High Performance Na–CuCl<sub>2</sub> Rechargeable Battery toward Room Temperature ZEBRA‐Type Battery

Kim, Boram; Jeong, Goojin; Kim, Ayoung; Kim, Youngkwon; Kim, Min; Kim, Hansu; Kim, Young‐Jun

doi:10.1002/aenm.201600862

Cited by 29 publications

(19 citation statements)

References 35 publications

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“…New types of rechargeable Na‐metal‐based batteries, such as RT sodium‐sulfur (Na‐S) batteries, RT sodium‐oxygen (Na‐O 2 ) batteries, and RT ZEBRA‐type sodium‐metal halide batteries, also exhibit potentials to develop high‐energy and low‐cost energy storage systems. However, there are still some key issues to be solved …”

Section: Introductionmentioning

confidence: 99%

Design Strategies to Enable the Efficient Use of Sodium Metal Anodes in High‐Energy Batteries

et al. 2019

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Sodium-based batteries have attracted considerable attention and are recognized as ideal candidates for large-scale and low-cost energy storage. Sodium (Na) metal anodes are considered as one of the most promising anodes for next-generation, high-energy, Na-based batteries owing to their high theoretical specific capacity (1166 mA h g −1 ) and low standard electrode potential. Herein, an overview of the recent developments in Na metal anodes for high-energy batteries is provided. The high reactivity and large volume expansion of Na metal anodes during charge and discharge make the electrode/electrolyte interphase unstable, leading to the formation of Na dendrites, short cycle life, and safety issues. Design strategies to enable the efficient use of Na metal anodes are elucidated, including liquid electrolyte engineering, electrode/electrolyte interface optimization, sophisticated electrode construction, and solid electrolyte engineering. Finally, the remaining challenges and future research directions are identified. It is hoped that this progress report will shape a consistent view of this field and provide inspiration for future research to improve Na metal anodes and enable the development of high-energy sodium batteries.

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Section: Introductionmentioning

confidence: 99%

Design Strategies to Enable the Efficient Use of Sodium Metal Anodes in High‐Energy Batteries

et al. 2019

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“…Recently, we demonstrated that a room‐temperature Na‐CuCl 2 battery employing nonflammable and highly conductive SO 2 ‐based inorganic liquid electrolyte showed a high energy density of ≈580 Wh kg −1 with excellent capacity retention over 1000 cycles. [ 6 ] Apart from outstanding battery performance, the Na‐CuCl 2 battery can guarantee safe operation owing to the intrinsic properties of the SO 2 ‐based inorganic liquid electrolyte such as nonflammability, five times higher Na ionic conductivity than that of organic electrolyte, and a wide operation temperature range from −40 to 60 °C. [ 7 ] However, the Na‐CuCl 2 battery has two major problems to overcome for its commercialization.…”

Section: Figurementioning

confidence: 99%

“…The Cu electrode soaked in the NaAlCl 4 ·2SO 2 electrolyte shows well‐resolved peaks between 8980 and 9000 eV, indicating the presence of Cu 2+ as well as Cu + states. [ 6,14 ] Figure 2c shows the ex situ XRD patterns of cycled electrodes with respect to the degree of reaction for the first cycle. As anticipated, the converted Cu electrode composed of CuCl and NaCl was electrochemically oxidized into CuCl 2 after charging.…”

Section: Figurementioning

confidence: 99%

Self‐Formulated Na‐Based Dual‐Ion Battery Using Nonflammable SO₂‐Based Inorganic Liquid Electrolyte

Kim

Jung

Song

et al. 2019

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Sodium secondary batteries have gained much attention as alternative power sources to replace lithium secondary batteries. However, some technical issues must be solved to ensure their success. Here, a highly safe and cost‐effective Na‐based dual‐ion battery system employing self‐formulated CuCl cathode material starting from a mixture of Cu and NaCl in conjunction with a nonflammable NaAlCl4·2SO2 inorganic liquid electrolyte is demonstrated. It is found that CuCl is spontaneously formed by redox coupling of Cu/Cu(I) and SO2/SO2− anion radical. In the proposed battery, Na+ and Cl− are employed as energy carriers for the anode and cathode, respectively, and it is further demonstrated that the Na‐metal‐free battery configuration is possible using a hard carbon anode. Owing to the use of cheap electrode materials and a highly conductive and safe electrolyte, the proposed batteries deserve to be regarded as a promising approach for next‐generation Na rechargeable batteries.

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“…This battery's cathode has the potential to deliver a high energy of about 580 Wh/kg with a cycling capability of >1000 and relatively high round-trip efficiency of about 97% [100]. Kim et al also maintained that this battery chemistry can be extended to copper halide materials such as CuBr 2 and CuF 2 that show exciting performances when used as cathode materials for the Na-Cu halide technology.…”

Section: High Performance Sodium Copper Chloridementioning

confidence: 99%

Battery Storage Technologies for Electrical Applications: Impact in Stand-Alone Photovoltaic Systems

2017

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Batteries are promising storage technologies for stationary applications because of their maturity, and the ease with which they are designed and installed compared to other technologies. However, they pose threats to the environment and human health. Several studies have discussed the various battery technologies and applications, but evaluating the environmental impact of batteries in electrical systems remains a gap that requires concerted research efforts. This study first presents an overview of batteries and compares their technical properties such as the cycle life, power and energy densities, efficiencies and the costs. It proposes an optimal battery technology sizing and selection strategy, and then assesses the environmental impact of batteries in a typical renewable energy application by using a stand-alone photovoltaic (PV) system as a case study. The greenhouse gas (GHG) impact of the batteries is evaluated based on the life cycle emission rate parameter. Results reveal that the battery has a significant impact in the energy system, with a GHG impact of about 36-68% in a 1.5 kW PV system for different locations. The paper discusses new batteries, strategies to minimize battery impact and provides insights into the selection of batteries with improved cycling capacity, higher lifespan and lower cost that can achieve lower environmental impacts for future applications.

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High Performance Na–CuCl₂ Rechargeable Battery toward Room Temperature ZEBRA‐Type Battery

Cited by 29 publications

References 35 publications

Design Strategies to Enable the Efficient Use of Sodium Metal Anodes in High‐Energy Batteries

Design Strategies to Enable the Efficient Use of Sodium Metal Anodes in High‐Energy Batteries

Self‐Formulated Na‐Based Dual‐Ion Battery Using Nonflammable SO₂‐Based Inorganic Liquid Electrolyte

Battery Storage Technologies for Electrical Applications: Impact in Stand-Alone Photovoltaic Systems

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High Performance Na–CuCl2 Rechargeable Battery toward Room Temperature ZEBRA‐Type Battery

Cited by 29 publications

References 35 publications

Design Strategies to Enable the Efficient Use of Sodium Metal Anodes in High‐Energy Batteries

Design Strategies to Enable the Efficient Use of Sodium Metal Anodes in High‐Energy Batteries

Self‐Formulated Na‐Based Dual‐Ion Battery Using Nonflammable SO2‐Based Inorganic Liquid Electrolyte

Battery Storage Technologies for Electrical Applications: Impact in Stand-Alone Photovoltaic Systems

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Product

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High Performance Na–CuCl₂ Rechargeable Battery toward Room Temperature ZEBRA‐Type Battery

Self‐Formulated Na‐Based Dual‐Ion Battery Using Nonflammable SO₂‐Based Inorganic Liquid Electrolyte