Materials Processing

Numerical simulations and experimental characterization of different types of materials processing, mainly related to metals.

References

Further details on experimental work and modeling and simulation on materials processing can be found in:

• H. Hallberg, A. Chamanfar and N. Nanninga, A constitutive model for the flow stress behavior and microstructure evolution in aluminum alloys under hot working conditions - with application to AA6099, Applied Mathematical Modelling, 81C:253-262, 2020
• B. Starman, H. Hallberg, M. Wallin, M. Ristinmaa, N. Mole and M. Halilovic, Modelling of the Mechanical Response in 304 Austenitic Steel during Laser Shock Peening and Conventional Shot Peening, Procedia Manufacturing, 47:450-457, 2020
• B. Starman, H. Hallberg, M. Wallin, M. Ristinmaa and M. Halilovic, Differences in phase transformation in laser peened and shot peened 304 austenitic steel, International Journal of Mechanical Sciences, 176:105535, 2020
• H. Hallberg, F. Adamski, S. Baiz and O. Castelnau, Microstructure and property modifications of cold rolled IF steel by local laser annealing, Metallurgical and Materials Transactions A, 48(10):4786-4802, 2017
• Y. Mellbin, H. Hallberg and M. Ristinmaa, An extended vertex and crystal plasticity framework for efficient multiscale modeling of polycrystalline materials, International Journal of Solids and Structures, 125:150-160, 2017
• M. Halilovic, S. Issa, M. Wallin, H. Hallberg and M. Ristinmaa, Prediction of the residual state in 304 austenitic steel after laser shock peening - effects of plastic deformation and martensitic phase transformation, International Journal of Mechanical Sciences, 111-112:24-34, 2016
• Y. Mellbin, H. Hallberg and M. Ristinmaa, Recrystallization and texture evolution during hot rolling of copper, studied by a multiscale model combining crystal plasticity and vertex models, Modelling and Simulation in Materials Science and Engineering, 24(7):075004, 2016
• Y. Mellbin, H. Hallberg and M. Ristinmaa, A combined crystal plasticity and graph-based vertex model of dynamic recrystallization at large deformations, Modelling and Simulation in Materials Science and Engineering, 23(4):045011, 2015
• H. Hallberg, Influence of process parameters on grain refinement in AA1050 aluminum during cold rolling, International Journal of Mechanical Sciences, 66C:260-272, 2013
• H. Hallberg, L. Banks-Sills and M. Ristinmaa, Crack tip transformation zones in austenitic stainless steel, Engineering Fracture Mechanics, 79:266-280, 2012
• H. Hallberg and M. Ristinmaa, Modeling of crack behavior in austenitic stainless steel influenced by martensitic phase transformation, Key Engineering Materials, 452-453:637-640, 2010
• H. Hallberg, P. Hakansson and M. Ristinmaa, Thermo-mechanically coupled model of diffusionless phase transformation in austenitic steel, International Journal of Solids and Structures, 47(11-12):1580-1591, 2010
• H. Hallberg, M. Wallin and M. Ristinmaa, Modeling of continuous dynamic recrystallization in commercial-purity aluminum, Materials Science and Engineering A, 572:1126-1134, 2010
• H. Hallberg, P. Hakansson and M. Ristinmaa, A constitutive model for the formation of martensite in austenitic steels under large strain plasticity, International Journal of Plasticity, 23:1213-1239, 2007