Electrolytes for electrochemical energy storage

Xia, Lan; Yu, Lian; Hu, Di; Chen, George

doi:10.1039/c6qm00169f

Cited by 213 publications

(119 citation statements)

References 350 publications

(422 reference statements)

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“…The CV curves recorded at a slow scan rate (10 mV s À 1 ) clearly show the multiple redox peaks in both positive and negative potentials for KOH (Figure 3a). [25] This is clearly observed from the present investigations. During the negative potential, there is a single redox peak which belongs to the Mn 4 + to Mn 2 + .…”

Section: Electrochemical Characterizationssupporting

confidence: 84%

“…The half-cell performance was studied in neutral (2 M Na 2 SO 4 ) and alkaline (6 M KOH) electrolytes. [25] It is also believed that the size of the hydrated K + and Na + may also influence the performance of the electrode materials. The MCC electrode experienced typical pseudo behaviour in both cases due to the partial Faradic reaction.…”

Section: Electrochemical Characterizationsmentioning

confidence: 99%

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Transformation of Spent Li‐Ion Battery in to High Energy Supercapacitors in Asymmetric Configuration

et al. 2019

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For the first time, herein we report a new track to regenerate the MnÀ Co carbonate (MCC) from the mixed composition of cathodes of spent LIBs and successfully evaluated as an electrode material for supercapacitor applications (ASC). The resultant MCC spheres are first tested in a half cell with Pt-strip as the counter electrode using neutral and alkaline electrolytes. The fabricated ASC with regenerated MCC as the positive electrode and commercial activated carbon (AC) as the negative electrode in the presence of 6 M KOH reveals a specific capacitance of 119 F g À 1 at 0.5 A g À 1 , also could retain 65 F g À 1 at a high current density of 4 A g À 1 accompanied by outstanding cycling stability of 9000 cycles with 60 % retention at 1.5 A g À 1 . Furthermore, this low-cost ASC MCC//AC offers a high energy density of 42.2 Wh kg À 1 at a power density of 1.6 kW kg À 1 , in a stable potential window of 0-1.6 V. In addition, the flexible ASC in solid-state assembly in series efficiently power a green lightemitting-diode, inspiring its promising practical application to build new ASC using spent LIBs materials as sources in "wasteto-wealth" approach for high energy asymmetric all-solid-state supercapacitors.

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Section: Electrochemical Characterizationssupporting

confidence: 84%

Section: Electrochemical Characterizationsmentioning

confidence: 99%

Transformation of Spent Li‐Ion Battery in to High Energy Supercapacitors in Asymmetric Configuration

et al. 2019

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“…1 The conventional organic electrolytes have a number of drawbacks such as volatility, tedious purification process, higher environmental impact, flammability, and low ionic conductivity. 2 These problems are limiting their applicability in lithium-ion batteries in terms of safety and performance. For example, the most common conventional electrolyte used in the commercially available lithium-ion batteries is the LiPF 6 salt dissolved in a mixture of ethylene carbonate (EC) and diethyl carbonate (DEC).…”

Section: Introductionmentioning

confidence: 99%

Ion dynamics in halogen-free phosphonium bis(salicylato)borate ionic liquid electrolytes for lithium-ion batteries

Shah

Гнездилов

Филиппов

2017

Phys. Chem. Chem. Phys.

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“…Compared with solid-state electrolytes, polyelectrolytes are more suitable for energy storage devices because of their high ionic conductivity (10 −4 to 10 −3 S cm −1 ), tunable mechanical properties, good chemical compatibility with electrode components, easy processing, good stability, and low cost. [94][95][96] So far, only a few examples of self-healing hydrogel electrolytes for flexible supercapacitors and sensors have been reported in the literature.…”

Section: Self-healing Ionic Conductorsmentioning

confidence: 99%

Self‐Healing Materials for Next‐Generation Energy Harvesting and Storage Devices

Chen

Wang

Yang

et al. 2017

Advanced Energy Materials

213

172

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Because of the great breakthroughs of self‐healing materials in the past decade, endowing devices with self‐healing ability has emerged as a particularly promising route to effectively enhance the device durability and functionality. This article summarizes recent advances in self‐healing materials developed for energy harvesting and storage devices (e.g., nanogenerators, solar cells, supercapacitors, and lithium‐ion batteries) over the past decade. This review first introduces the main self‐healing mechanisms among different materials including insulators, electrical conductors, semiconductors, and ionic conductors. Then, the basic concepts, fabrication techniques, and healing performances of the newly developed self‐healing energy harvesting (nanogenerators and solar cells) and storage (supercapacitors and lithium‐ion batteries) devices are described in detail. Finally, the existing challenges and promising solutions of self‐healing materials and devices are discussed.

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Electrolytes for electrochemical energy storage

Cited by 213 publications

References 350 publications

Transformation of Spent Li‐Ion Battery in to High Energy Supercapacitors in Asymmetric Configuration

Transformation of Spent Li‐Ion Battery in to High Energy Supercapacitors in Asymmetric Configuration

Ion dynamics in halogen-free phosphonium bis(salicylato)borate ionic liquid electrolytes for lithium-ion batteries

Self‐Healing Materials for Next‐Generation Energy Harvesting and Storage Devices

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