Potentiodynamics of the Zinc and Proton Storage in Disordered Sodium Vanadate for Aqueous Zn-Ion Batteries

Abstract: A rechargeable Zn-ion battery is a promising aqueous system, where coinsertion of Zn2+ and H+ could address the obstacles of the sluggish ionic transport in cathode materials imposed by multivalent battery chemistry. However, there is a lack of fundamental understanding of this dual-ion transport, especially the potentiodynamics of the storage process. Here, a quantitative analysis of Zn2+ and H+ transport in a disordered sodium vanadate (NaV3O8) cathode material has been reported. Collectively, synchrotron X-… Show more

“…All of the above results indicate the reversible redox of DQP during a discharge/charge process with active CN bonds. Different from most of the reported organic materials with carbonyls as active sites for ZIBs, DQP delivers a relatively high initial capacity, owing to the more stable charged state with negative charge on N. As is known, proton insertion can be found in many ZIBs with inorganic − and organic cathodes. However, when it comes to organic cathodes with active CN bonds, the role of protons is still controversial. , Hence, clarifying the mechanism of proton storage is necessary for the following study.…”

Extended π-Conjugated System in Organic Cathode with Active C═N Bonds for Driving Aqueous Zinc-Ion Batteries

“…All of the above results indicate the reversible redox of DQP during a discharge/charge process with active CN bonds. Different from most of the reported organic materials with carbonyls as active sites for ZIBs, DQP delivers a relatively high initial capacity, owing to the more stable charged state with negative charge on N. As is known, proton insertion can be found in many ZIBs with inorganic − and organic cathodes. However, when it comes to organic cathodes with active CN bonds, the role of protons is still controversial. , Hence, clarifying the mechanism of proton storage is necessary for the following study.…”

Extended π-Conjugated System in Organic Cathode with Active C═N Bonds for Driving Aqueous Zinc-Ion Batteries

“…All types of cathode materials, including V-, Mn-, and Co-based and Prussian blue analogs, undergo dissolution in aqueous electrolytes. ,,− There are three ways in which the cathode material can dissolve in the electrolyte. First, the cathode material can dissolve into the electrolyte while the battery is operational. ,− This dissolution has been ascribed to the fact that transition metal ions can become unstable during the charging/discharging step in the mildly acidic zinc electrolytes, and this has been discussed in detail in previous review papers. , …”

Undesired Reactions in Aqueous Rechargeable Zinc Ion Batteries

“…Thereinto, it is important to further study vanadium-based cathodes because of their high capacity and rich oxidation states [23][24][25] . They mainly include: V 2 O 5 [26] , VO 2 [27] , and vanadates [28][29][30][31] , etc. However, their poor energy density and sluggish ion transfer speed have not been well resolved.…”

Aqueous zinc ion batteries based on sodium vanadate electrode materials with long lifespan and high energy density