[1] G. Rotella, O.W. Dillon, D. Umbrello, L. Settineri, I.S. Jawahir, Finite element modeling of microstructural changes in turning of AA7075-T651 Alloy, Journal of Manufacturing Processes,
Volume 15, Issue 1, 2013, pp. 87-95, ISSN 1526-6125.
[2] Furumoto, T., Abe, S., Yamaguchi, M. et al. Improving surface quality using laser scanning and machining strategy combining powder bed fusion and machining processes. Int J Adv Manuf Technol 117, 3405–3413 (2021).
[3] Calamaz, M., Coupard, D., Nouari, M. et al. Numerical analysis of chip formation and shear localisation processes in machining the Ti-6Al-4V titanium alloy. Int J Adv Manuf Technol 52, 887–895 (2011). https://doi.org/10.1007/s00170-010-2789-x
[4] Ravindranadh Bobbili, Vemuri Madhu, A modified Johnson-Cook model for FeCoNiCr high entropy alloy over a wide range of strain rates, Materials Letters, 218, 2018, pp. 103-105, https://doi.org/10.1016/j.matlet.2018.01.163.
[5] M. Alitavoli, A. Darvizeh, M. Moghaddam, P. Parghou, R. Rajabiehfard, Numerical modeling based on coupled Eulerian-Lagrangian approach and experimental investigation of water jet spot welding process, Thin-Walled Structures, Volume 127, 2018, pp. 617-628, ISSN 0263-8231, https://doi.org/10.1016/j.tws.2018.02.005.
[6] S. Imbrogno, G. Rotella, S. Rinaldi, Surface and subsurface modifications of AA7075-T6 induced by dry and cryogenic high speed machining, The International Journal of Advanced Manufacturing Technology volume 107: 905–918 (2020)
[7] K. Ma, H. Wen, T. Hu, T. D. Topping, D. Isheim, D. N. Seidman, E. J. Lavernia, J. M. Schoenung, (2014), Mechanical behavior and strengthening mechanisms in ultrafine grain precipitation-strengthened aluminum alloy, Acta Materialia, 61: 141-155.
[8] M. Dixit, R. S. Mishra, K. K. Sankaran, (2008), Structure–property correlations in Al 7050 and Al 7055 high-strength aluminum alloys, Materials Science and Engineering A, 478: 163–172.
[9] Y. H. Zhao, X. Z. Liao, Z. Jin, R. Z. Valiev, Y. T. Zhu, (2004), Microstructures and mechanical properties of ultrafine grained 7075 Al alloy processed by ECAP and their evolutions during annealing, Acta Materialia, 52: 4589-4599.
[10] U.F. Kocks, A statistical theory of flow stress and work-hardening, Philosophical Magazine, 13 (1966), pp. 541-566
[11] S. N. Melkote, R. Liu, P. F. Zelaia, T. Marusich, (2015), A physically based constitutive model for simulation of segmented chip formation in orthogonal cutting of commercially pure titanium, Cirp Annals, 64: 65-68.
[12] I. Sabirov, M. Y. Murashkin, R. Z. Valiev, (2013), Nanostructured aluminium alloys produced by severe plastic deformation: New horizons in development, Materials Science and Engineering A, 560: 1-24.
[13] T.D. Topping, B. Ahn, Y. Li, S.R. Nutt, E.J. Lavernia, (2012), Influence of Process Parameters on the Mechanical Behavior of an Ultrafine-Grained Al Alloy, Metallurgical and Materials Transactions A, 43: 505-519.
[14] J. Gubicza, I. Schiller, N.Q. Chinh, J. Illy, Z. Horita, T.G. Langdon, (2007), The effect of severe plastic deformation on precipitation in supersaturated Al–Zn–Mg alloys, Materials Science and Engineering A: 461: 77–85.
[15] H. Frost, M. Ashby, (1977b), Deformation-mechanism maps for pure iron, two austenitic stainless steels and a low-alloy ferritic steel. In: Jaffee, R.I., Wilcox, B.A. (Eds.), Fundamental Aspects of Structural Alloy Design. Plenum Press, pp. 26–65.
[16] H. Conrad, (1970), The athermal component of the flow stress in crystalline solids, Material Science and Engineering A, 6: 265–273.
[17] E. Arzt, Size effects in materials due to microstructural and dimensional constraints: a comparative review, Acta Materialia, 46 (16): 5611-5626.
[18] A. Seeger, (1956) The mechanism of Glide and Work Hardening in FCC and HCP Metals. In: Fisher, J., Johnston, W.G., Thomson, R., Vreeland, T.J. (Eds.), Dislocations and Mechanical Properties of Crystals, pp. 243–329.
[19] Y. Bergström, (1983), The plastic deformation of metals - A dislocation model and its applicability. Reviews on powder metallurgy and physical ceramics 2/3: 79–265.
[20] D. Holt, (1970), Dislocation cell formation in metals, Journal of Applied Physics, 41: 3197-3201.
[21] T. L. Johnson, C. E. Feltner, Grain size effects in the strain hardening of polycrystals, Metallurgical and Materials Transactions B volume 1, 1161 (1970)
[22] A. V. Lubarda, On Atomic Disregistry, Misfit Energy, and the Peierls Stress of a Crystalline Dislocation, THE MONTENEGRIN ACADEMY OF SCIENCES AND ARTS PROCEEDINGS OF THE SECTION OF NATURAL SCIENCES, 17, 2007
[23] S. Takeuchi (2001), The mechanism of the inverse Hall-Petch relation of nanocrystals, Scripta Materialia Volume 44 (8–9): 1483-1487.
[24] R. O. Scattergood, C. C. Kock, (1992), A modified model for Hall-Petch behavior in nanocrystalline materials, Scripta Metallurgica et Materialia, 27: 1195-1200.
[25] G. J. Thomas, R.W. Siegel, J.A. Eastman, (1990), Grain boundaries in nanophase palladium: high resolution electron microscopy and image simulation, Scripta Metallurgica et Materialia, 24: 201-206.
[26] H. Hallberg, M. Wallin, M. Ristinmaa, (2010), Modelling of continuous dynamic recrystallization in commercial-purity aluminum, Materials Science and Engineering A, 527: 1126–1134.
[27] G. Z. Quan, Y. P. Mao, G. S. Li, W. Q. Lv, Y. Wang, J. Zhou, (2012), A characterization for the dynamic recrystallization kinetics of as-extruded 7075 aluminum alloy based on true stress–strain curves, Computational Material Science, 55: 65-72.
[28] C. Shi, W. Mao, X. G. Chen, (2013), Evolution of activation energy during hot deformation of AA7150 aluminum alloy, Materials Science and Engineering A 571: 83-91.
[29] D. Caillard, J. L. Martin, (2003), Thermally Activated Mechanisms in Crystal Plasticity, Pergamon, Oxford.
[30] H. Frost, M. Ashby, (1982), Deformation-mechanism maps - the plasticity and creep of metals and ceramics, Pergamon Press, Oxford.
[31] M. Nicolas, A. Deschamps, (2003), Precipitate Microstructures and Resulting Properties of Al-Zn-Mg Metal Inert Gas–Weld Heat-Affected Zones, Metallurgical and Materials Transactions A, 35: 1437-1448
[32] O. Ryen, O. Nijs, E. Sjolander, B. Holmedal, H.E. Ekstrom, E. Nes, (2006), Strengthening mechanisms in solid solution aluminum alloys, Metallurgical and Materials Transactions A, 37: 1999-2006.
[33] V. P. Astakhov, S. Joksch, (2012), Metalworking fluids (MWFs) for cutting and grinding – fundamentals and recent advances: 147–151; Cambridge, UK, Woodhead Publishing Limited, 1.
[34] F. Pušavec, T. Lu, C. Courbon, J. Rech, U. Aljancic, J. Kopac, I. S. Jawahir, (2016), Analysis of the influence of nitrogen phase and surface heat transfer coefficient on cryogenic machining performance, Journal of Materials Processing Technology, 233: 19-28.
[35] A. Bordin, S. Imbrogno, G. Rotella, S. Bruschi, A. Ghiotti, D. Umbrello, Finite Element Simulation of Semi-finishing Turning of Electron Beam Melted Ti6Al4V Under Dry and Cryogenic Cooling Procedia CIRP, 31 (2015), pp. 551-556.
[36] T. Özel, (2006), The influence of friction models on finite element simulations of machining, International Journal of Machine Tools and Manufacture, 46: 518–530.
[37] P. J. Arrazola, T. Ӧzel, (2010), Investigations on the effects of friction modeling in finite element simulation of machining, International Journal of Mechanical Sciences, 52: 31-42.
[38] F. Cabanettes, J. Rolland, F. Dumont, J. Rech, Z. Dimkovski, (2016), Influence of Minimum Quantity Lubrication on friction characterizing tool-aluminum alloy contact, Journal of Tribology, 138: 1-10.
[39] S. Imbrogno, G. Rotella, S. Rinaldi (2020), Surface and subsurface modifications of AA7075-T6 induced by dry and cryogenic high speed machining, The International Journal of Advanced Manufacturing Technology, 107: 905–918.