Improved Electrochemical Performance of Zinc Anodes by EDTA in Near‐Neutral Zinc−Air Batteries

Guerrero, Saul Said Montiel; Durmus, Yasin Emre; Dzięcioł, Krzysztof; Basak, Shibabrata; Tempel, Hermann; Waasen, Stefan van; Kungl, Hans; Eichel, Rüdiger‐A.

doi:10.1002/batt.202100116

Cited by 11 publications

(4 citation statements)

References 57 publications

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“…This difference is attributable to the strong chelation ability of Zn 2+ ions with EDTA molecules, leading to the creation of a more stable and long-lasting coating. 41,42 Consequently, this coating may effectively impede the inltration of corrosive ions, enhancing its corrosion resistance properties.…”

Section: Morphological Analysis Of the Coatingmentioning

confidence: 99%

Modulating chelation with pH sensitivity for controlled structural defects and enhanced electrochemical and photocatalytic activities of LDH films

Khan,

Safira,

Kaseem

2024

J. Mater. Chem. A

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Section: Morphological Analysis Of the Coatingmentioning

confidence: 99%

Modulating chelation with pH sensitivity for controlled structural defects and enhanced electrochemical and photocatalytic activities of LDH films

Khan,

Safira,

Kaseem

2024

J. Mater. Chem. A

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“…Zn 2+ can only be deposited along the (002) crystal surface in the charge and discharge (GCD) process, greatly slowing down the growth of dendrites. 24,25 Merely solving the dendrite growth problem is not enough, so L-carnitine and sodium tartrate have also recently been used as electrolyte additives to improve the anodic HERs. 26,27 These additives are rich in hydroxyl, carboxyl, and other oxygen-containing functional groups, which can effectively regulate the solvated shell of Zn 2+ , thereby reducing the HERs caused by the decomposition of active H 2 O molecules.…”

Section: Introductionmentioning

confidence: 99%

“…The EDTA additive is also often used in the modification of electrolyte of AZIBs, the (100) crystal surface will generate a dissolution reaction when the Zn comes into contact with EDTA. Zn 2+ can only be deposited along the (002) crystal surface in the charge and discharge (GCD) process, greatly slowing down the growth of dendrites. , Merely solving the dendrite growth problem is not enough, so l -carnitine and sodium tartrate have also recently been used as electrolyte additives to improve the anodic HERs. , These additives are rich in hydroxyl, carboxyl, and other oxygen-containing functional groups, which can effectively regulate the solvated shell of Zn 2+ , thereby reducing the HERs caused by the decomposition of active H 2 O molecules . Therefore, designing an excellent electrolyte additive is attractive and challenging.…”

Section: Introductionmentioning

confidence: 99%

Low-Temperature and High-Performance Vanadium-Based Aqueous Zinc-Ion Batteries

Jin,

Ye,

Chen

et al. 2024

ACS Appl. Mater. Interfaces

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Aqueous zinc-ion batteries have attracted attention due to their low cost and high safety. Unfortunately, dendrite growth, hydrogen evolution reactions, cathodic dissolution, and other problems are more serious; not only that, but also the cathodic and anodic materials' lattices contract when the temperature drops, and charge transfer and solid phase diffusion become slow, seriously aggravating dendrite growth. At present, there are few studies on the low-temperature system, and studies on retaining high specific capacity are even more rare. Herein, ethylene glycol (EG) and manganese sulfate (MSO) are selected as additives, and the manganese vanadate (MVO) cathode is used to find a high-performance solution at low temperature. MVO can provide higher specific capacity and better structural stability than MnO 2 to adapt to a low-temperature environment. At the same time, Mn 2+ in MSO can produce a cationic shield covering the initial zinc tip at an appropriate concentration to avoid the tip effect and inhibit the dissolution of MVO. EG can not only reduce the freezing point of the electrolyte but also promote the desolvation of [Zn(H 2 O) 6 ] 2+ . The synergistic effect of the three elements prevents the dissolution equilibrium of Mn 2+ in MVO from fluctuating greatly due to the change of temperature. Therefore, when we use EG@0.2 M MnSO 4 + 2 M ZnSO 4 (EG + 0.2Mn/2ZSO) electrolyte at −30 °C, the Zn||Zn batteries which used this type of electrolyte can remain 350 h at 1 mA cm −2 without failure. The Zn||Cu batteries can retain 100% Coulombic efficiency after more than 2000 cycles at 0.2 mA cm −2 . The Zn||MVO battery can reach 231.13 mA h g −1 at its first cycle, and the capacity retention rate is still above 85% after 1000 cycles, which is higher than that of the existing low-temperature research system.

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“…Among the various types of metal‐air batteries, iron‐air batteries stand out, given the vast abundance of iron, a decent theoretical energy density of 9677 Wh/L Fe (or 1228 Wh/kg Fe , excl. oxygen uptake), a potentially low price [6] and a preeminent environmental friendliness [7–10] . Moreover, iron is less prone to form dendrites upon electrochemical cycling in alkaline media than zinc, [8,11] with all of the aforementioned aspects ever‐sparking research and commercial interest since the times of Thomas Alva Edison [12,13] .…”

Section: Introductionmentioning

confidence: 99%

In Situ Hydrogen Evolution Monitoring During the Electrochemical Formation and Cycling of Pressed‐Plate Carbonyl Iron Electrodes in Alkaline Electrolyte

Weinrich

Pleie

Schmid

et al. 2022

Batteries & Supercaps

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The hydrogen evolution reaction (HER) on iron is a parasitic side reaction for the reduction of iron (hydr)oxide in alkaline electrolyte, which lowers the Coulombic efficiency of iron‐based batteries. Tackling this issue, here we investigate the HER on iron electrodes by in situ gas chromatography, allowing for a quantitative correlation of the applied electrode potential and the resulting hydrogen evolution. As a result, it is shown that the HER follows a distinctive profile corresponding to the electrode potential and changes depending on the state of the iron electrode formation. Moreover, it is shown that the charging efficiency of the iron electrode can be increased by an alteration of the charging procedure, i. e., a more negative cut‐off potential for the discharge and a potential limitation for the recharge. In this study, a charging efficiency of 96.7 % is achieved, using an optimized charging procedure for a formed carbonyl iron electrode containing 8.5 wt.% of Bi2S3.

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Improved Electrochemical Performance of Zinc Anodes by EDTA in Near‐Neutral Zinc−Air Batteries

Cited by 11 publications

References 57 publications

Modulating chelation with pH sensitivity for controlled structural defects and enhanced electrochemical and photocatalytic activities of LDH films

Modulating chelation with pH sensitivity for controlled structural defects and enhanced electrochemical and photocatalytic activities of LDH films

Low-Temperature and High-Performance Vanadium-Based Aqueous Zinc-Ion Batteries

In Situ Hydrogen Evolution Monitoring During the Electrochemical Formation and Cycling of Pressed‐Plate Carbonyl Iron Electrodes in Alkaline Electrolyte

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