General Papers
| Fatigue Crack Path in new generation Al alloys: coupled influence of microstructure and atmosphere environment | |
| J. Petit, C. Sarrazin-Baudoux, S. Richard, C. Gasquères |
| Numerical Analysis of Crack Initiation and Propagation Behaviors in TP-650 Titanium Matrix Composites | |
| W.D. Song, J.G. Ning, X.N. Mao |
| Concrete-to-Concrete Interfacial Surfaces | |
| A. Satoh, K. Yamada, S. Ishiyama |
| Modeling the mechanics of intergranular crack propagation | |
| A. Stoll, A.J. Wilkinson |
| An Experimental Study of the Influence of Laser ShockPeening on Fatigue Crack Growth | |
| A. Chahardehi, F. P. Brennan, A. Steuwer |
| Crack Path in Turbine Blades for Transition from Very- to High-Cycle-Fatigue Regime | |
| A. A. Shanyavskiy |
| SUBSURFACE SHORT CRACKS PATH IN TI-6AL-3MO-0.4SI TI-ALLOY | |
| A.A. Shanyavskiy, M.D. Banov |
| CRACK PATH OF IN-SERVICE FAILED TITANIUM COMPRESSOR DISKS IN HIGH- AND LOW-CYCLE-FATIGUE REGIME | |
| A.A. Shanyavskiy, Yu.A. Potapenko |
| CRACK PATH OF IN-SERVICE FAILED TITANIUMCOMPRESSOR DISKS IN HIGH- AND LOW-CYCLE-FATIGUE REGIME | |
| A.A. Shanyavskiy, Yu.A. Potapenko |
| Stresses and Crack Tip Stress Intensity Factors AroundSpherical and Cylindrical Voids and Inclusions of DifferingElastic Properties and with Misfit Sizes | |
| Paul C. Paris, Thierry Palin-Luc, Hiroshi Tada, Nicolas Saintier |
| Smart Stress-Memory Patch Sensor for Fatigue Damage of aSingle Steel Bar JIS G 3502 – Galvanized Wire – JSS II 11 -1994 | |
| M. Enoki, Y. Fujino, E. Sorrivi, S. Takayuki, E. Viola |
| Numerical investigations on the influence of 3D frictionalcrack surface interaction | |
| W. Weber, K. Willner, P. Steinmann, G. Kuhn |
| Near-Threshold Propagation of Mode II and Mode III Cracks | |
| L. Holá?, R. Pippan, J. Pokluda, J. Horníková, A. Hohenwarter, K. Sláme?ka |
| On the Mechanism of Factory-Roof Formation | |
| J. Pokluda, K. Sláme?ka, P. Šandera |
| Crack propagation in Low Temperature Co-fired Ceramics underbiaxial loading | |
| R. Bermejo, I. Kraleva, R. Morrell, F. Aldrian, P. Supancic, R. Danzer |
| Cohesive element model for simulation of crack growth incomposite materials | |
| M. Prechtel, P. Leiva Ronda, R. Janisch, G. Leugering, A. Hartmaier, P. Steinmann |
| Efficient finite element modeling of the static collapse ofcomplex bonded structures | |
| D. Castagnetti, A. Spaggiari, E. Dragoni |
| Numerical simulation of crack paths in materials with a functional gradation perpendicular to the crack orientation | |
| M. Fulland, M. Steigemann, H. A. Richard, M. Specovius-Neugebauer |
| Can we describe kinetics of fatigue crack growth withoutinfluence of R-ratio? | |
| M. Szata, G. Lesiuk |
| A transversal crack in a steel slab and its analysis | |
| K. Stransky, F. Kavicka, J. Dobrovska |
| The Influence of Constraint Level on Crack Path | |
| M. Šev?ík, P. Huta?, L. Náhlík, S. Seitl |
| Crack paths in functionally graded materials | |
| M. Steigemann, M. Fulland, M. Specovius-Neugebauer, H.A. Richard |
| Crack Growth Trajectories under Mixed Mode and BiaxialFracture | |
| V.N. Shlyannikov |
| An Investigation on Fracture Surfaces of Shot Blasted and AsForged Components in Constant and Variable LoadingFatigue | |
| K. Dalaei, B. Karlsson, L.-E. Svensson |
| Fractographic studies of fatigue cracks under pure Mode II loading | |
| A. Hohenwarter, R. Pippan, Erich Schmid |
| Solidifying ceramics EUCOR and its tendency to the cracks and fractures | |
| K. Stransky, J. Dobrovska, F. Kavicka, B. Sekanina |
| Crack Propagation Behavior of SCM440H Low Alloy Steel Enhanced by Hydrogen under Long-term Varying Loadand Static Load | |
| Yoshiyuki KONDO, Masanobu KUBOTA, Katsuya SHIMADA |
| Crack Propagation in Laminar Ceramics | |
| L. Náhlík, L. Šestáková, P. Huta? |
| Mixed mode crack path investigation in a limestone rock using two circular shaped samples –An experimental and theoretical study | |
| M. R. M. Aliha, M. R. Ayatollahi, D. J. Smith, M. J. Pavier |
| On a numerical scheme for curved crack propagation based on configurational forces and maximum dissipation | |
| Henning Schütte |
| Crack Paths in Weld Details under Combined Normal andShear Loading | |
| Y. Sumi |
| Stress intensity factors in three-dimensional planar crackssubjected to uniform tensile stress | |
| Paolo Livieri, Fausto Segala |
| Application of a Subsurface Stress/Strain Fatigue Life Approach to Contact Components under Cyclic Bending Loads | |
| Giora Shatil |
| Multiscale Material Design and Crack Path Prediction of a Cementitious Cover Layer with High Toughness | |
| L.P. Guo, W. Sun, Andrea Carpinteri, A. Spagnoli, Q.Y. Cao |
| omprehensive Evaluation of Crack Resistance for Dam Concrete Based on Temperature Stress Testing Machine | |
| CB. Chen, Y.B. Cai, J.T. Ding, W. Sun, N.N. Shi, B. Dong |
| Tensile Cracking Behaviour of Strain-Hardening Cement-Based Composites using a Micromechanical Lattice Model | |
| Andrea Carpinteri, Roberto Brighenti, Andrea Spagnoli, Sabrina Vantadori |
| Crack path prediction in brittle solids by a new discontinuous-like FE approach | |
| Andrea Carpinteri, Roberto Brighenti, Andrea Spagnoli, Sabrina Vantadori |