Recent Development in Composite Membranes for Flow Batteries

Wu, Jine; Dai, Qing; Zhang, Huamin; Li, Xianfeng

doi:10.1002/cssc.202000633

Cited by 33 publications

(18 citation statements)

References 140 publications

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“…Nevertheless, it is worth mentioning that non‐perfluorinated membranes (AEM and CEM) and porous membranes with high ion selectivity and chemical stability are still the hotspots of the future development of ICRFB membrane materials [64] . Modifications of perfluorinated membranes, including inorganic‐organic hybrid, polymer blending, and amphoteric membranes need to be further investigated to ameliorate the ionic selectivity, as the developing trend of membranes for vanadium‐based RFB system [4,73] …”

Section: Research Status Of Key Components In Icrfbmentioning

confidence: 99%

“…As the name suggests, two independent electrolyte solutions undergo redox reactions in the corresponding half-cell of the battery during system charging and discharging, so as to store (charging cycle) or release (discharging cycle) electrical energy. [4] The volume and concentration of the catholyte/anolyte determine the energy storage capacity of the battery. On the other hand, the power of the RFB depends on the system design (the number of individual cells and the size of electrodes).…”

Section: Introductionmentioning

confidence: 99%

“…The catholyte/anolyte is stored in reservoirs outside the active battery area and pumped through the battery system as needed. As the name suggests, two independent electrolyte solutions undergo redox reactions in the corresponding half‐cell of the battery during system charging and discharging, so as to store (charging cycle) or release (discharging cycle) electrical energy [4] . The volume and concentration of the catholyte/anolyte determine the energy storage capacity of the battery.…”

Section: Introductionmentioning

confidence: 99%

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Review of the Development of First‐Generation Redox Flow Batteries: Iron‐Chromium System

2021

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The iron-chromium redox flow battery (ICRFB) is considered the first true RFB and utilizes low-cost, abundant iron and chromium chlorides as redox-active materials, making it one of the most cost-effective energy storage systems. ICRFBs were pioneered and studied extensively by NASA and Mitsui in Japan in the 1970-1980s, and extensive studies on ICRFBs have been carried out over the past few decades. In addition, ICRFB is considered to be one of the most promising directions for costeffective and large-scale energy storage applications, as its cost can theoretically be lower than that of zinc-bromine and all-vanadium RFBs, giving it the potential for large-scale promotion. With the resolution of problems such as hydrogen evolution and electrolyte intermixing, the ICRFB technology is moving out of the laboratory and striving for greater power and more stable industrialization requirements. This Review summarizes the history, development, and research status of key components (carbon-based electrode, electrolyte, and membranes) in the ICRFB system, aiming to give a brief guide to researchers who are involved in the related subject.

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Section: Research Status Of Key Components In Icrfbmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Review of the Development of First‐Generation Redox Flow Batteries: Iron‐Chromium System

2021

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“…[4][5][6][7] Despite this intriguing possibility, current NAqRFB prototypes display limited performance and lifetime due, at least in part, to the lack of membranes with suitable combinations of selectivity, conductivity, and stability. [8][9][10][11] Ideally, a RFB membrane should simultaneously block undesired transport of redox-active species and solvent between the positive and negative electrolytes, promote the rapid and selective transport of supporting ions, possess high mechanical and chemical stability, and be conducive to low-cost and scalable production. 12 In practice, this is difficult to implement, and while there have been considerable efforts dedicated to advancing redox chemistries for NAqRFBs, thus far, fewer attempts have focused on developing membranes to support leading chemistries, frustrating full cell performance and durability.…”

Section: Introductionmentioning

confidence: 99%

“…12 In practice, this is difficult to implement, and while there have been considerable efforts dedicated to advancing redox chemistries for NAqRFBs, thus far, fewer attempts have focused on developing membranes to support leading chemistries, frustrating full cell performance and durability. [8][9][10][11] Most prior research on NAqRFBs incorporates commercially available ion-exchange membranes, 13,14 which are not specifically engineered for nonaqueous electrochemical environments and thus typically display unfavorable combinations of ionic conductivity and species selectivity. [15][16][17] Therefore, new separation approaches must be considered, with particular emphasis on materials developed for energy storage technologies that operate in similar (electro)chemical environments.…”

Section: Introductionmentioning

confidence: 99%

Synthesis and Characterization of Lithium-Conducting Composite Polymer–Ceramic Membranes for Use in Nonaqueous Redox Flow Batteries

Gandomi

Krasnikova

Akhmetov

et al. 2021

ACS Appl. Mater. Interfaces

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Redox flow batteries (RFBs) are a burgeoning electrochemical platform for long-duration energy storage, but present embodiments are too expensive for broad adoption. Nonaqueous redox flow batteries (NAqRFBs) seek to reduce system costs by leveraging the large electrochemical stability window of organic solvents (> 3 V) to operate at high cell voltages and to facilitate the use of redox couples that are incompatible with aqueous electrolytes. However, a key challenge for emerging nonaqueous chemistries is the lack of membranes/separators with suitable combinations of selectivity, conductivity, and stability. Single-ion conducting ceramics, integrated with polymeric fillers to make flexible composites, may offer a pathway to the performance attributes needed for competitive nonaqueous systems. Here, we explore composite polymer-inorganic binder-filler membranes for lithium-based NAqRFBs, investigating two different ceramic compounds with NASICON-type (NASICON: sodium (Na) Super Ionic CONductor) crystal structure, Li1.3Al0.3Ti1.7(PO4)3 (LATP) and Li1.4Al0.4Ge0.2Ti1.4(PO4)3 (LAGTP), blended with a polyvinylidene fluoride (PVDF) polymeric matrix. We characterize the physicochemical and electrochemical properties of the synthesized membranes as a function of processing conditions and formulation using a range of microscopic, spectroscopic, and electrochemical techniques. We then integrate select composite membranes into a single electrolyte flow cell configuration and perform polarization measurements with different redox electrolyte compositions. We find that mechanically robust, chemically stable LATP/PVDF composites can support > 40 mA cm −2 at 400 mV cell overpotential, but further improvements are needed in selectivity. The insights gained through this work begin to establish the foundational knowledge needed to advance composite polymer-inorganic membranes/separators for NAqRFBs.

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Iron–Chromium Flow Battery

Zhang

Sun

2023

Flow Batteries

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Recent Development in Composite Membranes for Flow Batteries

Abstract: Figure 13. a) Schematicillustration of selection principle duringt he ion transportprocess of aP IM-1.b)Permeability of protons and VO 2 +. [36b] Reproduced with permission from Ref. [36b].Copyright2 016. Wiley-VCH.

Cited by 33 publications

References 140 publications

Review of the Development of First‐Generation Redox Flow Batteries: Iron‐Chromium System

Review of the Development of First‐Generation Redox Flow Batteries: Iron‐Chromium System

Synthesis and Characterization of Lithium-Conducting Composite Polymer–Ceramic Membranes for Use in Nonaqueous Redox Flow Batteries

Iron–Chromium Flow Battery

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