Balun, J.; Inden, G.; Eleno, L. T. F.; Schön, C. G.: Phase Equilibria in the Ternary Fe–Rh–Ti System. TMS Annual Meeting 2003, International Symposium on Intermetallic and Advanced Metallic Materials – A Symposium dedicated to Dr. C.T. Liu, San Diego, CA, USA (2003)
Zhang, J.; Schneider, A.; Inden, G.: Metal dusting of iron in CO–H2–H2O mixtures at 700 °C. EFC-Workshop: Metal Dusting, Carburisation and Nitridation, Frankfurt, Germany (2003)
Palm, M.; Inden, G.: Experimentelle Bestimmung der Phasengleichgewichte in den Systemen Fe–Al–Ti und Fe–Al–Cr. 15. Vortragsveranstaltung des DVM Arbeitskreises Rastermikroskopie in der Materialprüfung, Kassel, Germany (1992)
Kwiatkowski da Silva, A.; Ponge, D.; Inden, G.; Gault, B.; Raabe, D.: Physical Metallurgy of segregation, austenite reversion, carbide precipitation and related phenomena in medium Mn steels. Gordon Research Conference: Physical Metallurgy, Biddeford, ME, USA (2017)
Belde, M. M.; Springer, H.; Inden, G.; Raabe, D.: Tailoring multi-phase steel microstructures by controlling local chemical gradients. MSE 2014, Darmstadt, Germany (2014)
Eleno, L. T. F.; Schneider, A.; Inden, G.: Experimental determination and thermodynamic modelling of Fe-based high-melting alloys. Calphad XXXIV, Maastricht / The Netherlands (2005)
Schneider, A.; Zhang, J.; Inden, G.: Metal dusting of Fe3Al-based alloys. Annual Meeting 2003, Symposium: International Symposium on Intermetallics and Advanced Metallic Materials, San Diego, CA, USA (2003)
Palm, M.; Kainuma, R.; Inden, G.: Reinvestigation of Phase Equilibria in the Ti-rich Part of the Ti–Al System. Journées d´Automne 1996, Paris, France (1996)
The mission of our group is to uncover the fundamental mechanisms of deformation and degradation in battery systems and to leverage mechanical principles to design damage-resilient energy storage systems.
This project studies the mechanical properties and microstructural evolution of a transformation-induced plasticity (TRIP)-assisted interstitial high-entropy alloy (iHEA) with a nominal composition of Fe49.5Mn30Co10Cr10C0.5 (at. %) at cryogenic temperature (77 K). We aim to understand the hardening behavior of the iHEA at 77 K, and hence guide the future design of advanced HEA for cryogenic applications.