Explore the words cloud of the NanoMMES project. It provides you a very rough idea of what is the project "NanoMMES" about.
The following table provides information about the project.
Coordinator |
IMPERIAL COLLEGE OF SCIENCE TECHNOLOGY AND MEDICINE
Organization address contact info |
Coordinator Country | United Kingdom [UK] |
Total cost | 1˙499˙871 € |
EC max contribution | 1˙499˙871 € (100%) |
Programme |
1. H2020-EU.1.1. (EXCELLENT SCIENCE - European Research Council (ERC)) |
Code Call | ERC-2019-STG |
Funding Scheme | ERC-STG |
Starting year | 2019 |
Duration (year-month-day) | from 2019-11-01 to 2024-10-31 |
Take a look of project's partnership.
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1 | IMPERIAL COLLEGE OF SCIENCE TECHNOLOGY AND MEDICINE | UK (LONDON) | coordinator | 1˙499˙871.00 |
With the rapid development of renewable energy such as solar and wind power, energy storage technologies are in urgent need to integrate the low carbon energy into the power grid. Redox flow batteries are promising for grid scale energy storage owing to their scalable storage capacity, decoupled power and energy, long-term cycle performance, and quick response time. Membrane separators play a crucial role in flow batteries by selectively transporting ions while preventing the crossover of redox-active materials. Commercial Nafion membranes are being widely used for flow batteries, however, their high costs limit the large-scale application of this promising technology. Next-generation low-cost membranes with high ionic conductivity and selectivity, and durability are desirable for flow battery energy storage. This proposal NanoMMES aims at designing and nanoengineering low-cost, high-performance, ion-selective microporous membranes for redox flow battery energy storage applications. The objectives of NanoMMES will be achieved through curiosity-driven research into (1) designing the structures of microporous polymers to precisely tune the pore size and ion-conducting functionality required for batteries with different redox chemistries; (2) processing and nanoengineering polymers into highly conductive and selective membranes, and understanding the mechanisms of transport of ions and redox materials; (3) combining the designer membranes with redox flow battery chemistries to achieve efficient and stable energy storage. NanoMMES will undertake interdisciplinary research combining the molecular design of microporous polymers, membrane science and engineering, and redox flow battery chemistry and technology. The ultimate goal of the project is to generate design principles for next-generation ion-selective membranes that will have broad implications on advanced batteries for energy storage, helping the EU develop renewable energy and reduce greenhouse gas emissions.
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The information about "NANOMMES" are provided by the European Opendata Portal: CORDIS opendata.