A High‐Performance Dual‐Ion Battery‐Supercapacitor Hybrid Device Based on LiCl in Ion Liquid Dual‐Salt Electrolyte

Xiong, Zhangyi; Guo, Peijing; Yang, Yushan; Yuan, Shaoyu; Shang, Ningzhao; Wang, Chun; Zhang, Yufan; Wang, Huan; Gao, Yongjun

doi:10.1002/aenm.202103226

Cited by 29 publications

(28 citation statements)

References 57 publications

(23 reference statements)

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“…The reduced intensities of these peaks in the sample at discharged state could be assigned to the disassociation of ClO 4 − (Figure S11c, Supporting Information). [29,30] In the N 1s spectra of the PTPAn cathode at charged state, a new peak located at 401.78 eV appeared, which ascribed to the formation of N radical cation, [31] which was severely weakened in the discharged state, implying the reduction of N radical cation (Figure S11d, Supporting Information). According to these results, the working mechanism of CAN-ODIB was illustrated in Figure S12 in the Supporting Information.…”

Section: Resultsmentioning

confidence: 99%

Calcium Based All‐Organic Dual‐Ion Batteries with Stable Low Temperature Operability

Jiang

Liu

et al. 2022

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In response to the application requirements of secondary batteries at low temperature, an all‐organic dual‐ion battery with calcium perchlorate contained acetonitrile as the electrolyte (CAN‐ODIB) is fabricated in this work. The electrochemical energy is stored in CAN‐ODIB via the association and disassociation of calcium and perchlorate ions in perylene diimide‐ethylene diamine/carbon black composite based anode and polytriphenylamine based cathode with highly reversible redox states. Benefiting from the energy storage mechanism, CAN‐ODIB exhibits excellent electrochemical performances in tests with the temperature ranging from 25 to −50 °C. Especially, CAN‐ODIB at −50 °C reserves ≈61% of the capacity at 25 °C (83.4 mA h g−1) with the current density of 0.2 A g−1. CAN‐ODIB also shows excellent cycling stability at low temperature by retaining 90.3% of the initial capacity at 1.0 A g−1 after 450 charge–discharge cycles at −30 °C. The impedance analysis of CAN‐ODIB at different temperatures indicates that the low temperature performance of CAN‐ODIB depends more on the electrode materials than the electrolyte, which provides the important guidance for the further design of secondary batteries operable at low temperatures.

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Section: Resultsmentioning

confidence: 99%

Calcium Based All‐Organic Dual‐Ion Batteries with Stable Low Temperature Operability

Jiang

Liu

et al. 2022

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“…Conventional electrolytes used in batteries are liquid in nature, made up of carbonate based organic solvents with high ionic conductivity such as ethylene carbonate, diethyl carbonate, dimethyl carbonate, etc . These electrolytes, despite their success, suffer from several shortcomings such as their reactivity toward electrodes, flammable nature of organic solvents, and the possibility of leakage of the liquid electrolytes .…”

Section: Lignocellulose In Battery Applicationsmentioning

confidence: 99%

Lignocellulose Biopolymers and Electronically Conducting Polymers: Toward Sustainable Energy Storage Applications

et al. 2022

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The demand for the development of electrochemical energy storage systems from abundant, renewable, eco-friendly, and cost-effective materials has been the focal and driving point in the advancement of electronic devices. This task and demand can be addressed with a resource that is abundant and possesses the attributes of being developed into efficient electrochemical energy storage systems. Lignin and cellulose, which are collectively known as lignocellulose, are the two most abundant biopolymers available, and they possess the attributes and the qualities to meet this demand. Lignocellulose biopolymers possess unique characteristics such as mechanical flexibility, porosity, and tunability because of their abundant and diverse functional groups. These qualities enable suitable pairing with electronically conducting polymers as enhanced materials for the development of sustainable energy storage devices. This Review highlights the challenges and the utilization of lignocellulose with electronically conducting polymers in supercapacitors applications and battery applications in various capacities as electrodes, separators, binders, and electrolytes.

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“…16 Not surprisingly, there have been few reports of chlorine oxidation in the field of electrochemical capacitors, although the intercalation behavior of chloride ions has been reported in hybrid devices. 17 This is because the reaction potential of chlorine exceeds the stable voltage window of aqueous electrolytes and the gaseous oxidation products have difficulty achieving reversibility in the liquid phase. 18 From the perspective of the energy-storage mechanism of redox additives in electrolytes, under an applied bias, the redox species in the pores of electrode materials are the most adaptable to the electrosorption process and undergo electron transfer to convert into oxidized/reduced states.…”

Section: ■ Introductionmentioning

confidence: 99%

“…Chlorine has the highest standard redox potential (1.358 V vs SHE (standard hydrogen electrode)) and lowest molecular weight in the halogen family, except for fluorine, implying its potential to provide high capacity . Not surprisingly, there have been few reports of chlorine oxidation in the field of electrochemical capacitors, although the intercalation behavior of chloride ions has been reported in hybrid devices . This is because the reaction potential of chlorine exceeds the stable voltage window of aqueous electrolytes and the gaseous oxidation products have difficulty achieving reversibility in the liquid phase .…”

Section: Introductionmentioning

confidence: 99%

A Chlorine-Based Redox Electrochemical Capacitor

Wang

et al. 2022

ACS Appl. Mater. Interfaces

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Electrochemical capacitors are under the spotlight due to their high power density, but they have a low energy density. Redox electrolytes have emerged as a promising approach to design high-energy electrochemical energy storage devices. Herein, a chlorine-based redox electrochemical capacitor is reported in an ionic liquid electrolyte. The commercial activated carbon is employed as the working electrode to render the reversible redox of chloride ions in an ionic liquid, by the restriction of micropores on neutral chlorine. The carbon material can simultaneously provide electrical double-layer capacitance. The effective integration of a chlorine redox reaction and electrical double layer allows for high-energy electrochemical capacitors. By this means, a rechargeable chlorine-based redox electrochemical capacitor with reversible capacity and good rate capability and cycling stability is obtained. This work offers a solution for a new type of high-energy electrochemical capacitors.

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A High‐Performance Dual‐Ion Battery‐Supercapacitor Hybrid Device Based on LiCl in Ion Liquid Dual‐Salt Electrolyte

Cited by 29 publications

References 57 publications

Calcium Based All‐Organic Dual‐Ion Batteries with Stable Low Temperature Operability

Calcium Based All‐Organic Dual‐Ion Batteries with Stable Low Temperature Operability

Lignocellulose Biopolymers and Electronically Conducting Polymers: Toward Sustainable Energy Storage Applications

A Chlorine-Based Redox Electrochemical Capacitor

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