Redox Tuning in Crystalline and Electronic Structure of Bimetal–Organic Frameworks Derived Cobalt/Nickel Boride/Sulfide for Boosted Faradaic Capacitance

Wang, Qingyong; Luo, Yumei; Hou, Ruizuo; Zaman, Shahid; Qi, Kai; Liu, Hongfang; Park, Ho Seok; Xia, Bao Yu

doi:10.1002/adma.201905744

Cited by 160 publications

(73 citation statements)

References 50 publications

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“…EDLCs store energy by reversible ion adsorption at the electrolyte/electrode surface, which highly depends on the specific surface area. In contrast, pseudocapacitors work through Faradaic redox reactions both on and near the surface of the electroactive materials, which usually have larger capacitance than that of EDLCs [9][10][11]. However, the relatively low energy density is a common bottleneck for both types of supercapacitors, severely limiting their widespread applications.…”

Section: Introductionmentioning

confidence: 99%

Ultrathin Ni(OH)2 layer coupling with graphene for fast electron/ion transport in supercapacitor

et al. 2020

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Integration of fast electrochemical double-layer capacitance and large pseudocapacitance is a practical way to improve the overall capability of supercapacitor, yet remains challenging. Herein, an effective cyanogel synthetic strategy was demonstrated to prepare ultrathin Ni(OH) 2 nanosheets coupling with conductive reduced graphene oxide (rGO) (rGO-Ni(OH) 2) at ambient condition. Ultrathin Ni(OH) 2 nanosheet with 3-4 layers of edge-sharing octahedral MO 6 maximally exposes the active surface of Faradic reaction and promotes the ion diffusion, while the conductive rGO sheet boosts the electron transport during the reaction. Even at 30 A g −1 , the optimal sample can deliver a specific capacitance of 1119.52 F g −1 , and maintain 82.3% after 2000 cycles, demonstrating much higher electrochemical capability than bare Ni(OH) 2 nanosheets. A maximum specific energy of 44.3 W h kg −1 (148.5 W kg −1) is obtained, when assembled in a two-electrode system rGO-Ni(OH) 2 //rGO. This study provides an insight into efficient construction of two-dimensional hybrid electrodes with high performance for the new-generation energy storage system.

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Section: Introductionmentioning

confidence: 99%

Ultrathin Ni(OH)2 layer coupling with graphene for fast electron/ion transport in supercapacitor

et al. 2020

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“…As revealed in Figure a, UMC‐IPNs, PC‐MFB and PC‐MF electrodes show similar cyclic voltammetry (CV) curves closed to the rectangle, suggesting a good electric double layer capacitance (EDLC) behavior . The difference is that the CV area of UMC‐IPNs is much larger than the area of PC‐MFB and PC‐MF, which means the highest specific capacity of it . Subsequently, the CV of UMC‐IPNs was carried out from 5 to 200 mV s −1 (Figure S3a).…”

Section: Resultsmentioning

confidence: 84%

Design of Ultra‐Microporous Carbons by Interpenetrating MF Prepolymer into PAAS Networks at Molecule Level for Enhanced Electrochemical Performance

Gao

Chen

et al. 2020

ChemElectroChem

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The pore structure control of porous carbons, especially ultramicroporous carbons, has long been a great challenge, and it is desirable to propose new strategies to deal with this dilemma. Herein, we designed and obtained ultra-microporous dominant porous carbon materials (UMC-IPNs) with an unimodal pore diameter of 0.6 nm by the strategy of interpenetrating polymer networks precursor carbonization. Thanks to the intertwining characteristics of the two interpenetrating polymer networks, the microphase separation which often occurs between the polymers is well suppressed, and also the pores of the as-obtained ultra-microporous carbons are interconnected. The calculated specific surface area is 1551 m 2 g À 1 . Furthermore, as electrode material, UMC-IPNs has been confirmed to have exceptional electrochemical performance (the specific capacitance is 268 F g À 1 at 0.5 A g À 1 , and after 10,000 cycles, the capacity is 96 % of the original at 6 A g À 1 ) and rapid electrochemical kinetics (the surface capacitance effect ratio is about 85.4 % in our calculation results). In addition, ultra-microporous carbons are interesting for other applications such as gas capture, catalysis, and sensor technology.

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“…As a new high‐energy battery successfully developed in the 20 th century, LIBs have been widely used to power portable electronics and electrical vehicles (e. g. mobile phones, portable computers, and video cameras, etc.). To meet the demand of higher capacity and better rate capability for next‐generation LIBs, people have put considerable effort on searching for promising alternative electrode materials . Among the currently emerging candidates, iron oxides (Fe 2 O 3 and Fe 3 O 4 ) have drawn intensive attention due to their high theoretical capacity of about 1000 mAh g −1 , environmental benignity, natural abundance, low cost, high corrosion resistance, and several other appealing advantages (e. g. design flexibility, more beneficial lithium insertion and the non‐inflammability) .…”

Section: Figurementioning

confidence: 99%

“…To boost their lithium storage properties, the major strategies developed to date are focusing on following two pathways: (i) constructing iron oxide electrodes to porous and/or hollow micro‐/nanostructures with plenty of voids to relieve the strain of volume change during the charge/discharge cycling process; additionally, such nanostructures can expose more active sites, allowing for fast diffusion of Li + ions, and can also guarantee a full contact between electrode and electrolyte; (ii) to integrate carbonaceous materials (e. g. graphene, carbon nanotubes, amorphous carbon, and their derivatives) into iron oxide to form hybrid nanostructures. As such, the electronic conductivity can be improved and may also serve to buffer the volume strain .…”

Section: Figurementioning

confidence: 99%

A Biomimetic‐Mineralization‐Inspired Hybrid Mesocrystal with Boosted Lithium Storage Properties

Fei

Zhu

2020

ChemistrySelect

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Smart controlling the structure and composition of hybrid anode materials to boost the electrochemical performance is still challenging yet significant for lithium ion batteries (LIBs). Herein, a biomimetic strategy is reported for the synthesis of mesostructured Fe3O4@N‐doped carbon (Fe3O4@CN) hybrid anodes, inspired by structural features and hybrid compositions of the biomineralized mesocrystals. By using the regenerated silk fibroin (RSF)‐biomineralized hematite (ɑ‐Fe2O3) as a single precursor (RSF‐Fe2O3) followed by a simple annealing treatment, its interspaced RSF‐templates can be carbonized in situ to a kind of RSF‐derived CN material, which can further reduce the ɑ‐Fe2O3 to Fe3O4, generating Fe3O4@CN hybrid mesocrystal. Such a biomimetically designed hybrid mesostructure concurrently possesses electrochemically favorable features with abundant internal voids and uniformly introduced carbonaceous layer. Owing to these distinctive structural and compositional merits, the Fe3O4@CN electrode exhibits remarkable lithium storage properties embracing high capacity, outstanding rate capability, as well as long‐term stable cycling life.

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Redox Tuning in Crystalline and Electronic Structure of Bimetal–Organic Frameworks Derived Cobalt/Nickel Boride/Sulfide for Boosted Faradaic Capacitance

Cited by 160 publications

References 50 publications

Ultrathin Ni(OH)2 layer coupling with graphene for fast electron/ion transport in supercapacitor

Ultrathin Ni(OH)2 layer coupling with graphene for fast electron/ion transport in supercapacitor

Design of Ultra‐Microporous Carbons by Interpenetrating MF Prepolymer into PAAS Networks at Molecule Level for Enhanced Electrochemical Performance

A Biomimetic‐Mineralization‐Inspired Hybrid Mesocrystal with Boosted Lithium Storage Properties

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