Prof. Dr. Michael Zaiser



Organisationseinheit


Lehrstuhl für Werkstoffsimulation



Projektleitung

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(Skalenübergreifende Bruchvorgänge: Integration von Mechanik, Materialwissenschaften, Mathematik, Chemie und Physik (FRASCAL)):
GRK2423 - P4: Teilprojekt P4 - Fragmentation in Large Scale DEM Simulations
Prof. Dr. Thorsten Pöschel; Prof. Dr. Michael Zaiser
(02.01.2019 - 30.06.2023)

(Skalenübergreifende Bruchvorgänge: Integration von Mechanik, Materialwissenschaften, Mathematik, Chemie und Physik (FRASCAL)):
GRK2423 - P5: Teilprojekt P5 - Compressive Failure in Porous Materials
Prof. Dr.-Ing. Paul Steinmann; Prof. Dr. Michael Zaiser
(02.01.2019 - 30.06.2023)

Molekulare Simulationen zur Entwicklung nanoskaliger Verbundwerkstoffe aus Metallen und Kohlenstoff-Nanoteilchen
Prof. Dr. Michael Zaiser
(01.04.2018 - 31.03.2021)

(Fracture Across Scales and Materials, Processes and Disciplines (FRAMED)):
FRAMED: Fracture Across Scales and Materials, Processes and Disciplines
Prof. Dr.-Ing. Erik Bitzek; Prof. Dr.-Ing. Paul Steinmann; Prof. Dr. Michael Zaiser
(01.09.2017 - 31.08.2021)

Theorie und Simulation der Versetzungsbewegung in einphastigen hochentropischen Legierungen
Prof. Dr. Michael Zaiser
(01.06.2016 - 31.05.2019)


Mitarbeit in Forschungsprojekten


GRK 2423 FRASCAL: Skalenübergreifende Bruchvorgänge: Integration von Mechanik, Materialwissenschaften, Mathematik, Chemie und Physik (FRASCAL)
Prof. Dr.-Ing. Paul Steinmann
(01.01.2019 - 30.06.2023)


Publikationen (Download BibTeX)

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Wu, R., & Zaiser, M. (2019). Cyclic-loading microstructure-property relations from a mesoscale perspective: An example of single crystal Nickel-based superalloys. Journal of Alloys and Compounds, 770, 964-971. https://dx.doi.org/10.1016/j.jallcom.2018.08.168
Zaiser, M., Lu, S., Zhang, B., Li, X., Zhao, J., Zaiser, M.,... Zhang, X. (2019). Grain boundary effect on nanoindentation: A multiscale discrete dislocation dynamics model. Journal of the Mechanics and Physics of Solids, 126, 117-135. https://dx.doi.org/10.1016/j.jmps.2019.02.003
Moretti, P., Renner, J., Safari, A., & Zaiser, M. (2019). Graph theoretical approaches for the characterization of damage in hierarchical materials. European Physical Journal B, 92(5). https://dx.doi.org/10.1140/epjb/e2019-90730-9
Zhai, J., & Zaiser, M. (2019). Properties of dislocation lines in crystals with strong atomic-scale disorder. Materials Science and Engineering A-Structural Materials Properties Microstructure and Processing, 285-294. https://dx.doi.org/10.1016/j.msea.2018.10.010
Monavari, M., & Zaiser, M. (2018). Annihilation and sources in continuum dislocation dynamics. Materials Theory, 2.
Castellanos, D.F., & Zaiser, M. (2018). Avalanche Behavior in Creep Failure of Disordered Materials. Physical Review Letters, 121(12). https://dx.doi.org/10.1103/PhysRevLett.121.125501
Moretti, P., Dietemann, B., Esfandiary, N., & Zaiser, M. (2018). Avalanche precursors of failure in hierarchical fuse networks. Scientific Reports, 8(1). https://dx.doi.org/10.1038/s41598-018-30539-x
Liebenstein, S., & Zaiser, M. (2018). Determining Cosserat Constants for 2D cellular solids from beam models,. Materials Theory, 2.
Wu, R., Tuzes, D., Ispanovity, P.D., Groma, I., Hochrainer, T., & Zaiser, M. (2018). Instability of dislocation fluxes in a single slip: Deterministic and stochastic models of dislocation patterning. Physical Review B, 98(5). https://dx.doi.org/10.1103/PhysRevB.98.054110
Liebenstein, S., Sandfeld, S., & Zaiser, M. (2018). Size and disorder effects in elasticity of cellular structures: From discrete models to continuum representations. International Journal of Solids and Structures, 146, 97-116. https://dx.doi.org/10.1016/j.ijsolstr.2018.03.023

Zuletzt aktualisiert 2016-22-07 um 05:35

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