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S. Henkel et alii, Frattura ed Integrità Strutturale, 34 (2015) 466-475; DOI: 10.3221/IGF-ESIS.34.52 475 R EFERENCES [1] Matvienko, J.G., The effect of the non-singular T-stress components on crack tip plastic zone under mode I loading, Procedia Materials Science, 3 (2014) 141-146. [2] Anderson, Ted. L., Fracture mechanics, fundamentals and applications, 3rd ed., Tayler & Francis, Boca Raton, (2005). [3] Roos, E., Grundlagen und notwendige Voraussetzungen zur Anwendung der Risswiderstandskurve in der Sicherheitsanalyse angerissener Bauteile, Fortschritt-Berichte VDI. Reihe 18, Mechanik/Bruchmechanik, Band 122, (1993). [4] Varfolomeev, I., Luke, M., Burdack, M., Effect of specimen geometry on fatigue crack growth rates for the railway axle material EA4T, Engineering Fracture Mechanics, 78 (2011) 742-753. [5] Shercliff, H. R., Fleck, N. A., Effect of specimen geometry on fatigue crack growth in plane strain – II. Overload response, Fatigue & Fracture of Engineering Materials & Structures, 13 (1990) 1460-2695. [6] Hoshide, T., Tanaka, K., Yamada, A., Stress-ratio effect of fatigue crack propagation in a biaxial stress field, Fatigue & Fracture of Engineering Materials & Structures, 4 (1981) 1460-2695. [7] Dalle Donne, C., Trautmann, K.-H., Amstutz, H., Cruciform sprcimens for in-plane biaxial fracture, deformation and fatigue testing, in S. Kalluri, P. J. Bonacuse (Eds.), Multiaxial Fatigue and Deformation: Testing and Prediction, ASTM STP 1387, American Society for Testing and Materials, West Conshohocken, (2000) 405-422. [8] Sunder, R., Ilchenko, B.V., Fatigue crack growth under flight spectrum loading with superposed biaxial loading due to fuselage cabin pressure, International Journal of Fatigue, 33 (2011) 1101-1110. [9] Veccnio, R.S., Hertzberg, R.W., Jaccard R., Overload induced crack growth rate attenuation behavior in aluminum alloys, Scripta Metallurgica, 17 (1983) 343-346. [10] ASTM E647-13ae1, Standard Test Method for Measurement of Fatigue Crack Growth Rates, ASTM International, West Conshohocken, (2013). [11] Sandner, M., Sicherheit und Betriebsfestigkeit von Maschinen und Anlagen: Konzepte und Methoden zur Lebensdauer-Vorhersage. Springer-Verlag, Berlin, (2008). [12] Hübner, P., Gärtner, S., Pusch G., Holze, J., Einfluss des Gefüges auf die Risswachstumseigenschaften einer AlMgSi1 Legierung, 31. Tagung DVM Arbeitskreis Bruchvorgänge, Darmstadt, DVM-Band, 231 (1999) 297-305. [13] Brown, M.W., Miller, K.J., Mode I fatigue crack growth under biaxial stress at room and elevated temperature, in K.J. Miller, M.W. Brown (Eds.), Multiaxial Fatigue, American Society for Testing and Materials, ASTM STP 853 (1985) 135-152. [14] Mönch E., Galster, D.: A method for producing a defined uniform biaxial tensile stress field, British Journal of Applied Physics, 14 (1963) 810-812. [15] Sherry, A. H., France, C. C., Goldthorpe, M. R.,Compendium of T-stress solutions for two and three dimensional cracked geometries, Fatigue & Fracture of Engineering Materials & Structures, 18 (1995) 1460-2695. [16] Itoh, T., Nakata, T., Sakane, M., & Ohnami, M., Nonproportional low cycle fatigue of 6061 aluminum alloy under 14 strain paths, in Proceedings of the 5 th International conference on biaxial/multiaxial fatigue and fracture, Krakow Poland, (1997) 173-187. [17] Hübner, P., Pusch, G., Zerbst, U., Henkel, S., Wie genau müssen zyklische Risswachstumsdaten sein? Quantilrisswachstumskurven von Konstruktionswerkstoffen, in F.J. Schmidt (Ed.) Anwendungen und Fortschritte in der Bruch- und Schädigungsmechanik, (2009) 39-49. [18] Kuna, M., Numerische Beanspruchungsanalyse von Rissen, Springer Verlag, Berlin, (2009). [19] Henkel, S., Holländer, D., Wünsche, M., Theilig, H., Hübner, P., Biermann, H., & Mehringer, S., Crack observation methods, their application and simulation of curved fatigue crack growth. Engineering Fracture Mechanics, 77 (2010) 2077-2090. [20] Mall, S., Perel, V.Y., Crack growth behavior under biaxial fatigue with phase difference, International Journal of Fatigue, 74 (2015) 166-172. [21] Sadananda, K., Vasudevan, A.K., Holtz, R.L., Lee, E.U., Analysis of overload effects and related phenomena, International Journal of Fatigue, 21 (1999) 233-246.

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