| 683 - 683 |
Reaction- and Process Engineering as an Enabler of electrochemical Technologies
Krewer U, Turek T |
| 695 - 698 |
50 Years of Chemical Engineering and BCI in Dortmund - A brief Outline of Teaching and Research
Kockmann N |
| 699 - 706 |
The Role of Electrochemistry in Future Dynamic Bio-Refineries: A Focus on (Non-)Kolbe Electrolysis
Palkovits S, Palkovits R |
| 707 - 719 |
The Role of Gas Diffusion Electrodes in the Zinc-Air and Lithium-Air Battery
Fenske D, Bardenhagen I, Schwenzel J |
| 720 - 733 |
Modeling Oxygen Gas Diffusion Electrodes for Various Technical Applications
Kubannek F, Turek T, Krewer U |
| 734 - 743 |
Membrane Fuel Cells
Heinzel A, Beckhaus P, Karstedt J |
| 744 - 757 |
Strategies for Targeted Improvement of Anodic Electron Transfer in Microbial Fuel Cells
Heydorn RL, Engel C, Krull R, Dohnt K |
| 758 - 768 |
Microstructure- and Theory-Based Modeling andSimulation of Batteries and Fuel Cells
Latz A, Danner T, Horstmann B, Jahnke T |
| 769 - 785 |
Electrochemical Reactors for Wastewater Treatment
Muddemann T, Haupt D, Sievers M, Kunz U |
| 786 - 794 |
Which Parameter is Governing for Aqueous Redox Flow Batteries with Organic Active Material?
Hofmann JD, Schroder D |
| 795 - 808 |
Energy-Efficient Gas-Phase Electrolysis ofHydrogen Chloride
Bechtel S, Vidakovic-Koch T, Sundmacher K |
| 809 - 820 |
Electrochemical Ceramic Membrane Reactors in Future Energy and Chemical Process Engineering
Heddrich MP, Gupta S, Santhanam S |
| 821 - 832 |
Design of a Zero-Gap Laboratory-Scale Polymer Electrolyte Membrane Alkaline Water Electrolysis Stack
Hnat J, Kodym R, Denk K, Paidar M, Zitka J, Bouzek K |
| 833 - 842 |
Dynamic Modeling of Reversible Solid Oxide Cells
Wehrle L, Wang YQ, Banerjee A, Brandon N, Deutschmann O |
| 843 - 855 |
Microkinetic Modeling of Nickel Oxidation in Solid Oxide Cells: Prediction of Safe Operating Conditions
Neidhardt JP, Bessler WG |
| 856 - 864 |
Modeling and Parameter Identification foraBiofilm in a Microbial Fuel Cell
Kubannek F, Krewer U |
| 865 - 871 |
Statistical Analysis of the Local Water Transport of a Polymer Electrolyte Fuel Cell
Froning D, Yu JL, Reimer U, Lehnert W |
| 872 - 882 |
Utilizing Formate as an Energy Carrier by Coupling CO2 Electrolysis with Fuel Cell Devices
Bienen F, Kopljar D, Lowe A, Assmann P, Stoll M, Rossner P, Wagner N, Friedrich A, Klemm E |
| 883 - 888 |
Simulation of Electrolyte Imbibition inGasDiffusion Electrodes
Kunz P, Hopp-Hirschler M, Nieken U |
| 889 - 899 |
Simulative Approach for Linking Electrode and Electrolyte Properties to Supercapacitor Performance
Krois K, Hufner L, Glasel J, Etzold BJM |
| 900 - 906 |
Exploring Flow Characteristics in Vanadium Redox-Flow Batteries: Optical Measurements andCFD Simulations
Prumbohm E, Wehinger GD |
| 907 - 918 |
Spatially Resolved Current Density Mapping in PEM-Water Electrolysis Cells
Immerz C, Bensmann B, Trinke P, Suermann M, Hanke-Rauschenbach R |
