Long-life aqueous zinc-iodine flow batteries enabled by
Here, authors develop a tailored ionic-molecular sieve membrane that selectively intercepts hydrated ions, enabling stable high-capacity long cycling with low projected costs.
Menu
Menu
Here, authors develop a tailored ionic-molecular sieve membrane that selectively intercepts hydrated ions, enabling stable high-capacity long cycling with low projected costs.
The size-sieving effect effectively suppresses polyiodide cross-over, enabling the utilization of porous membranes with high ionic conductivity.
Herein, we report the development of high-performance ion-conducting membranes with enhanced hydroxide ion selectivity and conductivity, specifically tailored for alkaline zinc-based flow
Herein, we develop a tailored ionic-molecular sieve membrane to regulate the transport behaviors of water/hydrated ion clusters, enabling the electrolyte balance by precise size sieving effects.
This review provides an in-depth understanding of all theoretical reaction mechanisms to date concerning zinc–iodine batteries. It revisits the inherent issues and solutions of zinc–iodine
In this perspective, we first review the development of battery components, cell stacks, and demonstration systems for zinc-based flow battery technologies from the perspectives of both
The exploration of enhancing ionic pathways involves multiple aspects such as the introduction of nano-fillers, optimization of polymer matrix, incorporation of ionic liquids, and other emerging methods.
The morphological evolution of zinc electrodes was controlled by using ionic liquids, 1-ethyl-3-methylimidazolium acetate (EMIA), and 1-propylsulfonic-3-methylimidazolium tosylate
Here, high‐conductivity thin Turing membranes prepared by Co²⁺ coordination with polybenzimidazole (OPBI) are designed and their efficient ion transport in the alkaline zinc‐iron flow...
PDF version includes complete article with source references. Suitable for printing and offline reading.