptorDoping 424

Contents

11.4.3 DonorDoping 427

11.5 ThermalPerformances 429

11.6 DegradationBehaviors 431

11.7 DevelopmentofSnO2-BasedVaristors 432 References 434

12 WO3-Based Varistor Ceramics of Low Breakdown Voltage 441

12.1 Introduction 441

12.2 TungstenOxide 442

12.3 PreparationofWO3-BasedVaristors 444

12.4 ElectricalPerformances 446

12.5 ImprovingtheElectricalStability 448

12.6 MechanismModelofWO3-BasedVaristors 449

12.7 DopingE?ects 452

12.7.1 TheAdditionofRareEarthOxides 452

12.7.2 TheAdditionofCuO 453

12.7.3 TheAdditionofAl2O3 454

12.7.4 TheAdditionofTiO2 455

12.7.5 TheAdditionofOtherAdditives 455 References 456

Index 461