Electrochemical Performance of MnO<sub>2</sub>‐based Air Cathodes for Zinc‐air Batteries

Li, G.; Mezaal, Mohammed Adnan; Zhang, R.; Zhang, K.; Lei, Lixu

doi:10.1002/fuce.201500077

Cited by 22 publications

(18 citation statements)

References 26 publications

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“…By this, the above‐mentioned phenomena (e. g., s. Figure 5a+b, marker 6*) are disappearing or getting weaker with proceeding cycling through the decrease of overpotentials, and the accumulation of the afore‐mentioned Zn 2+ /Mn 2+ hexaaquo complexes. For the 0.9 mM H 2 SO 4 (a), the presence of the ORR during the initial discharge cycle could explain the excess discharge capacities (s. Figure 4), the strong pH increase (s. Figure 5a, marker 2) and the reduction current peak at low potentials during only the initial CV cycle (s. Figure 6a, marker 1). According to the sluggish reaction kinetics of the ORR, this reaction is only enabled for this electrolyte due to the high overpotentials and discharge potential shifts (s. literature of metal‐air batteries, e. g.) [52–56] . For the 0.5 M MnSO 4 (b) electrolyte, the CV measurement (s. Figure 6b) showed the same characteristic of the current peaks of a MnO 2 deposition/dissolution process as seen in other publications [35,61–64] …”

Section: Resultssupporting

confidence: 60%

“…Therefore, the Mn 2+ /MnO 2 deposition/dissolution mechanism could be taken as the main explanatory approach for the generation of capacity. Furthermore, at least for the initial discharge cycle, the presence of the ORR (s. metal‐air batteries including MnO 2 as catalyst for the ORR at the cathode) [52–56] in consequence of the high overpotential could contribute to the discharge capacity. Interestingly, the cycling of symmetrical MnO 2 //MnO 2 cells (for details, s. Figure S1, Supporting Information) still showed a comparable behaviour, underlining the above‐mentioned interpretations and the major influence of Mn 2+ /MnO 2 deposition/dissolution mechanisms.…”

Section: Resultsmentioning

confidence: 99%

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Electrolyte Study with in Operando pH Tracking Providing Insight into the Reaction Mechanism of Aqueous Acidic Zn//MnO₂ Batteries

et al. 2021

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The reaction mechanisms (RM) during cycling of aqueous rechargeable Zn//MnO2 batteries (ARZIBs) are still controversially discussed. The present study of different acidic electrolyte compositions (0.9 mM H2SO4, 0.5 M MnSO4, 2 M ZnSO4, 2 M ZnSO4+0.5 M MnSO4) and their pH behaviour is therefore designed as an alternative approach to investigate the RM. In operando pH tracking during cycling shows periodic pH changes for each electrolyte, highlighting the role of the pH‐relevant ions OH− and H+ in the chemical processes, the major influence of MnO2 deposition/dissolution mechanisms and the buffering behaviour of the zinc hydroxide sulphate (ZHS) precipitation. Innovative coupled cyclic voltammetry (CV) and pH measurements can link CV redox peaks to a pH change and a corresponding chemical reaction. It was found that a Zn2+ (de‐)intercalation has little or no influence on the capacity. The cycling of the SO42−‐free electrolyte 2 M Zn(CF3SO3)2 underlines the pH‐dependant behaviour of the chemical processes. The results can contribute to the debate of RMs in ARZIBs and other aqueous battery chemistries by introducing a novel measurement technique.

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Section: Resultssupporting

confidence: 60%

Section: Resultsmentioning

confidence: 99%

Electrolyte Study with in Operando pH Tracking Providing Insight into the Reaction Mechanism of Aqueous Acidic Zn//MnO₂ Batteries

et al. 2021

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“…For decades, transitional metal oxides have been extensively used as a promising electrocatalyst for ORR. Manganese oxides (MnO x ) have attracted much attention due to its high electrocatalytic activity, availability, low cost, and benign nature . Despite its poor stability in acidic medium, MnO x can be employed as a favorable electrocatalyst for cathodic reduction of oxygen in both AFCs and metal air batteries.…”

Section: Introductionmentioning

confidence: 91%

Chitosan‐Derived NiO‐Mn₂O₃/C Nanocomposites as Non‐Precious Catalysts for Enhanced Oxygen Reduction Reaction

et al. 2018

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NiO‐Mn2O3/C nanocomposite was synthesized from chitosan, a renewable biopolymer, NiO and MnO2 and pyrolyzed at 500 °C under nitrogen. The morphology of material was characterized with various microscopic analyses. The graphitic carbon showed metal nanoparticles dispersed on the nanocomposite that could be clearly differentiated. X‐ray photoelectron spectroscopy indicated the Mn species reduced from +4 to +3 oxidation state, while Ni species remained as NiO, which was further supported by X‐ray diffraction. The electrochemical behavior of NiO‐Mn2O3/C toward oxygen reduction reaction (ORR) in alkaline medium was investigated via cyclic voltammetry (CV). CVs revealed a ORR peak at 0.67 V vs. RHE with significantly high current density. Hydrodynamic studies indicated that NiO‐Mn2O3/C catalyzed ORR via a four‐electron reduction pathway. A high rate constant in the order of magnitude of 106 mol−1s−1 was obtained for ORR. This low‐cost, environmentally friendly and stable ORR catalyst derived from chitosan and doped with metal oxides proved to be a promising electrocatalyst for ORR and could alternatively find its application in alkaline fuel cells (AFCs).

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“…Plentiful materials have appeared in the area of ORR electrocatalysts, including noble metals and their alloys, transitional metals, metal oxides/chalcogenides/carbides/nitrides, carbon nanomaterials, and their composites . However, different reaction mechanisms may happen on the surface of different catalysts . The 2‐electron reduction path is favored on most of nanocarbons and transitional metal based composites, while the direct 4‐electron reduction is favored on noble metal‐based catalysts .…”

Section: Primary Zn–air Batteriesmentioning

confidence: 99%

Advanced Architectures and Relatives of Air Electrodes in Zn–Air Batteries

et al. 2018

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Zn–air batteries are becoming the promising power sources for portable and wearable electronic devices and hybrid/electric vehicles because of their high specific energy density and the low cost for next‐generation green and sustainable energy technologies. An air electrode integrated with an oxygen electrocatalyst is the most important component and inevitably determines the performance and cost of a Zn–air battery. This article presents exciting advances and challenges related to air electrodes and their relatives. After a brief introduction of the Zn–air battery, the architectures and oxygen electrocatalysts of air electrodes and relevant electrolytes are highlighted in primary and rechargeable types with different configurations, respectively. Moreover, the individual components and major issues of flexible Zn–air batteries are also highlighted, along with the strategies to enhance the battery performance. Finally, a perspective for design, preparation, and assembly of air electrodes is proposed for the future innovations of Zn–air batteries with high performance.

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Electrochemical Performance of MnO₂‐based Air Cathodes for Zinc‐air Batteries

Cited by 22 publications

References 26 publications

Electrolyte Study with in Operando pH Tracking Providing Insight into the Reaction Mechanism of Aqueous Acidic Zn//MnO₂ Batteries

Electrolyte Study with in Operando pH Tracking Providing Insight into the Reaction Mechanism of Aqueous Acidic Zn//MnO₂ Batteries

Chitosan‐Derived NiO‐Mn₂O₃/C Nanocomposites as Non‐Precious Catalysts for Enhanced Oxygen Reduction Reaction

Advanced Architectures and Relatives of Air Electrodes in Zn–Air Batteries

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Electrochemical Performance of MnO2‐based Air Cathodes for Zinc‐air Batteries

Cited by 22 publications

References 26 publications

Electrolyte Study with in Operando pH Tracking Providing Insight into the Reaction Mechanism of Aqueous Acidic Zn//MnO2 Batteries

Electrolyte Study with in Operando pH Tracking Providing Insight into the Reaction Mechanism of Aqueous Acidic Zn//MnO2 Batteries

Chitosan‐Derived NiO‐Mn2O3/C Nanocomposites as Non‐Precious Catalysts for Enhanced Oxygen Reduction Reaction

Advanced Architectures and Relatives of Air Electrodes in Zn–Air Batteries

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Product

Resources

About

Electrochemical Performance of MnO₂‐based Air Cathodes for Zinc‐air Batteries

Electrolyte Study with in Operando pH Tracking Providing Insight into the Reaction Mechanism of Aqueous Acidic Zn//MnO₂ Batteries

Electrolyte Study with in Operando pH Tracking Providing Insight into the Reaction Mechanism of Aqueous Acidic Zn//MnO₂ Batteries

Chitosan‐Derived NiO‐Mn₂O₃/C Nanocomposites as Non‐Precious Catalysts for Enhanced Oxygen Reduction Reaction