Electrodeposited Manganese Oxide on Carbon Paper for Zinc‐Ion Battery Cathodes

Dhiman, Arjun; Ivey, Douglas G.

doi:10.1002/batt.201900150

Cited by 34 publications

(15 citation statements)

References 62 publications

(259 reference statements)

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“…20 Thus, soluble Mn 2+ salts are typically employed as electrolyte additives to inhibit this dissolution and stabilize cycle life. However, electrolytes containing Mn 2+ allow for electrodeposition of MnO 2 onto the electrode surface, 73 which risks diminishing the quality of the cathode material and/or passivating the electrode-electrolyte interface. Because a delicate balance exists between Mn 2+ dissolution into the electrolyte and MnO 2 deposition onto the electrode surface, future research is urgently required to provide crucial insight into this equilibrium process.…”

Section: Conversion Oxides: Manganese-and Cobalt-based Materialsmentioning

confidence: 99%

Scientific Challenges for the Implementation of Zn-Ion Batteries

Blanc

Kundu

Nazar

2020

Joule

1,276

950

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The safety, affordability, and impressive electrochemical performance of many Zn-ion batteries (ZIBs) has recently triggered an overwhelming literature surge. As is typical for a new area, initial enthusiasm and high expectations have now been replaced by a more measured period of research that reaches deep into the underlying factors controlling electrochemical properties. Rather than battery metrics, this review focuses on fundamental aspects of the chemistry of ZIBs that are the least understood and on which there has been progress over the last few years. We provide guidance for future research regarding (1) the significant challenge of proton/Zn 2+ co-intercalation in aqueous media, (2) limitations to conversion chemistry that often accompanies ZIB electrochemistry, (3) positive aspects of facile Zn 2+ (de)intercalation in nonaqueous electrolytes and organic cathode materials, (4) the desolvation penalty at electrode-electrolyte interfaces, (5) solutions for controlling Zn dendritic growth, and (6) suggested electrochemistry protocols for the field.

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Section: Conversion Oxides: Manganese-and Cobalt-based Materialsmentioning

confidence: 99%

Scientific Challenges for the Implementation of Zn-Ion Batteries

Blanc

Kundu

Nazar

2020

Joule

1,276

950

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“…Perhaps the most well‐studied ZIB cathode materials are Mn‐based oxides [28–30] . This is due to the highly matured synthesis techniques reported for various Mn‐based oxides, economical aspects, and the various oxidation states of Mn [24,31–35] . As such, these factors have garnered increasing interest in the development of high‐performing Mn‐based oxides as ZIB cathode [36] .…”

Section: Introductionmentioning

confidence: 99%

Recent Development of Mn‐based Oxides as Zinc‐Ion Battery Cathode

2021

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Manganese‐based oxide is arguably one of the most well‐studied cathode materials for zinc‐ion battery (ZIB) due to its wide oxidation states, cost‐effectiveness, and matured synthesis process. As a result, there are numerous reports that show significant strides in the progress of Mn‐based oxides as ZIB cathode. However, ironically, due to the sheer number of Mn‐based oxides that have been published in recent years, there remain certain contemplations with regards to the electrochemical performance of each type of Mn‐based oxides and their performance comparison among various Mn polymorphs and oxidation states. Thus, to provide a clearer indication of the development of Mn‐based oxides, the recent progress in Mn‐based oxides as ZIB cathode was summarized systematically in this Review. More specifically, (1) the classification of Mn‐based oxides based on the oxidation states (i. e., MnO2, Mn3O4, Mn2O3, and MnO), (2) their respective polymorphs (i. e., α‐MnO2 and δ‐MnO2) as ZIB cathode, (3) the modification strategies commonly employed to enhance the performance, and (4) the effects of these modification strategies on the performance enhancement were reviewed. Lastly, perspectives and outlook of Mn‐based oxides as ZIB cathode were discussed at the end of this Review.

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“…Only a few manganese oxides can be cathode materials for ZIBs [171]. Mn 3 O 4 is an important one, in which the valence of [180] with permission from Springer Verlag.…”

Section: Mn 3 Omentioning

confidence: 99%