Regenerable Cu-intercalated MnO2 layered cathode for highly cyclable energy dense batteries

Yadav, Gautam G.; Gallaway, Joshua W.; Turney, Damon E.; Nyce, Michael; Huang, Jinchao; Wei, Xia; Banerjee, Sanjoy

doi:10.1038/ncomms14424

Cited by 224 publications

(227 citation statements)

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“…In fact, for the active materials in aqueous ZIBs and some other rechargeable aqueous batteries, their structure and phase generally undergo complex changes during charge/discharge processes (e.g., the active materials can interact with not only metal ions, but also H + , OH − , and water molecules) [39]. This is an important reason why the energy storage mechanism of MnO 2 cathode in ZIBs is still inconclusive [40][41][42][43].…”

Section: Introductionmentioning

confidence: 99%

Novel Insights into Energy Storage Mechanism of Aqueous Rechargeable Zn/MnO2 Batteries with Participation of Mn2+

et al. 2019

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HIGHLIGHTS• Pourbaix diagram of Mn-Zn-H 2 O system was used to analyze the charge-discharge processes of Zn/MnO 2 batteries.• Electrochemical reactions with the participation of various ions inside Zn/MnO 2 batteries were revealed.• A detailed explanation of phase evolution inside Zn/MnO 2 batteries was provided.ABSTRACT Aqueous rechargeable Zn/MnO 2 zinc-ion batteries (ZIBs) are reviving recently due to their low cost, non-toxicity, and natural abundance.However, their energy storage mechanism remains controversial due to their complicated electrochemical reactions. Meanwhile, to achieve satisfactory cyclic stability and rate performance of the Zn/MnO 2 ZIBs, Mn 2+ is introduced in the electrolyte (e.g., ZnSO 4 solution), which leads to more complicated reactions inside the ZIBs systems. Herein, based on comprehensive analysis methods including electrochemical analysis and Pourbaix diagram, we provide novel insights into the energy storage mechanism of Zn/MnO 2 batteries in the presence of Mn 2+ . A complex series of electrochemical reactions with the coparticipation of Zn 2+ , H + , Mn 2+ , SO 4 2− , and OH − were revealed. During the first discharge process, co-insertion of Zn 2+ and H + promotes the transformation of MnO 2 into Zn x MnO 4 , MnOOH, and Mn 2 O 3 , accompanying with increased electrolyte pH and the formation of ZnSO 4 ·3Zn(OH) 2 ·5H 2 O. During the subsequent charge process, Zn x MnO 4 , MnOOH, and Mn 2 O 3 revert to α-MnO 2 with the extraction of Zn 2+ and H + , while ZnSO 4 ·3Zn(OH) 2 ·5H 2 O reacts with Mn 2+ to form ZnMn 3 O 7 ·3H 2 O. In the following charge/discharge processes, besides aforementioned electrochemical reactions, Zn 2+ reversibly insert into/extract from α-MnO 2 , Zn x MnO 4 , and ZnMn 3 O 7 ·3H 2 O hosts; ZnSO 4 ·3Zn(OH) 2 ·5H 2 O, Zn 2 Mn 3 O 8 , and ZnMn 2 O 4 convert mutually with the participation of Mn 2+ . This work is believed to provide theoretical guidance for further research on high-performance ZIBs.

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Section: Introductionmentioning

confidence: 99%

Novel Insights into Energy Storage Mechanism of Aqueous Rechargeable Zn/MnO2 Batteries with Participation of Mn2+

et al. 2019

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“…Layered δ‐MnO 2 was synthesized for rechargeable aqueous Zn batteries using simple hydrothermal method according to previous report . The crystal structure of δ‐MnO 2 is made of loosely bound layers of edge‐shared MnO 6 located on the (001) plane (Figure ).…”

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confidence: 99%

Joint Charge Storage for High‐Rate Aqueous Zinc–Manganese Dioxide Batteries

et al. 2019

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Aqueous rechargeable zinc–manganese dioxide batteries show great promise for large‐scale energy storage due to their use of environmentally friendly, abundant, and rechargeable Zn metal anodes and MnO2 cathodes. In the literature various intercalation and conversion reaction mechanisms in MnO2 have been reported, but it is not clear how these mechanisms can be simultaneously manipulated to improve the charge storage and transport properties. A systematical study to understand the charge storage mechanisms in a layered δ‐MnO2 cathode is reported. An electrolyte‐dependent reaction mechanism in δ‐MnO2 is identified. Nondiffusion controlled Zn2+ intercalation in bulky δ‐MnO2 and control of H+ conversion reaction pathways over a wide C‐rate charge–discharge range facilitate high rate performance of the δ‐MnO2 cathode without sacrificing the energy density in optimal electrolytes. The Zn‐δ‐MnO2 system delivers a discharge capacity of 136.9 mAh g−1 at 20 C and capacity retention of 93% over 4000 cycles with this joint charge storage mechanism. This study opens a new gateway for the design of high‐rate electrode materials by manipulating the effective redox reactions in electrode materials for rechargeable batteries.

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“…− cycling, 0.1 C rate) in addition to noting synergistic effects when combining these additives. 27 Overall, with the exception of the work of Yadav et al, 16 stabilization of the MnO 2 cathode has been observed but mainly at non-practical low mass loadings (< 50%) and/or with thin electrodes (< 100 μm thick). Zn anode additives intended to reduce hydrogen evolution, mitigate shape change, suppress dendrite formation, and slow Zn transport have also been reported in the literature including In, 36 Bi, 36 Pb, 36 carboxymethyl cellulose, 37 tartaric acid, 38 polyethylene glycol (PEG), 38 Ca(OH) 2 , 6,39 tetra-alkyl ammonium hydroxides, 40 and sodium dodecylbenzene sulfonate (SDBS).…”

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confidence: 99%

“…These Bi and Cu stabilized MnO 2 cathodes have delivered the highest areal capacities for MnO 2 electrodes to date (∼29 mAh cm −2 , 60 wt% loading, 0.046 cm thick). 16 While a remarkable achievement, the MnO 2 electrodes are still susceptible to Zn poisoning (irreversibly forming ZnMn 2 O 4 ) and also required initial cycling versus a Ni(OH) 2 counter electrode in order to "form" the electrodes before they could be paired with a Zn anode to form the Zn/MnO 2 battery. 16,17 Comparatively, >900 cycles were achieved when a modified MnO 2 electrode was cycled against a Zn anode under relatively high Zn utilization conditions (∼15% DOD on Zn).…”

mentioning

confidence: 99%

“…16 While a remarkable achievement, the MnO 2 electrodes are still susceptible to Zn poisoning (irreversibly forming ZnMn 2 O 4 ) and also required initial cycling versus a Ni(OH) 2 counter electrode in order to "form" the electrodes before they could be paired with a Zn anode to form the Zn/MnO 2 battery. 16,17 Comparatively, >900 cycles were achieved when a modified MnO 2 electrode was cycled against a Zn anode under relatively high Zn utilization conditions (∼15% DOD on Zn). 17 This was achieved by employing a Ca(OH) 2 membrane as a separator which has been demonstrated to sequester Zn and prevent its transport to the cathode.…”

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confidence: 99%

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Impact of Triethanolamine as an Additive for Rechargeable Alkaline Zn/MnO₂Batteries under Limited Depth of Discharge Conditions

Kelly

Duay

Lambert

et al. 2017

J. Electrochem. Soc.

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Rechargeable alkaline Zn/MnO 2 batteries are being developed for use as cost-effective grid-scale energy storage devices. Previous studies have shown that limiting the depth of discharge (DOD) of the MnO 2 cathode extends cell lifetime while still providing a cost-effective battery system. Herein, a comprehensive study of triethanolamine (TEA) as an additive in Zn/MnO 2 limited DOD batteries is provided by examining the effect of TEA in full cells as well as independently on the cathode, anode, separator, and electrolyte. Improvement in cycle-ability of the cathode (on average, 80% of cycled capacity remains after 191 cycles without TEA, 568 cycles with TEA) and a decrease in ionic zinc mobility across Celgard 3501 (7.91 × 10 −5 cm 2 /min without TEA, 3.56 × 10 −5 cm 2 /min with TEA) and Cellophane 350P00 (3.26 × 10 −5 cm 2 /min without TEA, 4.74 × 10 −6 cm 2 /min with TEA) separators upon the addition of TEA are demonstrated. However, TEA increased both the reduction potential of Zn (−0.68 V vs. Hg/HgO without TEA, −0.76 V with TEA) and the solubility of Zn 2+ (0.813 M without TEA, 1.023 M with TEA). Overall, the addition of TEA extended the lifetime of limited DOD cells on average by 297%.

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Regenerable Cu-intercalated MnO2 layered cathode for highly cyclable energy dense batteries

Cited by 224 publications

References 66 publications

Novel Insights into Energy Storage Mechanism of Aqueous Rechargeable Zn/MnO2 Batteries with Participation of Mn2+

Novel Insights into Energy Storage Mechanism of Aqueous Rechargeable Zn/MnO2 Batteries with Participation of Mn2+

Joint Charge Storage for High‐Rate Aqueous Zinc–Manganese Dioxide Batteries

Impact of Triethanolamine as an Additive for Rechargeable Alkaline Zn/MnO₂Batteries under Limited Depth of Discharge Conditions

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Regenerable Cu-intercalated MnO2 layered cathode for highly cyclable energy dense batteries

Cited by 224 publications

References 66 publications

Novel Insights into Energy Storage Mechanism of Aqueous Rechargeable Zn/MnO2 Batteries with Participation of Mn2+

Novel Insights into Energy Storage Mechanism of Aqueous Rechargeable Zn/MnO2 Batteries with Participation of Mn2+

Joint Charge Storage for High‐Rate Aqueous Zinc–Manganese Dioxide Batteries

Impact of Triethanolamine as an Additive for Rechargeable Alkaline Zn/MnO2Batteries under Limited Depth of Discharge Conditions

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Impact of Triethanolamine as an Additive for Rechargeable Alkaline Zn/MnO₂Batteries under Limited Depth of Discharge Conditions