Progress in Rechargeable Aqueous Zinc‐ and Aluminum‐Ion Battery Electrodes: Challenges and Outlook

Verma, Vivek; Kumar, Sonal; Manalastas, William; Satish, Rohit; Srinivasan, Madhavi

doi:10.1002/adsu.201800111

Cited by 157 publications

(159 citation statements)

References 202 publications

Supporting

Mentioning

149

Contrasting

Unclassified

Order By: Relevance

“…iii) Radius of Zn 2+ . Zn 2+ can tightly coordinate with water to form hydrated Zn 2+ ([Zn(H 2 O) 6 ] 2+ ), which inserted into the host cathode in different ways . When the ion‐channel size is not large enough to accommodate the hydrated Zn 2+ , desolvation could happen for the successful cation intercalation …”

Section: Energy Storage Mechanism Of Zibsmentioning

confidence: 99%

Flexible Zn‐Ion Batteries: Recent Progresses and Challenges

Zeng

Zhang

et al. 2019

Small

442

307

View full text Add to dashboard Cite

the developing trend of modern electronic technologies, [6] and significant efforts have been devoted to transforming these energy storage systems to their light, flexible, small, and thin counterparts. [7] The flexible battery market is forecast to increase rapidly from $69.6 million in 2015 to $958.4 million in 2022. [8] Lithium-ion batteries (LIBs) historically and presently dominant the markets of rechargeablebattery for portable devices because of the lightness of lithium and high energy density of the battery systems. [9,10] Nonetheless, LIBs are marred by the high cost and the shortage of lithium resources. Moreover, the aprotic electrolytes used in LIBs are generally toxic and flammable. This fact causes great safety issues for LIBs, especially when they are used in wearable/implantable applications in close contact with human body. It is highly challenging to assemble flexible LIBs due to the requirement of a highly reliable protective packaging to avoid the electrolyte leakage and reconcile with the washing need of wearable devices in practical applications. [3] Moreover, due to the high barrier encapsulation, the volumetric performance would be severely restricted, especially when LIBs are miniaturized. In this context, it is highly desirable to prepare flexible "beyond Li-based" batteries with safe, low-cost, and eco-friendly aqueous electrolytes. [11] As alternatives for LIBs, multivalent ion battery technologies (Zn-ion battery, ZIB, Mg-ion battery, and Al-ion battery) are of high interest for electrochemical energy storage. In comparison with LIBs operating with single-electron transfer, multivalent ion batteries employ multielectron transfer during the charge/ discharge processes, thus delivering much higher volumetric energy densities. [12][13][14] Since the first utilization of Zn in batteries in 1799, [15] Zn metal has captured increasing attention as an ideal anode material. In earlier studies, Zn anodes were widely explored in many alkaline battery systems, such as alkaline zinc-MnO 2 batteries, [16] zinc-nickel batteries, [17][18][19][20] zinc-silver batteries, [21] and zinc-air batteries. [22][23][24] Zn metal is able to offering both high gravimetric and high volumetric capacities (820 and 5855 mAh cm −3 ). [25] Moreover, Zn has the merits of low cost, low-toxicity, abundance in earth crust (≈300 times higher than for lithium), environmental benignity, easily recyclable, and intrinsic safety. [14,26] These advantages directly drove the recent renaissance of Zn anode based batteries. [15] However, the use of corrosive alkaline electrolyte leads to the Zn-dendritic (sharp, needle-like metallic protrusions) growth [27,28] and soluble ZnO 2 2− formation on Zn anode, which poison the cathode and result in the rapid capacity To keep pace with the increasing pursuit of portable and wearable electronics, it is urgent to develop advanced flexible power supplies. In this context, Zn-ion batteries (ZIBs) have garnered increasing attention as favorable energy storage devices for flexible electronics, ...

show abstract

Section: Energy Storage Mechanism Of Zibsmentioning

confidence: 99%

Flexible Zn‐Ion Batteries: Recent Progresses and Challenges

Zeng

Zhang

et al. 2019

Small

442

307

View full text Add to dashboard Cite

show abstract

“…In tetragonal λ‐MnO 2 , Zn 2+ diffuses from 8a‐sites to neighboring 8a‐sites through 16c‐sites; however, Mn atoms at 16d‐sites (close to 16c‐sites) hinder the movement of Zn 2+ by electrostatic repulsion 81 . These findings confirm that further architecture modification is necessary for spinel‐type samples like λ‐MnO 2 and ZnMn 2 O 4 to become qualified Zn 2+ hosts considering their limited 3D tunnels and strong electrostatic repulsion toward Zn 2+ 26,38,39,48,67 . As shown in Figure 6, a treatment on the ZnMn 2 O 4 lattice was carried out to produce Mn vacancies or deficiencies by extracting oxygen anions, which lowers the electrostatic barrier for Zn 2+ transfer and alleviates the Mn species dissolution due to the higher Mn oxidation state.…”

Section: Crystal Structures Of Manganese Oxidesmentioning

confidence: 54%

Flexible Zn‐ion batteries based on manganese oxides: Progress and prospect

et al. 2020

View full text Add to dashboard Cite

The ever‐growing market of wearable electronic devices has greatly stimulated the rapid development of flexible Zn‐ion batteries (ZIBs). Manganese oxides are one of the most commonly used hosts for zinc ion accommodation and thus receive particular research interest for high‐performance flexible ZIB constructions. In this review, a comprehensive summary of the recent development of flexible ZIBs with manganese oxides as cathode materials is presented. Apart from the brief introduction of flexible electronic devices and ZIBs, the charge storage mechanisms and crystal structures of various manganese oxides are summarized. Modifications of the cathode materials in terms of morphology, conductivity, structures, and flexibilities are illustrated in detail, together with the demonstration of structure‐performance relationships and applications in flexible ZIBs. Finally, limitations to be overcome are indicated and the future work directions are proposed.

show abstract

“…The basic reason lies in the dissolution of Mn 2+ into the aqueous electrolyte, which leads to a change of stoichiometry and potential lattice rearrangement. Figure 3A shows the structure of an α‐MnO 2 , which has a 2 × 2 tunnel structure with corner‐sharing MnO 6 octahedra 34 . By comparing the XRD patterns of a Zn 2+ ‐intercalated α‐MnO 2 , Lee et al 43 found that the structure turned into a birnessite‐MnO 2 , which is similar with α‐MnO 2 except that the α‐MnO 2 layers are disconnected by one octahedral vacancy and are separated by two vertically aligned MnO 6 octahedra.…”

Section: Roles Of Water In Different Materialsmentioning

confidence: 99%

Intercalated water in aqueous batteries

Xiao

2020

Carbon Energy

View full text Add to dashboard Cite

The unprecedentedly growing demand for energy storage devices in recent years calls for diversified chemistries with unique advantages. When it comes to safety and cost, aqueous battery systems have attracted tremendous attention. Owing to its small size, high polarity, and hydrogen bonding, water in the electrode materials, either in the form of structural water or cointercalated hydrated cations, drastically change the electrochemical behavior through multiple aspects. This review discusses the roles of water in aqueous batteries from how water molecules coordinate with cations to examples of water‐mediated reactions in different types of host materials.

show abstract

Progress in Rechargeable Aqueous Zinc‐ and Aluminum‐Ion Battery Electrodes: Challenges and Outlook

Cited by 157 publications

References 202 publications

Flexible Zn‐Ion Batteries: Recent Progresses and Challenges

Flexible Zn‐Ion Batteries: Recent Progresses and Challenges

Flexible Zn‐ion batteries based on manganese oxides: Progress and prospect

Intercalated water in aqueous batteries

Contact Info

Product

Resources

About