A Ge/Carbon Atomic‐Scale Hybrid Anode Material: A Micro–Nano Gradient Porous Structure with High Cycling Stability

Yang, Zhiwei; Chen, Ting; Chen, Dequan; Shi, Xinyu; Yang, Shan; Zhong, Yanjun; Liu, Yuxia; Wang, Gongke; Zhong, Benhe; Song, Yang; Wu, Zhenguo; Guo, Xiaodong

doi:10.1002/ange.202102048

“…[17] However, these favorable properties are overshadowed by its relatively poor rate performance, severe capacity loss, and electrode pulverization. [18,19] This severe capacity loss and electrode pulverization are primarily induced by large volume expansion and contraction during Na + uptake and release, respectively.…”

Section: Introductionmentioning

confidence: 99%

Tailoring Ultrafast and High‐Capacity Sodium Storage via Binding‐Energy‐Driven Atomic Scissors

Peng

¹

,

Lv

²

,

Xu

³

et al. 2022

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Controllably tailoring alloying anode materials to achieve fast charging and enhanced structural stability is crucial for sodium‐ion batteries with high rate and high capacity performance, yet remains a significant challenge owing to the huge volume change and sluggish sodiation kinetics. Here, a chemical tailoring tool is proposed and developed by atomically dispersing high‐capacity Ge metal into the rigid and conductive sulfide framework for controllable reconstruction of GeS bonds to synergistically realize high capacity and high rate performance for sodium storage. The integrated GeTiS3 material with stable Ti–S framework and weak GeS bonding delivers high specific capacities of 678 mA h g−1 at 0.3 C over 100 cycles and 209 mA h g−1 at 32 C over 10 000 cycles, outperforming most of the reported alloying type anode materials for sodium storage. Interestingly, in situ Raman, X‐ray diffraction (XRD), and ex situ transmission electron microscopy (TEM) characterizations reveal the formation of well‐dispersed NaxGe confined in the rigid Ti–S matrix with suppressed volume change after discharge. The synergistically coupled alloying‐conversion and surface‐dominated redox reactions with enhanced capacitive contribution and high reaction reversibility by a binding‐energy‐driven atomic scissors method would break new ground on designing a high‐rate and high‐capacity sodium‐ion batteries.

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A Simple Gas–Solid Treatment for Surface Modification of Li‐Rich Oxides Cathodes

Ye

¹

,

Zhang²,

Chen

³

et al. 2021

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Li-richl ayered oxides with high capacity are expected to be the next generation of cathode materials. However,t he irreversible and sluggish anionic redox reaction leads to the O 2 loss in the surface as well as the capacity and voltage fading.I nt he present study,asimple gas-solid treatment with ferrous oxalate has been proposed to uniformly coat at hin spinel phase layer with oxygen vacancy and simultaneously realize Fe-ion substitution in the surface.T he integration of oxygen vacancy and spinel phase suppresses irreversible O 2 release,p revents electrolyte corrosion, and promotes Li-ion diffusion. In addition, the surface doping of Fe-ion can further stabilizet he structure.A ccordingly,t he treated Feox-2 %c athode exhibits superior capacity retention of 86.4 %a nd 85.5 %a t1Ca nd 2C to that (75.3 %a nd 75.0 %) of the pristine sample after 300 cycles,r espectively. Then, the voltage fading is significantly suppressed to 0.0011 V per cycle at 2Cespecially.T he encouraging results may play asignificant role in paving the practical application of Li-rich layered oxides cathode.

show abstract

A Simple Gas–Solid Treatment for Surface Modification of Li‐Rich Oxides Cathodes

Ye

¹

,

Zhang²,

Chen

³

et al. 2021

Self Cite

View full text Add to dashboard Cite

Li-richl ayered oxides with high capacity are expected to be the next generation of cathode materials. However,t he irreversible and sluggish anionic redox reaction leads to the O 2 loss in the surface as well as the capacity and voltage fading.I nt he present study,asimple gas-solid treatment with ferrous oxalate has been proposed to uniformly coat at hin spinel phase layer with oxygen vacancy and simultaneously realize Fe-ion substitution in the surface.T he integration of oxygen vacancy and spinel phase suppresses irreversible O 2 release,p revents electrolyte corrosion, and promotes Li-ion diffusion. In addition, the surface doping of Fe-ion can further stabilizet he structure.A ccordingly,t he treated Feox-2 %c athode exhibits superior capacity retention of 86.4 %a nd 85.5 %a t1Ca nd 2C to that (75.3 %a nd 75.0 %) of the pristine sample after 300 cycles,r espectively. Then, the voltage fading is significantly suppressed to 0.0011 V per cycle at 2Cespecially.T he encouraging results may play asignificant role in paving the practical application of Li-rich layered oxides cathode.

show abstract

A Ge/Carbon Atomic‐Scale Hybrid Anode Material: A Micro–Nano Gradient Porous Structure with High Cycling Stability

Cited by 4 publications

References 56 publications

Tailoring Ultrafast and High‐Capacity Sodium Storage via Binding‐Energy‐Driven Atomic Scissors

Tailoring Ultrafast and High‐Capacity Sodium Storage via Binding‐Energy‐Driven Atomic Scissors

A Simple Gas–Solid Treatment for Surface Modification of Li‐Rich Oxides Cathodes

A Simple Gas–Solid Treatment for Surface Modification of Li‐Rich Oxides Cathodes

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