LEADER 05501nam  2200697Ia 450 
001 9910139751103321
005 20170815110107.0
010   $a1-5231-1553-X
010   $a1-282-27995-5
010   $a9786612279959
010   $a0-470-45151-3
010   $a0-470-45150-5
035   $a(CKB)1000000000790468
035   $a(EBL)455844
035   $a(OCoLC)466446624
035   $a(SSID)ssj0000354439
035   $a(PQKBManifestationID)11264321
035   $a(PQKBTitleCode)TC0000354439
035   $a(PQKBWorkID)10302642
035   $a(PQKB)10401161
035   $a(MiAaPQ)EBC455844
035   $a(PPN)186179014
035   $a(EXLCZ)991000000000790468
100   $a20081119d2009      uy             0
101 0 $aeng
135   $aur|n|---|||||
181   $ctxt
182   $cc
183   $acr
200 10$aMechanical properties of ceramics$b[electronic resource] /$fJohn B. Wachtman
205   $a2nd ed.
210   $aHoboken, N.J. $cWiley$dc2009
215   $a1 online resource (497 p.)
300   $aDescription based upon print version of record.
311   $a0-471-73581-7 
320   $aIncludes bibliographical references and index.
327   $aMECHANICAL PROPERTIES OF CERAMICS; CONTENTS; Preface; Acknowledgments; 1 Stress and Strain; 1.1 Introduction; 1.2 Tensor Notation for Stress; 1.3 Stress in Rotated Coordinate System; 1.4 Principal Stress; 1.4.1 Principal Stresses in Three Dimensions; 1.5 Stress Invariants; 1.6 Stress Deviator; 1.7 Strain; 1.8 True Stress and True Strain; 1.8.1 True Strain; 1.8.2 True Stress; Problems; 2 Types of Mechanical Behavior; 2.1 Introduction; 2.2 Elasticity and Brittle Fracture; 2.3 Permanent Deformation; 3 Elasticity; 3.1 Introduction; 3.2 Elasticity of Isotropic Bodies
327   $a3.3 Reduced Notation for Stresses, Strains, and Elastic Constants3.4 Effect of Symmetry on Elastic Constants; 3.5 Orientation Dependence of Elastic Moduli in Single Crystals and Composites; 3.6 Values of Polycrystalline Moduli in Terms of Single-Crystal Constants; 3.7 Variation of Elastic Constants with Lattice Parameter; 3.8 Variation of Elastic Constants with Temperature; 3.9 Elastic Properties of Porous Ceramics; 3.10 Stored Elastic Energy; Problems; 4 Strength of Defect-Free Solids; 4.1 Introduction; 4.2 Theoretical Strength in Tension; 4.3 Theoretical Strength in Shear; Problems
327   $a5 Linear Elastic Fracture Mechanics5.1 Introduction; 5.2 Stress Concentrations; 5.3 Griffith Theory of Fracture of a Brittle Solid; 5.4 Stress at Crack Tip: An Estimate; 5.5 Crack Shape in Brittle Solids; 5.6 Irwin Formulation of Fracture Mechanics: Stress Intensity Factor; 5.7 Irwin Formulation of Fracture Mechanics: Energy Release Rate; 5.7.1 Relationship between G and K(I); 5.8 Some Useful Stress Intensity Factors; 5.9 The J Integral; 5.10 Cracks with Internal Loading; 5.11 Failure under Multiaxial Stress; Problems; 6 Measurements of Elasticity, Strength, and Fracture Toughness
327   $a6.1 Introduction6.2 Tensile Tests; 6.3 Flexure Tests; 6.3.1 Three-Point Bending; 6.3.2 Four-Point Bending; 6.3.3 Fracture Toughness Measurement by Bending; 6.4 Double-Cantilever-Beam Test; 6.5 Double-Torsion Test; 6.6 Indentation Test; 6.6.1 Direct Method; 6.6.2 Indirect Method; 6.6.3 Modified Method; 6.6.4 Summary of the Three Methods; 6.6.5 ASTM Standard C 1421 Method; 6.7 Biaxial Flexure Testing; 6.8 Elastic Constant Determination Using Vibrational and Ultrasonic Methods; Problems; 7 Statistical Treatment of Strength; 7.1 Introduction; 7.2 Statistical Distributions
327   $a7.3 Strength Distribution Functions7.3.1 Gaussian, or Normal, Distribution; 7.3.2 Weibull Distribution; 7.3.3 Comparison of the Normal and Weibull Distributions; 7.4 Weakest Link Theory; 7.5 Determining Weibull Parameters; 7.6 Effect of Specimen Size; 7.7 Adaptation to Bend Testing; 7.8 Safety Factors; 7.9 Example of Safe Stress Calculation; 7.10 Proof Testing; 7.11 Use of Pooled Fracture Data in Linear Regression Determination of Weibull Parameters; 7.12 Method of Maximum Likelihood in Weibull Parameter Estimation; 7.13 Statistics of Failure under Multiaxial Stress
327   $a7.14 Effects of Slow Crack Propagation and R-Curve Behavior on Statistical Distributions of Strength
330   $aA Comprehensive and Self-Contained Treatment of the Theory and Practical Applications of Ceramic Materials When failure occurs in ceramic materials, it is often catastrophic, instantaneous, and total. Now in its Second Edition, this important book arms readers with a thorough and accurate understanding of the causes of these failures and how to design ceramics for failure avoidance. It systematically covers: Stress and strain Types of mechanical behavior Strength of defect-free solids Linear elastic fracture mechanics Measurements of elasticity, stren
606   $aCeramic materials$xMechanical properties
606   $aCeramic materials$xElectric properties
615  0$aCeramic materials$xMechanical properties.
615  0$aCeramic materials$xElectric properties.
676   $a620.1/40492
676   $a620.140492
686   $aUQ 8500$2rvk
686   $aZM 6100$2rvk
700   $aWachtman$b J. B.$f1928-$0621925
701   $aCannon$b W. Roger$0771037
701   $aMatthewson$b M. John$0771038
801  0$bMiAaPQ
801  1$bMiAaPQ
801  2$bMiAaPQ
906   $aBOOK
912   $a9910139751103321
996   $aMechanical properties of ceramics$92131975
997   $aUNINA