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

Zhang, Fangzhou; Luo, Wei; Yang, Jianping

doi:10.1002/asia.202000164

Cited by 25 publications

(10 citation statements)

References 72 publications

(87 reference statements)

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“…The above results indicated that greatly suppressed cracking and pulverization could be achieved for the Li/B-SiO x @C anodes, which is extremely important for its significantly improved cycling and rate performance. Heteroatom doping can reform the internal chemical bonding and structure of Si-based anodes, which is therefore in favor of maintaining the structural integrity and improving the electrochemical performance of Si-based anodes. − It is believed that the B doping plays a key role in the formation of a strong bonding network within the Li/B-SiO x @C particles and therefore endows the Li/B-SiO x @C anodes with great resistance to cracking and pulverization during cycling and significantly improves the cycling and rate performance. ,, In Figure d,h, the Young’s modulus of lithiated SiO x @C and Li/B-SiO x @C anodes was obtained via AFM characterization. The Li/B-SiO x @C anode exhibited a greatly higher Young’s modulus (3283.82 MPa) than the SiO x @C anode (425.22 MPa), implying the strong bonding networks within the lithiated Li/B-SiO x @C anode …”

Section: Resultsmentioning

confidence: 99%

“…Heteroatom (e.g., phosphorus (P), boron (B), aluminum (Al), and magnesium (Mg)) doping can reform the electronic structure, chemical bonding, and interfacial property of Si-based anodes, thereby alleviating or reducing the volume expansion of Si-based anodes and improving their electrochemical performance. − For example, Zou et al reported a coral-like P-doped Si anode showing an excellent rate capability (911 mA h g –1 at 16 A g –1 ) and long cycling stability (1564 mA h g –1 after 100 cycles at 2 A g –1 ). Sun et al employed B doping and carbon nanotubes to enable the stable cycling of Si anodes with a capacity retention of 88.2% after 200 cycles.…”

Section: Introductionmentioning

confidence: 99%

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Lithium/Boron Co-doped Micrometer SiO_x as Promising Anode Materials for High-Energy-Density Li-Ion Batteries

Zhao

Tian

et al. 2022

ACS Appl. Mater. Interfaces

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The carbon-coated silicon monoxide (SiO x @C) has been considered as one of the most promising high-capacity anodes for the next-generation high-energy-density lithium-ion batteries (LIBs). However, the relatively low initial Coulombic efficiency (ICE) and the still existing huge volume expansion during repeated lithiation/delithiation cycling remain the greatest challenges to its practical application. Here, we developed a lithium and boron (Li/B) co-doping strategy to efficiently enhance the ICE and alleviate the volume expansion or pulverization of SiO x @C anodes. The in situ generated Li silicates (Li x SiO y ) by Li doping will reduce the active Li loss during the initial cycling and enhance the ICE of SiO x @C anodes. Meanwhile, B doping works to promote the Li + diffusion and strengthen the internal bonding networks within SiO x @C, enhancing its resistance to cracking and pulverization during cycling. As a result, the enhanced ICE (83.28%), suppressed volume expansion, and greatly improved cycling (85.4% capacity retention after 200 cycles) and rate performance could be achieved for the Li/B co-doped SiO x @C (Li/B-SiO x @C) anodes. Especially, the Li/B-SiO x @C and graphite composite anodes with a capacity of 531.5 mA h g −1 were demonstrated to show an ICE of 90.1% and superior cycling stability (90.1% capacity retention after 250 cycles), which is significant for the practical application of high-energy-density LIBs.

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Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Lithium/Boron Co-doped Micrometer SiO_x as Promising Anode Materials for High-Energy-Density Li-Ion Batteries

Zhao

Tian

et al. 2022

ACS Appl. Mater. Interfaces

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“…A semicircle is shown in the high-frequency region, which corresponds to the charge-transfer impedance (R ct ). 49,50 The sloping straight line at the low frequency region is related to Warburg impedance, 51 indicating the resistance of ion diffusion into the active material. 52 It can be obtained that the R ct of the GSCC electrode is about 72 Ω, which is lower than those of the SC (291 Ω) and GSC (138 Ω) electrodes, indicating that the introduction of Gr and the amorphous carbon layer can significantly improve the electronic conductivity of the materials.…”

Section: ■ Results and Discussionmentioning

confidence: 99%

Structure Design and Performance of the Graphite/Silicon/Carbon Nanotubes/Carbon (GSCC) Composite as the Anode of a Li-Ion Battery

Huang

Peng

et al. 2021

Energy Fuels

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Silicon (Si) or Si-based compounds have been paid much attention in the field of lithium-ion battery anodes on account of desirable theoretical capacity, moderate working voltage, abundant resources, and bing nontoxic. However, some disadvantages, including inferior electrical conductivity and enormous volume change in the process of lithiation/delithiation, hinder their widespread application in commercial lithium-ion batteries. To solve the above problems, we designed and prepared the graphite/silicon/carbon nanotubes/carbon (GSCC) composites with hierarchical structure. Herein, the graphite can absorb the bulk expansion stress of the Si particles. The carbon layer carbonized by pitch can further mitigate the volume change and physically separate Si and electrolyte, and an admirable conductive network can be provided by the carbon nanotube. As a consequence, the as-prepared GSCC electrode possesses a capacity of 1100.6 mAh g −1 at 0.2 A g −1 and high initial coulomb efficiency (ICE) of 78% and has a good capacity retention of 73%. Therefore, the combinational design of the graphite/silicon/ carbon nanotubes/carbon for the preparation of a silicon-based anode material is a meaningful exploration for large-scale production and commercial application in lithium ion batteries.

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“…Among alloying‐type materials, Si has received distinctive attention because of its high theoretical capacity up to 4200 mA h g −1 and natural abundance. [ 106 ] Early in 2012, Gu and co‐workers probed the lithiation behavior of silicon nanoparticles attached to (embedded in) a CNF using in situ TEM and theoretical analysis. [ 107 ] As shown in Figure 11d , e , compared to the attached structure, the lithiated silicon nanoparticles embedded in a carbon matrix will result in a high stress field, which may lead to the fracture of the CNF.…”

Section: Applications Of Oihfsmentioning

confidence: 99%

Organic/Inorganic Hybrid Fibers: Controllable Architectures for Electrochemical Energy Applications

et al. 2021

Self Cite

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Organic/inorganic hybrid fibers (OIHFs) are intriguing materials, possessing an intrinsic high specific surface area and flexibility coupled to unique anisotropic properties, diverse chemical compositions, and controllable hybrid architectures. During the last decade, advanced OIHFs with exceptional properties for electrochemical energy applications, including possessing interconnected networks, abundant active sites, and short ion diffusion length have emerged. Here, a comprehensive overview of the controllable architectures and electrochemical energy applications of OIHFs is presented. After a brief introduction, the controllable construction of OIHFs is described in detail through precise tailoring of the overall, interior, and interface structures. Additionally, several important electrochemical energy applications including rechargeable batteries (lithium-ion batteries, sodium-ion batteries, and lithium-sulfur batteries), supercapacitors (sandwich-shaped supercapacitors and fiber-shaped supercapacitors), and electrocatalysts (oxygen reduction reaction, oxygen evolution reaction, and hydrogen evolution reaction) are presented. The current state of the field and challenges are discussed, and a vision of the future directions to exploit OIHFs for electrochemical energy devices is provided.

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

Cited by 25 publications

References 72 publications

Lithium/Boron Co-doped Micrometer SiO_x as Promising Anode Materials for High-Energy-Density Li-Ion Batteries

Lithium/Boron Co-doped Micrometer SiO_x as Promising Anode Materials for High-Energy-Density Li-Ion Batteries

Structure Design and Performance of the Graphite/Silicon/Carbon Nanotubes/Carbon (GSCC) Composite as the Anode of a Li-Ion Battery

Organic/Inorganic Hybrid Fibers: Controllable Architectures for Electrochemical Energy Applications

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

Cited by 25 publications

References 72 publications

Lithium/Boron Co-doped Micrometer SiOx as Promising Anode Materials for High-Energy-Density Li-Ion Batteries

Lithium/Boron Co-doped Micrometer SiOx as Promising Anode Materials for High-Energy-Density Li-Ion Batteries

Structure Design and Performance of the Graphite/Silicon/Carbon Nanotubes/Carbon (GSCC) Composite as the Anode of a Li-Ion Battery

Organic/Inorganic Hybrid Fibers: Controllable Architectures for Electrochemical Energy Applications

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Lithium/Boron Co-doped Micrometer SiO_x as Promising Anode Materials for High-Energy-Density Li-Ion Batteries

Lithium/Boron Co-doped Micrometer SiO_x as Promising Anode Materials for High-Energy-Density Li-Ion Batteries