Low‐Temperature Synthesis of Amorphous Silicon and Its Ball‐in‐Ball Hollow Nanospheres as High‐Performance Anodes for Sodium‐Ion Batteries

Du, Fei‐Hu; Zhang, Ling; Tang, Yuncheng; Li, Shang-Qi; Huang, Yu; Dong, Le; Li, Qianqian; Liu, Hong; Wang, Dong; Wang, Yong

doi:10.1002/admi.202102158

Cited by 11 publications

(6 citation statements)

References 27 publications

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“…[135] Amorphous hollow silicon nanospheres produced via low-temperature synthesis can also enhance the cycling stability of batteries. [137] There are many other reported amorphous anode materials such as MoS x , [138] P 2 S 5 , [139] MoS 3 , [140] MoS 2 -MoO 3 -carbon, [141] FeOOH, [142] CuSnO 3 , [143] CoS, [144] CoMoS 4 , [145] Co 2 P, [146] Bi 2 S 3 , [147] P 4 SSe 2 , [148] antimony (Sb), [149] Sb 2 S 3 , [150] Sb 2 Se 3 , [151] SnSe, [152] Sn 2 P 2 O 7 , [153] SnO 2 , [154] TiO 2 , [155] V 2 O 5 , [156] VO 2 , [157] Zn 2 V 2 O 7 , [158] phosphorus (P), [159] Co─Sn─S, [160] SnO x P y , [161] SnO x , [162] zinc oxysulfide, [163] etc. In the future, it is necessary to further evaluate the index parameters of the reported amorphous anode materials from the perspective of commercialization.…”

Section: Non-glass Ams For Sodium Batteriesmentioning

confidence: 99%

Amorphous Materials for Lithium‐Ion and Post‐Lithium‐Ion Batteries

Ding,

Ji,

Yue

et al. 2023

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Lithium‐ion and post‐lithium‐ion batteries are important components for building sustainable energy systems. They usually consist of a cathode, an anode, an electrolyte, and a separator. Recently, the use of solid‐state materials as electrolytes has received extensive attention. The solid‐state electrolyte materials (as well as the electrode materials) have traditionally been overwhelmingly crystalline materials, but amorphous (disordered) materials are gradually emerging as important alternatives because they can increase the number of ion storage sites and diffusion channels, enhance solid‐state ion diffusion, tolerate more severe volume changes, and improve reaction activity. To develop superior amorphous battery materials, researchers have conducted a variety of experiments and theoretical simulations. This review highlights the recent advances in using amorphous materials (AMs) for fabricating lithium‐ion and post‐lithium‐ion batteries, focusing on the correlation between material structure and properties (e.g., electrochemical, mechanical, chemical, and thermal ones). We review both the conventional and the emerging characterization methods for analyzing AMs and present the roles of disorder in influencing the performances of various batteries such as those based on lithium, sodium, potassium, and zinc. Finally, we describe the challenges and perspectives for commercializing rechargeable AMs‐based batteries.

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Section: Non-glass Ams For Sodium Batteriesmentioning

confidence: 99%

Amorphous Materials for Lithium‐Ion and Post‐Lithium‐Ion Batteries

Ding,

Ji,

Yue

et al. 2023

Small

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“…[ 134 ] Li et al developed a new method called “sodiothermic reduction” for the preparation of amorphous silicon hollow nanospheres at lower temperatures and designed amorphous silicon matrix composites with yolk–shell structure by deposition of alumina atomic layers, in situ chemical polymerization of pyrrole, and dilute hydrochloric acid etching; the obtained composites all showed very good electrochemical properties as anode materials for sodium‐ion batteries, which are useful for the study of amorphous silicon anode materials for LIBs. [ 135 ] A‐Si preparation into thin films can shorten the ion diffusion length, thus promoting ion transport and storing more Li. [ 136 ] Thicker films are needed to meet the high energy density requirements for meeting LIBs, but increasing the thickness of the film will make the adhesion between the film and the collector decrease, leading to the detachment of both and thus the electrochemical performance, [ 137 ] so there is a need to reconcile the relationship between thickness and electrochemical performance as required.…”

Section: Other Optimization Schemesmentioning

confidence: 99%

Structural Control and Optimization Schemes of Silicon‐Based Anode Materials

Zhu

Zeng

et al. 2023

Energy Tech

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Rechargeable lithium‐ion batteries (LIBs) are today's best performing and most promising energy storage devices. Silicon‐based anode materials with ultrahigh specific capacity are expected to help LIBs play a more significant role in practical applications. However, the irreversible volume expansion of silicon during charge and discharge, which makes the material devastatingly shattered, and the unstable solid electrolyte intermediate film have greatly affected the LIB cycle stability and slowed the commercialization of silicon‐based anode LIBs. In recent years, various approaches have been tried to reduce the adverse effects of bulk effects, and nanosizing is a widely recognized and practical approach. Still, it has also reached a bottleneck in development. This work provides a comprehensive review of the recent progress in improving the electrochemical performance of silicon‐based anode LIBs. The development of mainstream silicon‐based compounds is described, the role of various structural control means for the improvement of silicon‐based anodes is elaborated, as well as other optimization schemes, and a view on the future development of silicon‐based anodes is presented.

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“…However, the actual performance of TMOs is much lower than expected as their capacity rapidly decays even at lower current rates due to disintegration/fragmentation of the electrode material as a result of significant volume changes during charging/discharging, and scientists have proposed the production of a variety of porous nanostructured materials to address these issues. , These materials involve well-organized hierarchical micro/nanostructures composed of secondary superstructures formed through the ordered assembly of nanounits. TMOs with a hierarchical arrangement benefit from the nanoscale structure (e.g., nanoparticles, nanosheets, and nanorods), as well as the nanoscale assemblies (such as mesoporous nanocubes, hollow nanospheres, ball-in-ball nanospheres, and mesoporous spindle-like nanostructure). These hierarchical structures exhibit a buffering effect, effectively mitigating structural strain and promoting improved contact between the electrode and electrolyte interface. , Additionally, carbon-based additives for forming nanocomposites with TMOs nanostructures not only improve the mechanical flexibility of the mixed materials to buffer volume changes during charging and discharging but also improve the electrical conductivity.…”

Section: Introductionmentioning

confidence: 99%

In Situ Flash Synthesis of Ultra-High-Performance Metal Oxide Anode through Shunting Current-Based Electrothermal Shock

Wu,

Qi,

Peng

et al. 2024

ACS Appl. Mater. Interfaces

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The synthesis of anode materials plays an important role in determining the production efficiency, cost, and performance of lithium-ion batteries (LIBs). However, a low-cost, high-speed, scalable manufacturing process of the anode with the desired structural feature for practical technology adoption remains elusive. In this study, we propose a novel method called in situ flash shuntelectrothermal shock (SETS) which is controllable, fast, and energy-saving for synthesizing metal oxide-based materials. By using the example of direct electrothermal decomposition of ZIF-67 precursor loaded onto copper foil support, we achieve rapid (0.1−0.3 s) pyrolysis and generate porous hollow cubic structure material consisting of carbon-coated ultrasmall (10−15 nm) subcrystalline CoO/Co nanoparticles with controllable morphology. It was shown that CoO/Co@N-C exhibits prominent electrochemical performance with a high reversible capacity up to 1503.7 mA h g −1 after 150 cycles at 0.2 A g −1 and stable capacities up to 434.1 mA h g −1 after 400 cycles at a high current density of 6 A g −1 . This fabrication technique integrates the synthesis of active materials and the formation of electrode sheets into one process, thus simplifying the preparation of electrodes. Due to the simplicity and scalability of this process, it can be envisaged to apply it to the synthesis of metal oxide-based materials and to achieve large-scale production in a nanomanufacturing process.

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Low‐Temperature Synthesis of Amorphous Silicon and Its Ball‐in‐Ball Hollow Nanospheres as High‐Performance Anodes for Sodium‐Ion Batteries

Cited by 11 publications

References 27 publications

Amorphous Materials for Lithium‐Ion and Post‐Lithium‐Ion Batteries

Amorphous Materials for Lithium‐Ion and Post‐Lithium‐Ion Batteries

Structural Control and Optimization Schemes of Silicon‐Based Anode Materials

In Situ Flash Synthesis of Ultra-High-Performance Metal Oxide Anode through Shunting Current-Based Electrothermal Shock

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