LEADER 01098nam a2200277 i 4500
001 991001753909707536
008 060711s1997    enka     b    001 0 eng d
020   $a1859961002
035   $ab13422029-39ule_inst
040   $aDip.to Biologia$beng
082 0 $a572.63$221
100 1 $aBrooks, S. A.$0623959
245 10$aLectin histochemistry :$ba concise practical handbook /$cS. A. Brooks, A. J. C. Leathem, U. Schumacher
260 3 $aOxford :$bBIOS Scientific in association with the Royal Microscopical Society,$c1997
300   $axiii, 177 p. :$bill. ;$c24 cm
440  0$aMicroscopy handbooks ;$v36
504   $aIncludes bibliographical references and index
650  0$aHistochemistry$xTechnique
700 1 $aLeathem, A. J. C.
700 1 $aSchumacher, Udo
907   $a.b13422029$b11-10-11$c11-07-06
912   $a991001753909707536
945   $aLE003 572.6 BRO02.01 (1997)$g1$i2003000077032$lle003$o-$pE0.00$q-$rl$s-  $t0$u1$v12$w1$x0$y.i14265229$z11-07-06
996   $aLectin histochemistry$91097213
997   $aUNISALENTO
998   $ale003$b11-07-06$cm$da  $e-$feng$genk$h0$i0

LEADER 00888nam0 22002651i 450 
001 RML0256421
005 20231121125715.0
010   $a8814010498
100   $a20121121d1987    ||||0itac50      ba
101 | $aita
102   $ait
181  1$6z01$ai $bxxxe  
182  1$6z01$an
200 1 $a˜Il œcodice civile$ecommentario
210   $aMilano $cGiuffre' $d1987
606   $aDiritto privato$2FIR$3RMLC064825$9I
700  1$aLUMINOSO$b, Angelo$3RMLV152569$0145126
801  3$aIT$bIT-01$c20121121
850   $aIT-FR0098          
899   $aBiblioteca Area Giuridico Economica$bFR0098          
912   $aRML0256421
950  0$aBiblioteca Area Giuridico Economica$d 53DSG       GIU/TR10/1500$e 53VM 0000273575  VM                        barcode:24496-10. - Inventario:7475VM$fA $h20010423$i20121204
977   $a 53
996   $aCodice civile$93622499
997   $aUNICAS

LEADER 05311nam  2200673Ia 450 
001 9911020207803321
005 20200520144314.0
010   $a9786610921607
010   $a9781280921605
010   $a1280921609
010   $a9783527610686
010   $a3527610685
010   $a9783527610679
010   $a3527610677
035   $a(CKB)1000000000377588
035   $a(EBL)482140
035   $a(OCoLC)173134559
035   $a(SSID)ssj0000153732
035   $a(PQKBManifestationID)11149335
035   $a(PQKBTitleCode)TC0000153732
035   $a(PQKBWorkID)10413336
035   $a(PQKB)11182858
035   $a(MiAaPQ)EBC482140
035   $a(Perlego)2760113
035   $a(EXLCZ)991000000000377588
100   $a20060523d2007      uy         0
101 0 $aeng
135   $aur|n|---|||||
181   $ctxt
182   $cc
183   $acr
200 10$aFatigue crack propagation in metals and alloys $emicrostructural aspects and modelling concepts /$fUlrich Krupp
210   $aWeinheim $cWiley-VCH ;$aChichester $cJohn Wiley [distributor]$d2007
215   $a1 online resource (313 p.)
300   $aDescription based upon print version of record.
311 08$a9783527315376 
311 08$a3527315373 
320   $aIncludes bibliographical references and index.
327   $aFatigue Crack Propagation in Metals and Alloys; Foreword; Contents; Symbols and Abbreviations; 1 Introduction; 2 Basic Concepts of Metal Fatigue and Fracture in the Engineering Design Process; 2.1 Historical Overview; 2.2 Metal Fatigue, Crack Propagation and Service-Life Prediction: A Brief Introduction; 2.2.1 Fundamental Terms in Fatigue of Materials; 2.2.2 Fatigue-Life Prediction: Total-Life and Safe-Life Approach; 2.2.3 Fatigue-Life Prediction: Damage-Tolerant Approach; 2.2.4 Methods of Fatigue-Life Prediction at a Glance; 2.3 Basic Concepts of Technical Fracture Mechanics
327   $a2.3.1 The K Concept of LEFM2.3.2 Crack-Tip Plasticity: Concepts of Plastic-Zone Size; 2.3.3 Crack-Tip Plasticity: The J Integral; 3 Experimental Approaches to Crack Propagation; 3.1 Mechanical Testing; 3.1.1 Testing Systems; 3.1.2 Specimen Geometries; 3.1.3 Local Strain Measurement: The ISDG Technique; 3.2 Crack-Propagation Measurements; 3.2.1 Potential-Drop Concepts and Fracture Mechanics Experiments; 3.2.2 In Situ Observation of the Crack Length; 3.3 Methods of Microstructural Analysis and Quantitative Characterization of Grain and Phase Boundaries
327   $a3.3.1 Analytical SEM: Topography Contrast to Study Fracture Surfaces3.3.2 SEM Imaging by Backscattered Electrons and EBSD; 3.3.3 Evaluation of Kikuchi Patterns: Automated EBSD; 3.3.4 Orientation Analysis Using TEM and X-Ray Diffraction; 3.3.5 Mathematical and Graphical Description of Crystallographic Orientation Relationships; 3.3.6 Microstructure Characterization by TEM; 3.3.7 Further Methods to Characterize Mechanical Damage Mechanisms in Materials; 3.4 Reproducibility of Experimentally Studying the Mechanical Behavior of Materials
327   $a4 Physical Metallurgy of the Deformation Behavior of Metals and Alloys4.1 Elastic Deformation; 4.2 Plastic Deformation by Dislocation Motion; 4.3 Activation of Slip Planes in Single- and Polycrystalline Materials; 4.4 Special Features of the Cyclic Deformation of Metallic Materials; 5 Initiation of Microcracks; 5.1 Crack Initiation: Definition and Significance; 5.1.1 Influence of Notches, Surface Treatment and Residual Stresses; 5.2 Influence of Microstructual Factors on the Initiation of Fatigue Cracks; 5.2.1 Crack Initiation at the Surface: General Remarks
327   $a5.2.2 Crack Initiation at Inclusions and Pores5.2.3 Crack Initiation at Persistent Slip Bands; 5.3 Crack Initiation by Elastic Anisotropy; 5.3.1 Definition and Significance of Elastic Anisotropy; 5.3.2 Determination of Elastic Constants and Estimation of the Elastic Anisotropy; 5.3.3 FE Calculations of Elastic Anisotropy Stresses to Predict Crack Initiation Sites; 5.3.4 Analytical Calculation of Elastic Anisotropy Stresses; 5.4 Intercrystalline and Transcrystalline Crack Initiation; 5.4.1 Influence Parameters for Intercrystalline Crack Initiation
327   $a5.4.2 Crack Initiation at Elevated Temperature and Environmental Effects
330   $aThis comprehensive overview of the whole field of fatigue and fracture of metallic materials covers both the theoretical background and some of the latest experimental techniques. It provides a summary of the complex interactions between material microstructure and cracks, classifying them with respect to the overall damage process with a focus on microstructurally short cracks and dynamic embrittlement. It furthermore introduces new concepts for the numerical treatment of fatigue microcrack propagation and their implementation in fatigue-life prediction models.This comprehensive overview of t
606   $aMetals$xFatigue
606   $aAlloys$xFatigue
615  0$aMetals$xFatigue.
615  0$aAlloys$xFatigue.
676   $a620.1617
676   $a620.166
700   $aKrupp$b Ulrich$cPh. D.$01840831
801  0$bMiAaPQ
801  1$bMiAaPQ
801  2$bMiAaPQ
906   $aBOOK
912   $a9911020207803321
996   $aFatigue crack propagation in metals and alloys$94420403
997   $aUNINA