
Posters kindly sponsored by Lubrizol
Current posters for our 19-21 January 2021 virtual conference include:
No. | Group/Title | Name | Affiliation |
---|---|---|---|
Electrodes & catalysts | |||
72 | On the surface and activity enhancement of graphite felt by a combinational approach of carbon nanotube deposition and KOH etching | Hannes Radinger | Karlsruhe Institute of Technology, Germany |
Membranes | |||
8 | Asymmetric cycling of vanadium redox flow battery with poly (arylene piperidinium) – based anion exchange membrane: performance comparison with Nafion 212 | Amirreza Khataee | KTH Royal Institute of Technology, Sweden |
36 | Composite membranes based on LATP and LAGTP ceramics for lithium hybrid-flow batteries: composition and outer factors’ influence on the performance | Nikolay Ovsyannikov | Skolkovo Institute of Science and Technology, Russia |
85 | Composite anion exchange membrane proposed for RFBs. | Martyna Charyton | Amer-sil S.A., Luxembourg |
101 | Preferential volumetric vanadium redox flow battery transfer studies under running conditions | Valentin Vlasov | Skolkovo Institute of Science & Technology, Russia |
Organic & ionic liquid systems | |||
11 | A catechol-based organic catholyte for aqueous redox flow battery | Xiangrong Li | Institute of Metal Research, Chinese Academy of Sciences, China |
129 | HIGREEW aqueous organic redox flow battery: from materials development to final prototype integration | Ana Catarina Lopes | CIC energiGUNE, Spain |
127 | Development of zinc-air-batteries based on ionic liquids for uninterruptible power supplies (USP) | Manuel Forster | Westphalian University of Applied Sciences, Germany |
104 | Screening of novel organic electroactive compounds for redox flow batteries | Petr Mazur | University of Chemistry and Technology, Prague, Czech Republic |
124 | Development of highly water soluble organic active materials for redox flow battery. | Atsushi Kaiho | Nippon Kayaku Co. Ltd, Japan |
Non-traditional systems | |||
17 | Effect of electrolyte flow rate and different anode materials on the discharge performance of flow type zinc-air battery | Ram kishore Sankaralingam | Indian Institute of Technology, India |
56 | Zinc-air redox flow cell development with an automated test bench integrated | Elena Marchante | AIJU – Technological Institute for Children’s Products and Leisure, Spain |
109 | Characterisation of polyurethane, epoxy and silicone based sealants and adhesives for their potential use in vanadium redox flow batteries | Andreas Arlt | Wevo-Chemie GmbH, Germany |
New chemistries & materials | |||
86 | Enhancing currents with carbonaceous particles dispersed in flow cell | Dino Tonti | Institute of Materials Science of Barcelona, Spain |
136 | Vanadium manganese redox flow battery for energy storage and hydrogen production | Danick Reynard | Ecole Polytechnique Fédérale de Lausanne (EPFL), Switzerland |
220 | Carbonized elastomer composite filled with hybrid carbon fillers for VRFB bipolar plates | Andrei Usenko | Institute of Problems of Chemical Physics RAS, Russia |
Vanadium systems | |||
16 | Performance evaluation of single cell vanadium redox flow battery at low temperatures | Praphulla Rao | Indian Institute of Technology Madras, India |
32 | Flow battery operating in hybrid energy storage system | Krzysztof Rafal | Institute of Fluid Flow Machinery PAS, Poland |
44 | FlowBat 2021: redox flow batteries for large scale energy storage | Ricardo Santamaría | Instituto de Ciencia y Tecnología del Carbono, Spain |
46 | Investigating the deactivation of negative felt electrode of vanadium redox flow battery | Jindřich Mrlík | University of Chemistry and Technology, Czech Republic |
53 | Recent progress of large-scale stack generations for a 40 kW all-vanadium flow battery as part of a hybrid compensator | Jan Girschik | Fraunhofer UMSICHT, Germany |
94 | Electrolyte imbalance determination of a vanadium redox flow battery by potential‐step analysis of the initial charging step | Jan grosse Austing | VANEVO GmbH, Germany |