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Krüger, T.: Computer simulation study of collective phenomena in dense suspensions of red blood cells under shear. Springer Spektrum, Heidelberg (2012), 165 pp.
Alkauskas, A.; Deak, P.; Neugebauer, J.; Pasquarello, A.; van de Walle, C. G. (Eds.): Advanced Calculations for Defects in Materials: Electronic Structure Methods. WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim, Germany (2011), 384 pp.
Roters, F.; Eisenlohr, P.; Bieler, T. R.; Raabe, D.: Crystal Plasticity Finite Element Methods in Materials Science and Engineering. Wiley-VCH, Weinheim (2010), 197 pp.
Hassel, A. W.; Bonk, S.; Wicinski, M.; Stratmann, M.; Ogle, K.; Philips-Falcey, N.; Ostwald, C.; Janssen, S.; Stellnberger, K.-H.; Konrath, P.: Passive/active transistions in cyclic corrosion tests. Office for Official Publications of the European Communities, Luxembourg, Luxembourg (2007)
Janssens, K. G. F.; Raabe, D.; Kozeschnik, E.; Miodownik, M. A.; Nestler, B.: Computational Materials Engineering – An Introduction to Microstructure Evolution. Academic Press, Elsevier, USA (2007), 360 pp.
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The Department of Interface Chemistry and Surface Engineering (GO) is mainly focussing on corrosion and electrochemical energy conversion. It is internationally known to be one of the leading groups in the field of electrochemical sciences. Our mission is to combine both fundamental and applied sciences to tackle key-questions for a progress…
Plasticity, fatigue, and fracture of materials arise from localized deformation processes, which can be altered by the materials’ environment. Unravelling these mechanisms at variable temperatures and different atmospheres (like hydrogen), are essential to enhance mechanical performance and lifespan. This requires to understand the microstructure and its evolution down to the atomic level. The department is dedicated to crafting materials with superior mechanical properties by elucidating deformation mechanisms. This involves employing advanced transmission electron microscopy techniques and conducting nano-/micromechanical tests on complex, micro-architectured and/or miniaturized materials.
The department ‘Microstructure Physics and Alloy Design’ investigates the fundamentals of the relations between synthesis, microstructure and properties of often complex nanostructured materials. The focus lies on metallic alloys such as aluminium, titanium, steels, high and medium entropy alloys, superalloys, magnesium, magnetic and thermoelectric…
The Computational Materials Design (CM) Department aims at the development and application of hierarchical and fully parameter-free multiscale methods which allow to simulate iron, steel and related materials with hitherto unprecedented accuracy.