Linked e-resources
Details
Table of Contents
Intro; Preface; Contents; 1 Fatigue of low alloyed carbon steels in the HCF/VHCF-regimes; Abstract; Keywords; 1 Introduction; 2 Materials and Experimental; 2.1 Materials and Heat Treatment; 2.2 Electromechanical Fatigue Setup; 2.3 Ultrasonic Fatigue Setup; 2.4 Microstructure Investigations; 3 Results and Discussion; 3.1 Influence of Pearlite Phase Fraction on the Fatigue Behaviour; 3.2 Influence of Frequency; 3.3 Influence of Heat Treatment; 4 Summary and Conclusions; Acknowledgements; References
2 Atomic-scale modeling of elementary processes during the fatigue of metallic materials: from crack initiation to crack-microstructure interactionsAbstract; Keywords; 1 Methods; 2 Methods; 2.1 Interatomic potentials; 2.2 Creation of tilt grain boundaries and dislocations; 2.3 Setups for cracks; 2.4 Setup for dislocation-crack interactions; 2.5 Setup for crack initiation; 3 Results and discussion; 3.1 Properties of Fe and W potentials; 3.2 Cracks in perfect single crystals; 3.3 Fracture behavior of grain boundary cracks; 3.3.1 Straight grain boundary cracks; 3.3.2 Curved grain boundary cracks
4 Simulation of the VHCF deformation of austenitic stainless steels and its effect on the resonant behaviourAbstract; Keywords; 1 Introduction; 2 Experimental results; 3 Simulation model; 3.1 Shear band model; 3.2 Martensitic transformation model; 4 Numerical model; 5 Simulation of cyclic plastic deformation of austenitic stainless steels; 5.1 Cyclic plastic deformation of the metastable austenitic stainless steel; 5.2 Cyclic plastic deformation of the stable austenitic stainless steel; 5.3 Comparison of cyclic plastic deformation of the metastable and the stable austenitic stainless steel
5.4 Effect of initial martensite content in the microstructure on plastic sliding deformation5.5 Temperature-dependent cyclic plastic deformation at low stress amplitudes; 5.6 Influence of cyclic plastic deformation on the resonant behaviour; 6 Conclusions; Acknowledgements; References; 5 Slip band formation and crack initiation during very high cycle fatigue of duplex stainless steel
Part 1: Mechanical testing and microstructural investigations; Abstract; Keywords; 1 Introduction; 2 Experimental details; 2.1 Material and sample preparation; 2.2 Test equipment and combination for in situ-observation
2 Atomic-scale modeling of elementary processes during the fatigue of metallic materials: from crack initiation to crack-microstructure interactionsAbstract; Keywords; 1 Methods; 2 Methods; 2.1 Interatomic potentials; 2.2 Creation of tilt grain boundaries and dislocations; 2.3 Setups for cracks; 2.4 Setup for dislocation-crack interactions; 2.5 Setup for crack initiation; 3 Results and discussion; 3.1 Properties of Fe and W potentials; 3.2 Cracks in perfect single crystals; 3.3 Fracture behavior of grain boundary cracks; 3.3.1 Straight grain boundary cracks; 3.3.2 Curved grain boundary cracks
4 Simulation of the VHCF deformation of austenitic stainless steels and its effect on the resonant behaviourAbstract; Keywords; 1 Introduction; 2 Experimental results; 3 Simulation model; 3.1 Shear band model; 3.2 Martensitic transformation model; 4 Numerical model; 5 Simulation of cyclic plastic deformation of austenitic stainless steels; 5.1 Cyclic plastic deformation of the metastable austenitic stainless steel; 5.2 Cyclic plastic deformation of the stable austenitic stainless steel; 5.3 Comparison of cyclic plastic deformation of the metastable and the stable austenitic stainless steel
5.4 Effect of initial martensite content in the microstructure on plastic sliding deformation5.5 Temperature-dependent cyclic plastic deformation at low stress amplitudes; 5.6 Influence of cyclic plastic deformation on the resonant behaviour; 6 Conclusions; Acknowledgements; References; 5 Slip band formation and crack initiation during very high cycle fatigue of duplex stainless steel
Part 1: Mechanical testing and microstructural investigations; Abstract; Keywords; 1 Introduction; 2 Experimental details; 2.1 Material and sample preparation; 2.2 Test equipment and combination for in situ-observation