Boron-Doped Spherical Hollow-Porous Silicon Local Lattice Expansion toward a High-Performance Lithium-Ion-Battery Anode

Ren, Yongpeng; Zhou, Xiangyang; Tang, Jingjing; Ding, Jing; Chen, Song; Zhang, Jiaming; Hu, Tingjie; Yang, Xu Sheng; Wang, Xinming

doi:10.1021/acs.inorgchem.9b00158

Cited by 54 publications

(41 citation statements)

References 42 publications

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“…Moreover, the larger pores can also help in promoting better SEI formation and overall structure preservation . The interconnected porous structure also promotes the efficient transport of electrons and lithium ions . The methods for preparing porous silicon mainly include magnesiothermic reduction and acid/alkali etching.…”

Section: Suitable Structural Design Of Silicon Anodementioning

confidence: 99%

Silicon Anodes for High‐Performance Storage Devices: Structural Design, Material Compounding, Advances in Electrolytes and Binders

Hou

Yang

2020

ChemNanoMat

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Silicon has an extremely high theoretical capacity, a low voltage platform, and abundant natural reserves. It is considered to be one of the most promising anode materials for lithium-ion batteries. However, there are still many problems with silicon as an anode material for lithium-ion batteries. During the lithiation/delithiation of silicon, a huge volume expansion occurs, causing the silicon particles to pulverize and the capacity to drop sharply. Furthermore, the continuous increase in the silicon surface solid electrolyte interphase (SEI) films and the poor conductivity of silicon affect the specific capacity of the battery. Means to improve silicon-based anodes with regard to electrode cycling performance and electrode capacity include structural design, composite preparation, or improvements in electrolytes and binders (for example, designing silicon nanomaterials of different dimensions from 0D to 3D, including silicon nanoparticles, nanowires, nanorods, thin films, porous silicon, and core-shell structures). Silicon has been combined with different materials to buffer its own volume expansion, resulting in excellent performance. In addition, the design of a reasonable electrolyte solution, as well as the development of a selfhealing binder is one of the main methods to improve Sibased anodes. In recent years, sodium/potassium ion batteries have been increasingly studied, and silicon and sodium/potassium can be alloyed. The corresponding theoretical capacity can reach 954 mAh g À 1 and 955 mAh g À 1 , respectively. Advances in silicon-based anodes for sodium/ potassium ion storage are summarized herein.ductility. [25] It can increase the conductivity of silicon and adapt to the large volume expansion of silicon. In addition, some are compounded with silicon or metal or metal oxides. Such as copper, silver, tin oxide and titanium oxide. [39][40][41][42][43][44] In addition to changing the silicon's own morphological structure and preparing composite materials, the design and selection of electrolytes and binders is to improve the performance of silicon-based electrodes from the outside. By selecting the appropriate electrolytes, the electrode materials can be effectively reduced deterioration. At present, various additive-modified organic solvent electrolytes, ionic liquid electrolytes, and all-solid electrolytes are widely used in silicon-based anodes. [45][46][47][48] In addition, it is widely applicable to the binder polyvinylidene fluoride(PVDF) of lithium ion battery electrode materials, but

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Section: Suitable Structural Design Of Silicon Anodementioning

confidence: 99%

Silicon Anodes for High‐Performance Storage Devices: Structural Design, Material Compounding, Advances in Electrolytes and Binders

Hou

Yang

2020

ChemNanoMat

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“…The latter Si subgrains are dedicated to the high cycling stability by alleviating the volume change. [101] Unlike B doping (p-type) with higher insertion potential, the P-doped Si has lower Li insertion potential, indicating the smaller thermodynamic driving force for lithiation. [106][107] Sakaguchi et al have investigated the effect of P dopant on reactive behavior and the electrochemical performance of Si electrodes.…”

Section: Si-based Electrodesmentioning

confidence: 99%

“…[117] Furthermore, O vacancies can promote phase transition at the electrode/electrolyte interface by the modification of surface thermodynamics and avoid the structural disintegration on the electrode surface. [118] For instance, intrinsic structural instabilities of MnO with wurtzite Reproduced with permission from Ref., [101] Copyright 2019, American Chemical Society. (b) Schematic diagram and long cycling performance (when coated with carbon and graphene oxide) of porous Si from Fe and B defect etching.…”

Section: Transition Metal Oxides and Derivativesmentioning

confidence: 99%

Function and Application of Defect Chemistry in High‐Capacity Electrode Materials for Li‐Based Batteries

Qiao

Lin

Yan

et al. 2020

Chemistry An Asian Journal

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Current commercial Li-based batteries are approaching their energy density limitation, yet still cannot satisfy the energy density demand of the high-end devices. Hence, it is critical to developing advanced electrode materials with high specific capacity. However, these electrode materials are facing challenges of severe structural degradation and fast capacity fading. Among various strategies, constructing defects in electrode materials holds great promise in addressing these issues. Herein, we summarize a series of significant defect engineering in the high-capacity electrode materials for Li-based batteries. The detailed retrospective on defects specification, function mechanism, and corresponding application achievements on these electrodes are discussed from the view of point, line, planar, volume defects. Defect engineering can not only stabilize the structure and enhance electric/ionic conductivity, but also act as active sites to improve the ionic storage and bonding ability of electrode materials to Li metal. We hope this review can spark more perspectives on evaluating high-energydensity Li-based batteries.

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“…Boron (1s 2 2s 2 2p 1 ), as a graphitization catalyst, can significantly enhance the graphitization of carbon . Boron doping could modify the electronic properties of the graphitic framework, which is beneficial for lithium ion transport behavior . It has been widely confirmed that boron doping can improve the specific capacity and coulombic efficiency of Si‐based composite anode.…”

Section: Boron Dopingmentioning

confidence: 99%

Interface Heteroatom‐doping: Emerging Solutions to Silicon‐based Anodes

Zhang

Luo

Yang

2020

Chemistry An Asian Journal

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Silicon-based composites have been recognized as a promising anode material for high-energy lithium-ion batteries (LIBs). However, the intrinsically low conductivity and the huge volume expansion during lithiation/delithiation progresses impede its further practical applications. In the past decades, numerous efforts have been made for surface and interface modification of Si-based anodes. Among these, doping of active materials with heteroatoms is one promising method to endow silicon many unmatched electrochemical properties. In this review, we focus on the effects of heteroatom doping on the interfacial properties of Si-based anodes, and some typical strategies for the interface doping are highlighted. We aim to give some reference for interfacial doping of Si-based anodes in LIBs. 2 3 4 5 6 7 8

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Boron-Doped Spherical Hollow-Porous Silicon Local Lattice Expansion toward a High-Performance Lithium-Ion-Battery Anode

Cited by 54 publications

References 42 publications

Silicon Anodes for High‐Performance Storage Devices: Structural Design, Material Compounding, Advances in Electrolytes and Binders

Silicon Anodes for High‐Performance Storage Devices: Structural Design, Material Compounding, Advances in Electrolytes and Binders

Function and Application of Defect Chemistry in High‐Capacity Electrode Materials for Li‐Based Batteries

Interface Heteroatom‐doping: Emerging Solutions to Silicon‐based Anodes

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