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Advanced Materials Simulation with Phase Field (PFM2)

Lecturer

Dr. rer. nat. Frank Wendler, Akad. Rat

Details

Vorlesung mit Übung
Präsenz
2 cred.h, ECTS studies, ECTS credits: 2,5
für FAU Scientia Gaststudierende zugelassen, Sprache Englisch, Informationen zu Beitritt und Zoom-Link in StudOn: https://www.studon.fau.de/crs3789717.html
Time and place: Fri 14:15 - 15:45, 2.018-2 Seminarraum Technikum 2; comments on time and place: The first lecture will start 06.05.2022, a preparation meeting will be on 29.04.2022, 14:15. Zoom: https://fau.zoom.us/j/96480558540?pwd=Nnk0UE9pWHJOakxFMUJNRElRV0FUdz09 If the weekly date/place of the lecture doesn't fit into the majority's schedule, we might change it accordingly - please tell me at the preparation meeting, or give me a note

Fields of study

WPF MWT-MA-WSI ab 2 (ECTS-Credits: 2,5)
WPF NT-MA-WSI ab 2 (ECTS-Credits: 2,5)

Prerequisites / Organisational information

An ideal preparation for this course is ‘Introduction to Phase Field Simulation PFM1’ from the winter semester. Nevertheless, there will be an introduction to keep it self-contained and enable understanding even when not having heard PFM1.
Prerequisite for this course is good knowledge of PYTHON. If you haven't programmed in PYTHON yet you have to take part in our PYTHON introduction course "Scientific Programming with PYTHON (SciProgPy)" which will take place during the first week of lectures. For further details please refere to the UnivIS course "SciProPy".

Contents

Phase-field simulations become increasingly popular for investigating mesoscopic structure evolution in alloys, ceramics and soft matter. In this lecture the phase-field method is applied to extended material problems, where the growth a phase is influenced by thermal, compositional, elastic, and flow fields. Hand-on tutorials and example models in Python are presented to understand the implementation into code and its extension for own purposes. The coupled field problems include examples from solidification to stress driven microstructure transformations (precipitation, martensitic transformation) and influence of electromagnetic fields.

ECTS information:

Credits: 2,5

Additional information

www: https://www.studon.fau.de/crs3789717.html

Verwendung in folgenden UnivIS-Modulen

Startsemester WS 2021/2022:: Foundations of phase field modeling (PhaseFM)

Department: Chair for Materials Simulation



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