Translating Materials-Level Performance into Device-Relevant Metrics for Zinc-Based Batteries

Parker, Joseph F.; Ko, Jesse S.; Rolison, Debra R.; Long, Jeffrey W.

doi:10.1016/j.joule.2018.11.007

Cited by 154 publications

(127 citation statements)

References 31 publications

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“…Their problems are oen diluted or completely ignored in previous studies by using excessive amounts of Zn metals and electrolytes. 50,51 We note that the depth of discharge (DOD) in previous studies is mostly very low and even <1% for rechargeable batteries so as to maximize the impact of air cathodes. Such shallow discharges barely challenge Zn anodes.…”

Section: Zn Electrodementioning

confidence: 92%

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Zinc–air batteries: are they ready for prime time?

et al. 2019

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Section: Zn Electrodementioning

confidence: 92%

“…There are few demonstrations about fully cyclable Zn anodes for >100 cycles. 51 An alternative approach to improve the anode cyclability is to use non-alkaline electrolytes. Near-neutral aqueous electrolytes (e.g.…”

Section: Zn Electrodementioning

confidence: 99%

Zinc–air batteries: are they ready for prime time?

et al. 2019

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“…Operated in non-flammable aqueous electrolyte,a queous zinc batteries (AZBs) are considered amuch safer alternative to LIBs. [8][9][10][11][12] Furthermore,A ZBs also possess other advantages,including non-toxicity,low cost, and minimum requirements regarding the atmosphere. [13,14] In the last decade,most efforts are focused on enhancing battery performance (capacity delivery,c ycling stability,o rr ate property) of cathode materials in AZBs,i ncluding active materials of manganese oxides, [15][16][17] vanadate compounds, [18] Prussian blue, [19] organic cathode, [20] and so on.…”

Section: Introductionmentioning

confidence: 99%

An Interface‐Bridged Organic–Inorganic Layer that Suppresses Dendrite Formation and Side Reactions for Ultra‐Long‐Life Aqueous Zinc Metal Anodes

et al. 2020

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Aqueous zinc (Zn) batteries (AZBs) are widely considered as a promising candidate for next‐generation energy storage owing to their excellent safety features. However, the application of a Zn anode is hindered by severe dendrite formation and side reactions. Herein, an interfacial bridged organic–inorganic hybrid protection layer (Nafion‐Zn‐X) is developed by complexing inorganic Zn‐X zeolite nanoparticles with Nafion, which shifts ion transport from channel transport in Nafion to a hopping mechanism in the organic–inorganic interface. This unique organic–inorganic structure is found to effectively suppress dendrite growth and side reactions of the Zn anode. Consequently, the Zn@Nafion‐Zn‐X composite anode delivers high coulombic efficiency (ca. 97 %), deep Zn plating/stripping (10 mAh cm−2), and long cycle life (over 10 000 cycles). By tackling the intrinsic chemical/electrochemical issues, the proposed strategy provides a versatile remedy for the limited cycle life of the Zn anode.

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“…[ 1–6 ] Further, compared with rechargeable batteries that use organic solvents, aqueous batteries exhibit significantly higher ionic conductivities and better cost efficiencies. [ 7–9 ] Moreover, Zn is an attractive anode material owing to its low toxicity, natural abundance, high safety in humid conditions, low redox potential (−0.76 V vs standard hydrogen electrode (SHE)), and high theoretical capacity (820 mAh g −1 ). [ 10–15 ] Despite the advantages of Zn ion batteries, improved anodes are still required because conventional Zn metal electrodes show inferior stability in aqueous electrolytes.…”

Section: Introductionmentioning

confidence: 99%

Functionalized Zn@ZnO Hexagonal Pyramid Array for Dendrite‐Free and Ultrastable Zinc Metal Anodes

Kim

Liu

Shim

et al. 2020

Adv Funct Materials

174

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Here, an electrode comprising a Zn hexagonal pyramid array (HPA) coated with a functionalized ZnO layer (Zn@ZnO HPA) is prepared using a periodic anodizing technique. The HPA structure markedly increases the electroactive surface area of Zn anode, thus decreasing the local current density. Furthermore, the functionalized ZnO coating layer has a gradient thickness that plays an important role in the selective deposition of Zn ions and the mitigation of side reactions at the interface. The electrochemical stability of the Zn@ZnO HPA electrode, which is closely related to the electroactive surface area and charge transfer resistance, is determined by the “split” value, i.e., ratio of current‐off to current‐on time, a parameter of the periodic anodizing process. Compared with the pristine Zn‐based symmetric cell, the Zn@ZnO HPA‐based symmetric cell is safely operated in the investigated experimental range with the 10‐fold improved running life and 25‐fold enhanced current density without Zn dendrite growth. Moreover, the Zn@ZnO HPA/MnO2 battery exhibits outstanding long‐term cyclability (nearly 100%) with greater than 99% Coulombic efficiency after 1000 cycles at a current density of 9 A g−1. This periodic anodizing technique for ultrastable Zn metal anodes is expected to contribute to the development of inherently safe energy storage systems.

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Translating Materials-Level Performance into Device-Relevant Metrics for Zinc-Based Batteries

Cited by 154 publications

References 31 publications

Zinc–air batteries: are they ready for prime time?

Zinc–air batteries: are they ready for prime time?

An Interface‐Bridged Organic–Inorganic Layer that Suppresses Dendrite Formation and Side Reactions for Ultra‐Long‐Life Aqueous Zinc Metal Anodes

Functionalized Zn@ZnO Hexagonal Pyramid Array for Dendrite‐Free and Ultrastable Zinc Metal Anodes

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