Celgard/PIM‐1 proton conducting composite membrane with reduced vanadium permeability

Renewable energy systems need efficient and cheap storage devices and vanadium redox flow batteries (VRB) may become one of them. However, better performance of VRB membranes yet should be achieved. Novel composite Celgard‐based films coated with PIM‐1 for aqueous electrolyte VRB applications are pr...

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Bibliographic Details
Published in:Journal of applied polymer science 2022-04, Vol.139 (16), p.n/a
Main Authors: Sizov, Victor E., Zefirov, Vadim V., Volkova, Yulia A., Gusak, Danil I., Kharitonova, Elena P., Ponomarev, Igor I., Gallyamov, Marat O.
Format: Article
Language:English
Subjects:
Aqueous electrolytes
batteries and fuel cells
coatings
electrochemistry
Materials science
Membranes
Permeability
Polymers
Porous media
Protons
Rechargeable batteries
Selectivity
Storage batteries
Transport properties
Vanadium
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Summary:Renewable energy systems need efficient and cheap storage devices and vanadium redox flow batteries (VRB) may become one of them. However, better performance of VRB membranes yet should be achieved. Novel composite Celgard‐based films coated with PIM‐1 for aqueous electrolyte VRB applications are presented. Two types of the composites with different PIM‐1 loadings are obtained. Their properties are studied and compared with the original Celgard films. The deposited PIM‐1 forms a smooth layer on the outer Celgard surface and penetrates inside the porous matrix, thus significantly reducing the pores diameter and affecting the transport properties of the composite film. The nanoporous structure of PIM‐1 permits size‐screening of H3O+/hydrated vanadium ions when used in aqueous vanadium redox flow batteries applications, which allows to tailor the membrane permeability for the two types of ions and, therefore, to increase its selectivity from 4.3 × 106 to 1.3 × 107 mS min cm−3, while maintaining high proton conductivity. The use of renewable energy sources requires the development of more efficient devices for its storage and timely release, such as vanadium flow batteries (VFB). In order to optimize the VFB properties, we proposed a composite based on a porous polyolefin matrix and a polymer with internal microporosity PIM‐1 as an ion‐conducting membrane. PIM‐1 pores with diameter less than 2 nm provide size‐screening of H3O+/hydrate vanadium ions. The resulting structure demonstrates improved selectivity, which allows it to be used for real applications.
ISSN:0021-8995
1097-4628
DOI:10.1002/app.51985