Issue 33

F. Castro et alii, Frattura ed Integrità Strutturale, 33 (2015) 444-450; DOI: 10.3221/IGF-ESIS.33.49 450 [4] Araújo, J.A., Nowell, D., The effect of rapidly varying contact stress fields on fretting fatigue, Int J Fatigue, 24 (2002) 763–776. [5] Araújo, J.A., Castro, F.C., A comparative analysis between multiaxial stress and Δ K-based short crack arrest models in fretting fatigue Engineering Fracture Mechanics, 93 (2012) 34–47. [6] Araújo, J.A., Susmel, L., Taylor, D., Ferro J.C.T., Mamiya, E.N., On the use of the theory of critical distances and the Modified Wöhler curve method to estimate fretting fatigue strength of cylindrical contacts, Int J Fatigue, 29 (2007) 95–107. [7] Navarro, C., Muñoz, S., Domínguez, J., On the use of multiaxial fatigue criteria for fretting fatigue life assessment, Int J Fatigue, 30 (2008) 32–44. [8] Taylor, D., Geometrical effects in fatigue: a unifying theoretical model. Int J Fatigue, 21 (1999) 413–20. [9] Taylor, D., The Theory of Critical Distances: a new perspective in fracture mechanics. Elsevier BV, (2007). [10] Susmel, L., Multiaxial Notch Fatigue: from nominal to local stress-strain quantities. Woodhead & CRC, Cambridge, UK, (2009). [11] Susmel, L., Lazzarin, P., A bi-parametric Wöhler curve for high cycle multiaxial fatigue assessment, Fatigue Fract Eng Mater Struct, 25 (2002) 63–78. [12] Lazzarin, P., Susmel, L., A stress-based method to predict lifetime under multiaxial fatigue loading, Fatigue Fract Eng Mater Struct, 26 (2003) 1171–1187. [13] Castro, F.C., Araújo, J.A., Zouain, N. On the application of multiaxial high-cycle fatigue criteria using the theory of critical distances. Engng Fract Mech. 2009; 76:512–24. [14] Araújo, J.A., Dantas A.P., Castro F.C., Mamiya E.N., Ferreira J.L.A., On the characterization of the critical plane with a simple and fast alternative measure of the shear stress amplitude in multiaxial fatigue, Int J Fatigue, 33 (2011) 1092– 1100. [15] Susmel, L., Taylor, D., Two methods for predicting the multiaxial fatigue limits of sharp notches, Fatigue Fract Engng Mater Struct, 26 (2003) 821–833. [16] Susmel, L., Taylor, D., A novel formulation of the theory of critical distances to estimate lifetime of notched components in the medium-cycle fatigue regime, Fatigue Fract Engng Mater Struct, 30 (2007) 567–581. [17] Susmel, L., Taylor, D., The Modified Wöhler Curve Method applied along with the Theory of Critical Distances to estimate finite life of notched components subjected to complex multiaxial loading paths, Fatigue Fract Engng Mater Struct, 31 (2008) 1047–1064. [18] Susmel L, Taylor D., On the use of the theory of critical distances to predict static failures in ductile metallic materials containing different geometrical features, Eng Fract Mech, 75 (2008) 4410–4421. [19] Vingsbo, O., Söderberg, S., On fretting maps, Wear, 126 (1988) 131-147. [20] Susmel, L., Fatigue Design: Summary, Class notes, (2012). [21] Hills, D.A., Nowell, D., Mechanics of Fretting Fatigue. Dordrecht: Kluwer Academic Publishers, (1994).