PSI - Issue 52

D. Kujawski et al. / Procedia Structural Integrity 52 (2024) 293–308 Author name / Structural Integrity Procedia 00 (2019) 000 – 000

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affects fatigue damage ahead of the crack tip. Quantifying the crack tip chemistry and its relation to local stresses is a challenging research problem.

ACKNOWLEDGEMENT We thank Professor Reinhard Pippan for his comments and online discussion (with DK) regarding measurements and implementations of crack closure for FCG analysis. Contribution statement D. Kujawski: conceptualization and writing the original draft, A.K. Vasudevan: conceptualization and editing, R.E. Ricker: detail analysis about crack tip chemistry, K. Sadananda: final analysis and editing. References Bae, K., Conrad, H., 1989. Effect of viscosity of an oil environment on fatigue crack growth rate in AISI 316 Stainless Steel, Proceedings of the 7th International Conference on Fracture (ICF7), 1737-1745. Bowman, R., Antolovich. S.D. and Brown, R.C., 1988. A demonstration of problems associated with crack closure measurements techniques, Eng Fract Mech.. 31(4), 703-712. Busse, C., 2019. Modelling of crack growth in single crystal Ni-base superalloys. PhD Thesis, Linkoping University. Cabrera, N., Mott, N.F., 1949. Theory of the oxidation of metals, Reports on Progress in Physics. 12(1), 163 184. Cabrera, N., 2010. On the oxidation of metals at low temperatures and the influence of light, The London, Edinburgh, and Dublin Philosophical Magazine and Journal of Science, 40(301), 175-188. Elber, W., 1970. Fatigue crack closure under cyclic tension loading. Eng Fract Mech. 2(1), 37-45 . Gonzales, J.A.O., Castro, J.T.P., Meggiolaro, M.A., Gonzales, G.L.G., Freire, J.L.F., 2020. Challenging the “ΔK eff is the driving force for fatigue crack growth” hypothesis. Int J Fatigue 136, 105577. Holtz, R.L., Sadananda, K., 1998. Fatigue threshold maps of PWA 1480 superalloy single crystal in air and vacuum at room temperature. In: Srivatsan T.S. Soboyejo W.O. eds . High Cycle Fatigue of Structural Materials. The Minerals, Metals, and Materials Society . TMS Publications, 299-304. Kirby, B.R. and Beevers, C.J., 1979. Slow fatigue crack growth and threshold behavior in air and vacuum of commercial alloys. Fatigue Engng Mater Struct. 1, 203-215. Mott, N.F., 1939. A theory of the formation of protective oxide films on metals, Transactions of the Faraday Society 35. Mott, N.F., 1940. The theory of the formation of protective oxide films on metals, II, Transactions of the Faraday Society 35. Mott, N.F., 1947. The theory of the formation of protective oxide films on metals, III, Trans. Faraday Soc. 43, 429-434. Nguyen, L., Hashimoto, T., Zakharov, D.N., Stach, E.A., Rooney, A.P., Berkels, B., Thompson, G.E., Haigh, S.J., Burnett, T.L., 2018. Atomic-scale insights into the oxidation of aluminum, ACS Appl Mater Interfaces 10(3), 2230-2235. Newman, J.C., 2000. Analysis of fatigue crack growth and closure near threshold conditions. ASTM STP-1372, 227 – 251. Oudar, J., 1995. Introduction to Surface Reactions: Adsorption from Gas Phase in: P. Marcus, J. Oudar (Eds.), Corrosion Mechanisms in Theory and Practice , Marcel Dekker, Inc., New York, 19-54. Paris, P.C., Tada, H. and Donald, J.K., 1999. Service load fatigue damage – A historical perspective. Int J Fatigue 21, S35-S46. Pippan, R. and Hohenwater, A., 2017. Fatigue crack closure: a review of the physical phenomena. Fatigue Fract Engng Mater Struc. 40, 471-495. Petit, J., 1998. Influence of environment on small fatigue crack growth. In: Ravichandran KS, Ritchie RO,