2020
DOI: 10.1021/acsaem.0c00183
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High-Rate and Long-Cycle Stability with a Dendrite-Free Zinc Anode in an Aqueous Zn-Ion Battery Using Concentrated Electrolytes

Abstract: Recently, metallic zinc (Zn) is becoming a promising ideal anode material for rechargeable aqueous batteries by providing high theoretical capacity (820 mA h/g) with divalent reaction, environmental friendliness, earthy abundance, low cost, low toxicity, higher water compatibility, and low electrochemical potential (−0.762 V vs SHE). However, intensive growth of zinc dendrites while plating/stripping lowers its coulombic efficiency and shortens the cycle life of the rechargeable devices. Here, we report a conc… Show more

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Cited by 123 publications
(75 citation statements)
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“…The observed differences in Zn plating/stripping behavior from the two electrolytes could be attributed to the association of Zn 2+ cations with the different counteranions: singly charged and bulky TFSI − anions (vs SO 4 2− with double charge) and the concurrent solvation effects. [ 36–38,42,48 ] In order to corroborate that, we first explored the interaction between the water molecules and the different salts by using Raman spectroscopy ( Figure 2 a). A broad Raman band that observed in 2900–3700 cm −1 range consisting of several components of the OHH stretching vibration for a typical strongly hydrogen‐bonded pure liquid water was considerably narrowed ZnSO 4 < Zn(TFSI) 2 order, signifying the stronger interaction of the water molecules with the TFSI − than with the SO 4 2− anion.…”
Section: Resultsmentioning
confidence: 88%
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“…The observed differences in Zn plating/stripping behavior from the two electrolytes could be attributed to the association of Zn 2+ cations with the different counteranions: singly charged and bulky TFSI − anions (vs SO 4 2− with double charge) and the concurrent solvation effects. [ 36–38,42,48 ] In order to corroborate that, we first explored the interaction between the water molecules and the different salts by using Raman spectroscopy ( Figure 2 a). A broad Raman band that observed in 2900–3700 cm −1 range consisting of several components of the OHH stretching vibration for a typical strongly hydrogen‐bonded pure liquid water was considerably narrowed ZnSO 4 < Zn(TFSI) 2 order, signifying the stronger interaction of the water molecules with the TFSI − than with the SO 4 2− anion.…”
Section: Resultsmentioning
confidence: 88%
“…As already well‐proven systems, the formation of passivation layer of Zn 4 SO 4 (OH)6·3H 2 O in ZnSO 4 and ZnO in KOH and various by‐products (such as Zn(OH) 2 , x ZnCO 3 ⋅ y Zn(OH) 2 ⋅ z H 2 O, and ZnO) was evidenced from XRD pattern (Figure S8, Supporting Information). [ 48 ] Whereas, XRD of Zn after immersion in 4 m Zn(TFSI) 2 was almost similar to that of bare Zn without/or minimal formation of such corrosion by‐products.…”
Section: Resultsmentioning
confidence: 94%
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“…For example, the coordination number of Zn 2+ with H 2 O would decrease and the interaction between Zn 2+ and SO42 would be reinforced by increasing the concentration of a ZnSO 4 electrolyte. [ 18 ] In other words, the hydration number and hydrated cation radius are reduced in lower water surroundings, which is conducive to the rapid and reversible intercalation/deintercalation of hydrated Zn 2+ ions into the cathode materials, thus enhancing the electrochemical performance of the battery. Therefore, the “water‐in‐salt” concept has been proposed in AZB systems.…”
Section: Issues Related To High‐voltage Azbsmentioning
confidence: 99%