High‐Performance Platinum‐Perovskite Composite Bifunctional Oxygen Electrocatalyst for Rechargeable Zn–Air Battery

Wang, Xixi; Sunarso, Jaka; Lü, Qian; Zhou, Ziling; Dai, Jie; Guan, Daqin; Zhou, Wei; Shao, Zongping

doi:10.1002/aenm.201903271

Cited by 101 publications

(71 citation statements)

References 68 publications

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“…The performance and stability were also compared with Pt/C+IrO 2 catalyst (both 3 mg cm −2 ). Though the Pt/C+IrO 2 catalyst demonstrated better PPD (224 mW cm −2 ) (Figure 3b) and lower Δ V (0.72 V) than Co−MnO 2 (Figure 3c), it presented inferior cycling stability (Figure 3d), which was also reflected by other previous reports [27,67] . As displayed in Figure 3e, Co−MnO 2 also showed decent high‐rate performance with Δ V of ∼0.6 and ∼1.0 V at 1 and 30 mA cm −2 , respectively.…”

Section: Resultssupporting

confidence: 75%

Facilitating Oxygen Redox on Manganese Oxide Nanosheets by Tuning Active Species and Oxygen Defects for Zinc‐Air Batteries

Zhong

Dai

et al. 2020

ChemElectroChem

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Bifunctional oxygen catalyst is an important component in the cathode for rechargeable zinc‐air batteries. MnO2 catalysts have aroused intense interests owing to their promising activity for oxygen reduction reaction (ORR), which, however, is still not comparable to precious metal catalysts. To improve the ORR catalysis and meet the requirement for a bifunctional oxygen catalyst, MnO2 nanosheets are modified with Co, Ni or Fe via a facile solution‐based method. Among the modified samples, Co−MnO2 presents improved catalysis for both ORR and oxygen evolution reaction (OER). The modification introduces additional active sites for OER and induced more oxygen defects to further facilitate the ORR. Zn‐air batteries with the Co−MnO2 air cathode showed a higher peak power density of 167 mW cm−2, a lower potential gap of 0.75 V and a higher round‐trip efficiency of 63 % (5 mA cm−2) compared to MnO2 without modification. Good cycling stability of the battery is also achieved. The proper amount of cobalt species in the MnO2 is vital for achieving a balance between high performance and durable cycling.

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Section: Resultssupporting

confidence: 75%

Facilitating Oxygen Redox on Manganese Oxide Nanosheets by Tuning Active Species and Oxygen Defects for Zinc‐Air Batteries

Zhong

Dai

et al. 2020

ChemElectroChem

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“…echargeable Zn-air batteries (ZABs) with four-time higher theoretical energy density, better safety, and lower cost are commonly considered as one of the most promising replacements for Li-ion batteries [1][2][3][4][5] . These superiorities mainly originate from oxygen-based electrochemistry in aqueous systems, but their full potential has yet to be realized because of high polarization and short lifespan at the air cathodes [6][7][8] . As such, the core of ZABs development lies in exploring air cathodes that are capable of efficiently catalyzing both oxygen reduction (ORR) and evolution reactions (OER) for long working periods [9][10][11][12] .…”

mentioning

confidence: 99%

d-Orbital steered active sites through ligand editing on heterometal imidazole frameworks for rechargeable zinc-air battery

et al. 2020

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The implementation of pristine metal-organic frameworks as air electrode may spark fresh vitality to rechargeable zinc-air batteries, but successful employment is rare due to the challenges in regulating their electronic states and structural porosity. Here we conquer these issues by incorporating ligand vacancies and hierarchical pores into cobalt-zinc heterometal imidazole frameworks. Systematic characterization and theoretical modeling disclose that the ligand editing eases surmountable energy barrier for *OH deprotonation by its efficacy to steer metal d-orbital electron occupancy. As a stride forward, the selected cobalt-zinc heterometallic alliance lifts the energy level of unsaturated d-orbitals and optimizes their adsorption/desorption process with oxygenated intermediates. With these merits, cobalt-zinc heterometal imidazole frameworks, as a conceptually unique electrode, empowers zinc-air battery with a discharge-charge voltage gap of 0.8 V and a cyclability of 1250 h at 15 mA cm–2, outperforming the noble-metal benchmarks.

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“…On the other hand, the Ni x Co 1− x S 2 may provide a redox‐active surface for facilitating the redeposition of the dissolved Mn species. [ 62 ] The above excellent high‐rate galvanostatic charge–discharge performance and good cycling stability of the function‐separated MnS–Ni x Co 1− x S 2 electrode are better than most advanced cathodes for hybrid Zn batteries [ 15–18,23,26,29 ] and for Zn–air batteries, [ 31,63–72 ] as compared in Table S1 (Supporting Information).…”

Section: Resultsmentioning

confidence: 99%

A Function‐Separated Design of Electrode for Realizing High‐Performance Hybrid Zinc Battery

Zhong

Liu

et al. 2020

Advanced Energy Materials

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A rechargeable hybrid zinc battery is developed for reaching high power density and high energy density simultaneously by introducing an alkaline Zn–transition metal compound (Zn–MX) battery function into a Zn–air battery. However, the conventional single‐layer electrode design cannot satisfy the requirements of both a hydrophilic interface for facilitating ionic transfer to maximize the Zn–MX battery function and a hydrophobic interface for promoting gas diffusion to maximize the Zn–air battery function. Here, a function‐separated design is proposed, which allocates the two battery functions to the two faces of the cathode. The electrode is composed of a hydrophobic MnS layer decorated with Ni–Co–S nanoclusters that allows for smooth gas diffusion and efficient oxygen electrocatalysis and a hydrophilic NixCo1−xS2 layer that favors fast ionic transfer and superior performance for energy storage. The battery with the function‐separated electrode shows a high short‐term discharge voltage of ≈1.7 V, an excellent high‐rate galvanostatic discharge–charge with a power density up to 153 mW cm−2 at 100 mA cm−2, a good round‐trip efficiency of 75% at 5 mA cm−2, and a robust cycling stability for 330 h with an excellent voltage gap of ≈0.7 V at 5 mA cm−2.

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High‐Performance Platinum‐Perovskite Composite Bifunctional Oxygen Electrocatalyst for Rechargeable Zn–Air Battery

Cited by 101 publications

References 68 publications

Facilitating Oxygen Redox on Manganese Oxide Nanosheets by Tuning Active Species and Oxygen Defects for Zinc‐Air Batteries

Facilitating Oxygen Redox on Manganese Oxide Nanosheets by Tuning Active Species and Oxygen Defects for Zinc‐Air Batteries

d-Orbital steered active sites through ligand editing on heterometal imidazole frameworks for rechargeable zinc-air battery

A Function‐Separated Design of Electrode for Realizing High‐Performance Hybrid Zinc Battery

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