Applied physics and semiconductor spectroscopy Univ.-Prof. Dr. rer. nat. habil. Jan Ingo Flege

[1]   Müller et al., Sabatier-based CO2-Methanation by catalytic conversion, Energy Procedia, 2013

[2]   Müller et al., Sabatier based CO2-methanation of flue gas emitted by conventional power plants, Environmental Earth Sciences, 2013

[3]   J. Israel, Sabatierbasierte autothermale katalytische Rauchgasmethanisierung im Technikumsmaßstab und Rückverstromung im BHKW, Cottbus, BTU C-S, PhD, 2016

[4]   F. Rachow, Prozessoptimierung für die Methanisierung von CO2 -Vom Labor zum Technikum, Cottbus, BTU C-S, PhD, 2017

[5]   Müller et al., Direct Methanation of Flue Gas at a Lignite Power Plant, International Journal of Environmental Science, 2017

[6]   Grinter et al., In situ growth, structure, and real-time chemical reactivity of well-defined CeOx-Ru(0001) model surfaces, Appl. Catal. B: Environmental, 2016

[7]   Schaefer et al., Thermal reduction of ceria nanostructures on rhodium(111) and re-oxidation by CO2, Phys. Chem., 2018; Höcker et al., Unraveling the dynamic nanoscale reducibility (Ce4+ —> Ce3+) of CeOx-Ru in hydrogen activation, Adv. Mater. Interfaces, 2015

[8]   Müller, Klaus; Rachow, Fabian; Günther, Vivien; Schmeisser, Dieter, Schaefer et al., Methanation of Coke Oven Gas with Nickel-based Catalysts. International Journal of Environmental Science, 4, 73-79, 2019