Architecting hierarchical shell porosity of hollow prussian blue‐derived iron oxide for enhanced Li storage

Zhao, Zhijie; Chen, Luan; LIU, X.; WANG, D.; Qin, Tingting; Sui, Laizhi; Zhang, Wei

doi:10.1111/jmi.12836

Cited by 7 publications

(3 citation statements)

References 47 publications

(54 reference statements)

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“…(2) The rectangular shape of C@TiO 2 MHSs is more remarkable, and the corresponding area is larger. These suggest that the amorphous carbon shell can inspire the pseudocapacitive storage effect of TiO 2 MHSs [27,[33][34][35].…”

Section: Resultsmentioning

confidence: 91%

Pomegranate-like C@TiO₂ mesoporous honeycomb spheres for high performance lithium ion batteries

et al. 2020

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Pomegranate-like C@TiO2 mesoporous honeycomb spheres have been synthesized through two simple steps: formation of TiO2 mesoporous honeycomb spheres and the coating of polypyrrole followed by carbonization. TiO2 mesoporous honeycomb spheres are of large specific surface area of 153 m2 g−1 and contain abundant mesopores, which leads to high electrochemical activity and good kinetic performance of TiO2. A layer of amorphous carbon shell with the thickness of 30–40 nm tightly encapsulates a TiO2 mesoporous honeycomb sphere, forming a novel pomegranate-like small sphere, which significantly improves electronic conductivity and structural stability of TiO2. Benefiting from the unique pomegranate-like structure, C@TiO2 mesoporous honeycomb spheres exhibit high specific capacity, stable long-term cycling performance and good rate capability as an anode material for lithium ion batteries (LIBs). After 500 cycles at 1 C, the discharge capacity still reaches 184 mAh g−1. The electrochemical performance is superior to pure TiO2 mesoporous honeycomb spheres and most of the reported high-performance TiO2-based composites. This work provides a new high-performance TiO2-carbon-based composite material for LIBs as well as a new valuable research strategy.

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Section: Resultsmentioning

confidence: 91%

Pomegranate-like C@TiO₂ mesoporous honeycomb spheres for high performance lithium ion batteries

et al. 2020

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“…The Prussian blue with a stable structure can tolerate the volume change caused by sodium ion insertion and extraction processes. 35,36 Finally, Fe 3 [CO(CN) 6 ] 2 and its derivative are assembled as a full cell, which exhibits great potential in Na-ion battery. The low cost, simple synthesis method and excellent electrochemical performance make this hollow structured Prussian blue signicant in sodium ion energy storage applications and other elds such as supercapacitors, electro-catalysts, and biosensors.…”

Section: Discussionmentioning

confidence: 99%

Self-induced cobalt-derived hollow structure Prussian blue as a cathode for sodium-ion batteries

2021

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“…High capacity, good rate performance, and cycle stability of KIBs and SIBs are always pursued. So far, cathode materials such as transition-metal fluoride − and oxides and anode materials such as graphene, phosphorus, metal phosphides, carbon, Ti-based compounds, metal sulfides, and metal oxides , have been studied, and they exhibit good electrochemical properties. Phosphorus is regarded as an ideal material due to its high theoretical capacity (2594 mAh g –1 ) and a relatively low intercalation potential to K/K + .…”

Section: Introductionmentioning

confidence: 99%

Na/K Diffusion in FeP as an Anode Material for Ion Batteries

Fan

Wei

et al. 2020

J. Phys. Chem. C

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Potassium-and sodium-ion batteries (KIBs and SIBs) have attracted wide attention due to abundant potassium and sodium resources, low cost, and high safety. Therefore, in this work, FeP as an anode material is selected to study diffusions of Na/K using a density functional theory method in order to explain our experimental result that the rate performance of the FeP/C anode material in KIBs is much better than that in SIBs. The rate performance of the FeP/C anode material in KIBs and SIBs is related to diffusion activation energies including interaction energies between Na/K and FeP and migration energy barriers. Our calculations find that diffusion of Na/K in FeP is a multistep one. The most favorable one among various possible diffusion paths is obtained. A migration energy barrier is a key factor to distinguish between K and Na diffusions in FeP. Na−P/K−P bond lengths, consequent binding energies between Na/K and FeP, and local structures of transition states account for migration energy barriers. The calculated result of the larger migration energy barrier for Na in FeP than K in FeP can well explain our experimental phenomenon that the rate performance of FeP/C in KIBs is better than that in SIBs. This work provides a theoretical basis that iron phosphide can be used as a better, low-cost, and higher-energy-density anode material for KIBs.

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Architecting hierarchical shell porosity of hollow prussian blue‐derived iron oxide for enhanced Li storage

Cited by 7 publications

References 47 publications

Pomegranate-like C@TiO₂ mesoporous honeycomb spheres for high performance lithium ion batteries

Pomegranate-like C@TiO₂ mesoporous honeycomb spheres for high performance lithium ion batteries

Self-induced cobalt-derived hollow structure Prussian blue as a cathode for sodium-ion batteries

Na/K Diffusion in FeP as an Anode Material for Ion Batteries

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Architecting hierarchical shell porosity of hollow prussian blue‐derived iron oxide for enhanced Li storage

Cited by 7 publications

References 47 publications

Pomegranate-like C@TiO2 mesoporous honeycomb spheres for high performance lithium ion batteries

Pomegranate-like C@TiO2 mesoporous honeycomb spheres for high performance lithium ion batteries

Self-induced cobalt-derived hollow structure Prussian blue as a cathode for sodium-ion batteries

Na/K Diffusion in FeP as an Anode Material for Ion Batteries

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Product

Resources

About

Pomegranate-like C@TiO₂ mesoporous honeycomb spheres for high performance lithium ion batteries

Pomegranate-like C@TiO₂ mesoporous honeycomb spheres for high performance lithium ion batteries