Optimizing the Void Size of Yolk–Shell Bi@Void@C Nanospheres for High-Power-Density Sodium-Ion Batteries

Yang, Hai; Chen, Lin-Wei; He, Fuxiang; Zhang, Jiaqing; Feng, Yuezhan; Zhao, Lukang; Wang, Bin; He, Lixin; Zhang, Qiaobao; Yu, Yan

doi:10.1021/acs.nanolett.9b04829

Cited by 156 publications

(102 citation statements)

References 56 publications

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“…However,p oor kinetics associated with the high diffusion barrier of metal ions,a nd the severe volume variations originated from alloying/de-alloying process,a re two key obstacles that prevent wide application of this alloy anode. [21] Delicate structures,s uch as yolk-shell nanospheres for Na + storage, [22] colloidal nanocrystals for Mg-ion battery [13a] and dual-shell boxes for K-ion storage [23] can significantly enhance electrochemical performance by shortening the ion diffusion length. Here,f or the first time,m esoporous Bi nanosheets were loaded onto flexible substrate forming af ree-standing Mg 2+ storage anode.A si si llustrated in Figure S3 and S4, bismuth oxyiodide nanosheet was grown on carbon matrix via afacile hydrothermal approach.…”

Section: Structural Evolution and Electrochemical Performancementioning

confidence: 99%

Revealing the Magnesium‐Storage Mechanism in Mesoporous Bismuth via Spectroscopy and Ab‐Initio Simulations

Chao

Chen

et al. 2020

Angew Chem Int Ed

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We present mesoporous bismuth nanosheets as am odel to study the charge-storage mechanism of Mg/Bi systems in magnesium-ion batteries (MIBs). Using asystematic spectroscopyi nvestigation of combined synchrotron-based operando X-ray diffraction, near-edge X-ray absorption fine structure and Raman, we demonstrate ar eversible two-step alloying reaction mechanism Bi$MgBi$Mg 3 Bi 2 .A b-initio simulation methods disclose the formation of aM gBi intermediate and confirm its high electronic conductivity.T his intermediate serves as ab uffer for the significant volume expansion (204 %) and acts to regulate Mg storage kinetics. The mesoporous bismuth nanosheets,a sa ni deal material for the investigation of the Mg charge-storage mechanism, effectively alleviate volume expansion and enable significant electrochemical performance in al ithium-free electrolyte. These findings will benefit mechanistic understandings and advance material designs for MIBs.

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Section: Structural Evolution and Electrochemical Performancementioning

confidence: 99%

Revealing the Magnesium‐Storage Mechanism in Mesoporous Bismuth via Spectroscopy and Ab‐Initio Simulations

Chao

Chen

et al. 2020

Angew Chem Int Ed

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“…Up to date, typical yolk–shell nanostructures, defined as inner core@outer shell, integrating diverse functional components, such as Fe 3 O 4 @Carbon, [ 18 ] Fe 3 O 4 @SiO 2 , [ 19 ] Fe 3 O 4 @PMMA, [ 20 ] Au@PANI, [ 21 ] Au@Carbon, [ 22 ] Au@PNIPM, [ 23 ] Au@TiO 2 , [ 24 ] SiOx/Carbon, [ 25 ] Bi@Carbon, [ 26 ] and so on, have been developed. Among them, inner magnetic core, such as Fe 3 O 4 nanoparticles with strong magnetic responsivity and outer carbon shell with outstanding chemical stability, further functionalization and tunable pore structure were integrated to be one kind of most promising yolk–shell materials for facile drug targeting delivery, [ 27 ] rapid recovery of heterogenous catalysts in liquid phase, [ 28 ] rapid removal of metal ion and organic pollutants, [ 29,30 ] and rapid screening of biomolecules.…”

Section: Methodsmentioning

confidence: 99%

Yolk–Shell Fe₃O₄@Void@N‐Carbon Nanostructures Based on One‐Step Deposition of SiO₂ and Resorcinol‐3‐Aminophenol‐Formaldehyde (R‐APF) Cocondensed Resin Dual Layers onto Fe₃O₄ Nanoclusters

Tian

Wang

Guo

et al. 2020

Macromol. Rapid Commun.

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Yolk–shell magnetic nanoparticles@nitrogen‐enriched Carbon nanostructures with a magnetic core and a hollow nitrogen‐enriched carbon shell exhibit considerable promise in various applications, such as drug delivery, heterogenous catalysts, removal of metal ions and organic pollutants, and screening of biomolecules, due to their strong magnetic response, unique cavities, and the selective absorption ability of nitrogen‐enriched groups. However, their complicated synthesis always involves possible surface modification, layer‐by‐layer deposition of a sacrificial middle layer and an outer nitrogen‐enriched layer on magnetic nanoparticles, subsequent carbonization, and final removal of the sacrificial middle layer. Herein, yolk–shell Fe3O4@nitrogen‐enriched carbon nanostructures are constructed based on NH4+ ion‐induced one‐step deposition of SiO2 and Resorcinol‐3‐aminophenol‐formaldehyde cocondensed resin (R‐APF) dual layers onto poly acrylic acid‐modified Fe3O4 nanoclusters without any extra surface modification. The N‐Carbon shell thickness of the yolk–shell Fe3O4@Void@N‐Carbon nanostructure can be finely tailored though tailoring the feeding amount of aminophenol and resorcinol to tune the thickness of the outer R‐APF resin shell onto Fe3O4@SiO2 intermediate particles. This NH4+ ion‐induced one‐pot deposition of double layers can effectively promote synthesis efficiency of this kind of yolk–shell nanostructure.

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“…Notwithstanding, most Bi-based materials suffer from pulverization and fracture of the electrodes caused by dramatic volume variation, consequently diminishing the cycle stability. [29][30][31][32][33][34][35][36] To solve these problems, variety of strategies have been adopted, such as fabricating nanoscale materials to simultaneously alleviate mechanical stress and enhance the reaction kinetics, compounding with carbonaceous matrix to improve electrical conductivity, engineering alloys to strengthen the stability of active materials and optimizing electrolyte to build a stable solid electrolyte interface (SEI) film. [37][38][39][40][41][42][43][44][45][46][47] In this review, recent research progress on Bi-based electrode materials (e.g., metallic Bi and its oxides, sulfides, alloys and other compounds) for AIBs is summarized, mainly including the following three parts: 1) Thoroughly understand the relationship between the structure and performance of Bi-based materials and interface stability, focusing on the superior electrochemical performance of electrode materials.…”

Section: Introductionmentioning

confidence: 99%

Bi‐Based Electrode Materials for Alkali Metal‐Ion Batteries

Wang

Hong

Yang

et al. 2020

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Optimizing the Void Size of Yolk–Shell Bi@Void@C Nanospheres for High-Power-Density Sodium-Ion Batteries

Cited by 156 publications

References 56 publications

Revealing the Magnesium‐Storage Mechanism in Mesoporous Bismuth via Spectroscopy and Ab‐Initio Simulations

Revealing the Magnesium‐Storage Mechanism in Mesoporous Bismuth via Spectroscopy and Ab‐Initio Simulations

Yolk–Shell Fe₃O₄@Void@N‐Carbon Nanostructures Based on One‐Step Deposition of SiO₂ and Resorcinol‐3‐Aminophenol‐Formaldehyde (R‐APF) Cocondensed Resin Dual Layers onto Fe₃O₄ Nanoclusters

Bi‐Based Electrode Materials for Alkali Metal‐Ion Batteries

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Optimizing the Void Size of Yolk–Shell Bi@Void@C Nanospheres for High-Power-Density Sodium-Ion Batteries

Cited by 156 publications

References 56 publications

Revealing the Magnesium‐Storage Mechanism in Mesoporous Bismuth via Spectroscopy and Ab‐Initio Simulations

Revealing the Magnesium‐Storage Mechanism in Mesoporous Bismuth via Spectroscopy and Ab‐Initio Simulations

Yolk–Shell Fe3O4@Void@N‐Carbon Nanostructures Based on One‐Step Deposition of SiO2 and Resorcinol‐3‐Aminophenol‐Formaldehyde (R‐APF) Cocondensed Resin Dual Layers onto Fe3O4 Nanoclusters

Bi‐Based Electrode Materials for Alkali Metal‐Ion Batteries

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Yolk–Shell Fe₃O₄@Void@N‐Carbon Nanostructures Based on One‐Step Deposition of SiO₂ and Resorcinol‐3‐Aminophenol‐Formaldehyde (R‐APF) Cocondensed Resin Dual Layers onto Fe₃O₄ Nanoclusters