In Situ Growth of Zeolitic Imidazolate Framework‐67‐derived Nanoporous Carbon@K0.5Mn2O4 for High‐Performance 2.4 V Aqueous Asymmetric Supercapacitors

Wei, Xiujuan; Peng, Huarong; Li, Yanhong; Yang, Yibin; Xiao, Siyu; Li, Peng; Zhang, Yunhuai; Xiao, Peng

doi:10.1002/cssc.201801439

Cited by 54 publications

(12 citation statements)

References 56 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“… NiCoP/NiCo-OH30║ZIF-67 (MOF) derived porous carbon 1 A g −1 6 M KOH 101 F g −1 1.6 V 34 Wh kg −1 11.6 kW kg −1 92% after 1000 cycles [ 138 ] 12. K 0.5 Mn 2 O 4 nanosheets were subsequently grown on the carbon surface (NCMO)║ZIF-67 (MOF) derived nanoporous carbon 10 A g −1 1 M Na 2 SO 4 75 F g −1 2.4 V 60 Wh kg −1 12.3 kW kg −1 92.6% after 10,000 cycles [ 139 ] 13. TM-nanorods║MOF derived N-doped hierarchical porous carbon nanorods (TM-NPs) 1 A g −1 2 M KOH 161 F g −1 1.5 V 47.1 Wh kg −1 17.1 kW kg −1 83.2% after 10,000 cycles [ 140 ] 14.…”

Section: Non-faradaic Capacitive (Edlc Type) Electrode Materialsmentioning

confidence: 99%

“…Similarly, Li et al [ 138 ] synthesized a ZIF-67 (Co-based zeolitic imidazole framework)-derived porous carbon (PC) which obtained gravimetric specific capacitance of 150 F g −1 at current density of 1 A g −1 . Wei et al [ 139 ] prepared a ZIF-67-derived nanoporous carbon (NC) for supercapacitor applications. The prepared electrode delivered a specific capacitance of 269 F g −1 at a current density of 1 A g −1 along with 90.4% capacitance retention even after 10,000 cycles.…”

Section: Non-faradaic Capacitive (Edlc Type) Electrode Materialsmentioning

confidence: 99%

See 1 more Smart Citation

Comprehensive Insight into the Mechanism, Material Selection and Performance Evaluation of Supercapatteries

et al. 2020

View full text Add to dashboard Cite

HIGHLIGHTS• This article reviewed the recent progress on material challenges, charge storage mechanism, and electrochemical performance evaluation of supercapatteries.• Supercapatteries bridge the gap between supercapacitors (low energy density) and batteries (low power density). Fig. 1 a Ragone plot of various electrochemical energy conversion and storage devices [43]. b Schematic illustration of charge storage mechanism of EDL capacitor in porous carbon electrode. c Representation of EDLC structures: Helmholtz model, Gouy-Chapman model and Gouy-Chapman-Stern model. Schematic representation of the charge storage mechanisms in pseudocapacitor; d Intercalation (bulk redox) and e surface redox Nano-Micro Lett.(2020) 12:85Page 5 of 46 85 Table 1 Classification of various energy storage devices according to their charge storage mechanisms NFCS non-Faradaic capacitive storage = EDLC storage, CFS capacitive Faradaic storage = pseudocapacitive storage, NCFS non-capacitive Faradaic storage = battery-type storage Device Supercapattery Battery Supercapacitor Hybrid supercapacitor EDLC Pseudocapacitors

show abstract

Section: Non-faradaic Capacitive (Edlc Type) Electrode Materialsmentioning

confidence: 99%

Section: Non-faradaic Capacitive (Edlc Type) Electrode Materialsmentioning

confidence: 99%

Comprehensive Insight into the Mechanism, Material Selection and Performance Evaluation of Supercapatteries

et al. 2020

View full text Add to dashboard Cite

show abstract

“…[13,16] Subsequently, researchers are adopting various smart strategies to improve the PD of SCs without negotiating the high PD and longer cyclic stability. [17] In this regard, a new hybrid architecture approach is under consideration. The amalgamation of a capacitive and a battery-grade material in a…”

Section: Introductionmentioning

confidence: 99%

Drive towards Sonochemically Synthesized Ternary Metal Sulfide for High‐Energy Supercapattery

et al. 2021

View full text Add to dashboard Cite

The present research focuses on, combining the chemistry of supercapacitors and batteries to get highly efficient hybrid energy storage devices. For projected drive, a novel battery‐grade electrode material is introduced. In this regard, binary and ternary metal sulfides with different compositions are synthesized via a facile sonochemical route. The electrode material Co(25%)Cu(75%)MnS (S4) reveals prime electrochemical performance, possessing a maximum specific capacity of 503.5 C g−1 while operating at 0.5 A g−1 in a three‐electrode assembly. The charge storage performance is further scrutinized in a two‐electrode assembly. A supercapattery device (S4//AC) is fabricated by coupling the Co(25%)Cu(75%)MnS (positive) and activated carbon (negative) electrodes. The device displays outstanding energy storage performance with an ultrahigh energy density of 88.71 Wh kg−1 along with a power density of 320 W kg−1. The maximum power density delivered by the assembled supercapattery device is 8000 W kg−1 in parallel with an energy density of 20 Wh kg−1. The supercapattery device also demonstrates an excellent cyclic stability potential of 84% after 3000 continuous charge/discharge cycles. The outstanding outcomes of the fabricated device reveals its potential applications in high‐performance energy storage technologies.

show abstract

“…High power solar cell should be matched with a high power energy storage device, this is why electrochemical capacitor (EC) is often used as energy storage device in this system . Electrochemical capacitor has promising application foreground in this system due to its high specific power density, fast charging/discharging process, and long cycling life . For example, Karthik and co‐workers assembled a self‐sustaining power station by combining the electrochemical double‐layer capacitors (EDLCs) and a commercial solar cell, which exhibited an energy density of 17.7 Wh kg −1 and could power 40 light‐emitting diodes after charging .…”

Section: Introductionmentioning

confidence: 99%

High Energy Capacitors Based on All Metal‐Organic Frameworks Derivatives and Solar‐Charging Station Application

Wei

Peng

et al. 2019

Small

Self Cite

View full text Add to dashboard Cite

High energy and efficient solar charging stations using electrochemical capacitors (ECs) are a promising portable power source for the future. In this work, two kinds of metal‐organic framework (MOF) derivatives, NiO/Co3O4 microcubes and Fe2O3 microleaves, are prepared via thermal treatment and assembled into electrochemical capacitors, which deliver a relatively high specific energy density of 46 Wh kg−1 at 690 W kg−1. In addition, a solar‐charging power system consisting of the electrochemical capacitors and monocrystalline silicon plates is fabricated and a motor fan or 25 LEDs for 5 and 30 min, respectively, is powered. This work not only adds two novel materials to the growing categories of MOF‐derived advanced materials, but also successfully achieves an efficient solar‐ECs system for the first time based on all MOF derivatives, which has a certain reference for developing efficient solar‐charge systems.

show abstract

In Situ Growth of Zeolitic Imidazolate Framework‐67‐derived Nanoporous Carbon@K_0.5Mn₂O₄ for High‐Performance 2.4 V Aqueous Asymmetric Supercapacitors

Cited by 54 publications

References 56 publications

Comprehensive Insight into the Mechanism, Material Selection and Performance Evaluation of Supercapatteries

Comprehensive Insight into the Mechanism, Material Selection and Performance Evaluation of Supercapatteries

Drive towards Sonochemically Synthesized Ternary Metal Sulfide for High‐Energy Supercapattery

High Energy Capacitors Based on All Metal‐Organic Frameworks Derivatives and Solar‐Charging Station Application

Contact Info

Product

Resources

About