In Situ Encapsulation of Iron Complex Nanoparticles into Biomass‐Derived Heteroatom‐Enriched Carbon Nanotubes for High‐Performance Supercapacitors

Zhang, Jingjing; Zhao, Huihui; Li, Jun; Jin, Huile; Yu, Xiaochun; Lei, Yong; Wang, Shun

doi:10.1002/aenm.201803221

Cited by 90 publications

(43 citation statements)

References 51 publications

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“…The assembled devices were tested for EIS, CV, galvanostatic charge and discharge (GCD), etc., and the test parameters are the same as before. The specific energy density and power density of the sodium ion capacitor were calculated by the following formula [28]:…”

Section: Electrochemical Measurementsmentioning

confidence: 99%

N-Doped Modified Graphene/Fe2O3 Nanocomposites as High-Performance Anode Material for Sodium Ion Storage

et al. 2019

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Sodium-ion storage devices have received widespread attention because of their abundant sodium resources, low cost and high energy density, which verges on lithium-ion storage devices. Electrochemical redox reactions of metal oxides offer a new approach to construct high-capacity anodes for sodium-ion storage devices. However, the poor rate performance, low Coulombic efficiency, and undesirable cycle stability of the redox conversion anodes remain a huge challenge for the practical application of sodium ion energy storage devices due to sluggish kinetics and irreversible structural change of most conversion anodes during cycling. Herein, a nitrogen-doping graphene/Fe 2 O 3 (N-GF-300) composite material was successfully prepared as a sodium-ion storage anode for sodium ion batteries and sodium ion supercapacitors through a water bath and an annealing process, where Fe 2 O 3 nanoparticles with a homogenous size of about 30 nm were uniformly anchored on the graphene nanosheets. The nitrogen-doping graphene structure enhanced the connection between Fe 2 O 3 nanoparticles with graphene nanosheets to improve electrical conductivity and buffer the volume change of the material for high capacity and stable cycle performance. The N-GF-300 anode material delivered a high reversible discharge capacity of 638 mAh g −1 at a current density of 0.1 A g −1 and retained 428.3 mAh g −1 at 0.5 A g −1 after 100 cycles, indicating a strong cyclability of the SIBs. The asymmetrical N-GF-300//graphene SIC exhibited a high energy density and power density with 58 Wh kg −1 at 1365 W kg −1 in organic solution. The experimental results from this work clearly illustrate that the nitrogen-doping graphene/Fe 2 O 3 composite material N-GF-300 is a potential feasibility for sodium-ion storage devices, which further reveals that the nitrogen doping approach is an effective technique for modifying carbon matrix composites for high reaction kinetics during cycles in sodium-ion storage devices and even other electrochemical storage devices. IntroductionWith the rapid development of portable mobile electronic devices and electric vehicles, the importance of high-performance electrical energy storage (EES) devices is becoming increasingly prominent. The EES devices based on sodium ion such as sodium ion batteries (SIBs) and sodium ion supercapacitors (SICs) have attracted great attention due to their low cost, the rich abundance of sodium resource, and their high energy density, which approaches that of lithium-ion energy storage devices [1][2][3]. However, there are still some obstacles hindering the practical application of sodium ion energy storage devices, such as poor rate performance, low coulombic efficiency, and undesirable Nanomaterials 2019, 9, 1770 2 of 13 cycle stability. The foremost reason is the bigger radius of Na + (0.102 nm) compared to Li + (0.076 nm), which leads to low reaction kinetics for Na + insertion/extraction from the anode materials [4][5][6]. Meanwhile, excellent anode materials should have suitable microscopic internal ...

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Section: Electrochemical Measurementsmentioning

confidence: 99%

N-Doped Modified Graphene/Fe2O3 Nanocomposites as High-Performance Anode Material for Sodium Ion Storage

et al. 2019

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“…CA-400 exhibits typical amorphous carbon peaks with 2θ at 26 and 43 , whereas CA@Fe (1:3)-600, CA@Fe(1:3)-700 and CA@Fe(1:3)-800 show three characteristic peaks at 2θ = 30.2 , 35.5 , 42.9 , which are corresponding to (220), (311), and (400) crystal planes of Fe 3 O 4 , demonstrating the nanoparticles are Fe 3 O 4 . 25 It is noteworthy that the sharp peaks of Fe 3 O 4 crystal may cover up the carbon lattices in CA@Fe (1:3)-y. Figure S2A Raman spectra in Figure 2B show two obvious characteristic peaks at 1359 and 1590 cm −1 or so, which are ascribed to disordered sp 3 (D band) and graphitic sp 2 (G band) of carbon, respectively.…”

Section: Resultsmentioning

confidence: 98%

Biomass carbon dual‐doped with iron and nitrogen for high‐performance electrocatalyst in water splitting

Zhou

Yan²,

Xiang

et al. 2021

Int J Energy Res

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Energy crisis has become an urgent problem in the world. Hydrogen is a continuous and clean energy, but traditional electrocatalytic materials for water splitting have the shortcomings including high cost and low hydrogen production efficiency. Herein, we prepare a biomass carbon-based electrocatalyst doped with iron and nitrogen. The overpotential of so-obtained CA (abbreviation of "carbon from amaranth") @Fe(1:3)-800 is only 265 mV at 10 mA cm −2 for oxygen evolution reaction (OER), as well as the Tafel slope is 76.7 mV dec −1 , which are much superior to the results of CA-800 (the overpotential is 514 mV and the Tafel slope is 160.2 mV dec −1 ). It shows the positive influences of dual-doping with iron and nitrogen in biomass carbon. Our work opens up a low-cost and green avenue for fabricating high-performance electrocatalyst in hydrogen production field.

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“…On the anode side of HSC, carbonaceous materials are the most suitable electrode materials due to their rather high power densities, unique charge storage mechanism (results from the electric double layer capacitance, abbr. EDLC, a fast physical reversible ions adsorption/desorption process at the electrode/interface), desirable physical properties, controllable porosities and relatively inert electrochemical characters . Besides, the combination of EDLC‐typed carbon materials with the redox reaction‐typed heterostructured materials in a full cell device could potentially lead to the charge storage process simultaneous integrates the electrophysical (accumulation of charge) and electrochemical process (redox of central metal ions via electron gain/loss) .…”

Section: Introductionmentioning

confidence: 84%

“…EDLC, a fast physical reversible ions adsorption/desorption process at the electrode/interface), desirable physical properties, controllable porosities and relatively inert electrochemical characters. [13,[28][29][30] Besides, the combination of EDLC-typed carbon materials with the redox reaction-typed heterostructured materials in a full cell device could potentially lead to the charge storage process simultaneous integrates the electrophysical (accumulation of charge) and electrochemical process (redox of central metal ions via electron gain/loss). [13] Consequently, a hybrid energy storage system can be achieved by hybridization at either the mechanism or the device level, which can also generate a hybridization effect to the kinetics and electrochemical characteristics of a SC.…”

Section: Introductionmentioning

confidence: 99%

Solid‐State Hybrid Supercapacitor Assembled from a Heterostructured Co−Ni Battery‐like Cathode and Supercapacitor‐Type Highly Disordered Carbon Nanosheets

et al. 2020

ChemElectroChem

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Hybrid at either the mechanism or the device level can lead to a hybridization effect of the kinetics and electrochemical characteristic of a supercapacitor (SC). Herein, a heterostructured NiCo 2 S 4 /Co x Ni 1-x (OH) 2 battery-like cathode material was designed, with which the obtained sample accomplished the combination of excellent electronic and ionic conductivity so as to realize an enhanced faradaic redox storage process. Besides, a SC-type highly capacitive anode material of a N and S codoped porous carbon nanosheets (ACNS) was also fabricated, which exhibits great advantages in terms of its enlarged specific surface area, the ease of introducing pseudocapacitive reactions, and its physical structure. These features directly lead to significant improvements in the electric double-layer capacitor (EDLC)-type electrochemical properties of the carbon anode. The combination of an EDLC-type carbon anode with the redox-reaction-type cathode in a full cell device could potentially lead to a charge storage process that simultaneously integrates the electrophysical and electrochemical processes. For these reasons, the obtained solid-state hybrid SC delivers a wide voltage window of 1.6 V, a high specific capacity of 121.3 C g À 1 , and enhanced energy/power densities of 26.1 Wh kg À 1 /11 kW kg À 1 . The as-assembled device can maintain a high and stable capacity retention of 89.1 % for over 10 000 cycles. The developed hybrid assembly strategy and the electrode combination may provide design guidelines for designing other high-energy hybrid SCs.

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In Situ Encapsulation of Iron Complex Nanoparticles into Biomass‐Derived Heteroatom‐Enriched Carbon Nanotubes for High‐Performance Supercapacitors

Cited by 90 publications

References 51 publications

N-Doped Modified Graphene/Fe2O3 Nanocomposites as High-Performance Anode Material for Sodium Ion Storage

N-Doped Modified Graphene/Fe2O3 Nanocomposites as High-Performance Anode Material for Sodium Ion Storage

Biomass carbon dual‐doped with iron and nitrogen for high‐performance electrocatalyst in water splitting

Solid‐State Hybrid Supercapacitor Assembled from a Heterostructured Co−Ni Battery‐like Cathode and Supercapacitor‐Type Highly Disordered Carbon Nanosheets

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