PSI - Issue 52

Made Wiragunarsa et al. / Procedia Structural Integrity 52 (2024) 583–593 Wiragunarsa et al. / Structural Integrity Procedia 00 (2023) 000–000

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T.D. Grellier, B.D. Jones, R. Pramanik, K. Pan, A. Albaiz, J.R. Williams, 2016. Mixed-mode fracture modeling with smoothed particle hydrody namics. Computers and Geotechnics 79, 73-85. K. Tazoe, H. Tanaka, M. Oka, and G. Yagawa, 2020. Analyses of fatigue crack propagation with smoothed particle hydrodynamics method. Engineering Fracture Mechanics 228, 106819. K. Tazoe, and G. Yagawa, 2020. Fatigue crack separation and merging simulation using the smoothed particle hydrodynamics. International Journal of Fracture 229, 1-13. I.M. Wiragunarsa, L.R. Zuhal, T. Dirgantara, and I.S. Putra, 2021. A particle interaction-based crack model using an improved smoothed particle hydrodynamics for fatigue crack growth simulations. International Journal of Fracture 229, 229-244. K.V. Ganesh, M.R.I. Islam, P.K. Patra, and K.P. Travis, 2022. A pseudo-spring based SPH framework for studying fatigue crack propagation. International Journal of Fatigue 162, 106986. T. Dirgantara, M.H. Aliabadi, 2000. Crack Growth analysis of plates Loaded by bending and tension using dual boundary element method. Inter national Journal of Fracture 105, 27–47. R.H. Rigby, M.H. Aliabadi, 1998. Decomposition of the mixed-mode J -integral — revisited. International Journal of Solids and Structures 35(17), 2073–2099. M.A. Pustejovsky, 1979. Fatigue crack propagation in titanium under general in-plane loading—I: Experiments. Engineering Fracture Mechanics 11(1), 9-15. Y. Murakami, 1987. Stress intensity factors handbook. Pergamon Press, London.