2D Layered Materials for Fast‐Charging Lithium‐Ion Battery Anodes

Yang, Yaxiong; Dong, Ruige; Cheng, Hao; Wang, Linlin; Tu, Jibing; Zhang, Shichao; Zhao, Sihan; Zhang, Bing; Pan, Hongge; Lü, Yingying

doi:10.1002/smll.202301574

Cited by 15 publications

(7 citation statements)

References 185 publications

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“…[ 115–117 ] Similar to other metal oxides, WO 3 also encounters insufficient charge separation and serious e − – h + recombination. [ 118–122 ] To overcome this issue, a variety of WO 3 ‐based nanostructures by interface engineering, such as 1D WO 3 NR/0D Cu 2 O NP, [ 123 ] TiO 2 /WO 3 /BiVO 4 brochosomes‐like nanostructures, [ 124 ] ultrathin 2D WO 3 /2D g‐C 3 N 4 , [ 125 ] and 2D WO 3 nanoplate/1D Bi 2 S 3 NR, [ 74 ] have been rationally designed and precisely fabricated to significantly improve the efficient separation of e − – h + pairs and remarkably enhance the PEC water splitting in recent years. [ 126–129 ] For example, Wang et al.…”

Section: Versatile Pec Applicationsmentioning

confidence: 99%

Recent Progress in Interface Engineering of Nanostructures for Photoelectrochemical Energy Harvesting Applications

et al. 2023

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With rapid and continuous consumption of nonrenewable energy, solar energy can be utilized to meet the energy requirement and mitigate environmental issues in the future. To attain a sustainable society with an energy mix predominately dependent on solar energy, photoelectrochemical (PEC) device, in which semiconductor nanostructure‐based photocatalysts play important roles, is considered to be one of the most promising candidates to realize the sufficient utilization of solar energy in a low‐cost, green, and environmentally friendly manner. Interface engineering of semiconductor nanostructures has been qualified in the efficient improvement of PEC performances including three basic steps, i.e., light absorption, charge transfer/separation, and surface catalytic reaction. In this review, recently developed interface engineering of semiconductor nanostructures for direct and high‐efficiency conversion of sunlight into available forms (e.g., chemical fuels and electric power) are summarized in terms of their atomic constitution and morphology, electronic structure and promising potential for PEC applications. Extensive efforts toward the development of high‐performance PEC applications (e.g., PEC water splitting, PEC photodetection, PEC catalysis, PEC degradation and PEC biosensors) are also presented and appraised. Last but not least, a brief summary and personal insights on the challenges and future directions in the community of next‐generation PEC devices are also provided.

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Section: Versatile Pec Applicationsmentioning

confidence: 99%

Recent Progress in Interface Engineering of Nanostructures for Photoelectrochemical Energy Harvesting Applications

et al. 2023

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“…4 Meanwhile, it is well known that the structural degradation and surface failure under fast-charging conditions of the anodes are more significant than those of the cathodes in LIBs. 43 Hence, the development of advanced fast-charging anodes is the main challenge faced by researchers.…”

Section: Introductionmentioning

confidence: 99%

Fast-charging anodes for lithium ion batteries: progress and challenges

Ding,

Zhou,

et al. 2024

Chem. Commun.

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“…9 To overcome the aforementioned problem, van der Waals heterostructure composites with extraordinary characteristics have been fabricated by integrating the metal chalcogenides with metal oxides. 10,11 Metallic-phase molybdenum disulfate (MoS 2 ) is one of the transition metal dichalcogenides that exhibits impressive performance in electrochemical conversion and storage. The unique structure of MoS 2 enables a high degree of surface accessibility for the ions and excellent electronic conductivity.…”

Section: Introductionmentioning

confidence: 99%

In Situ Electrophoretic Decorated Cactus-Type Metallic-Phase MoS₂ on CaMn₂O₄ Nanofibers for Binder-Free Next-Generation LIBs

Tandon,

Sharma

2024

ACS Appl. Mater. Interfaces

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Ternary manganese-based oxides, such as CaMn 2 O 4 (CMO) nanofibers fabricated via the electrospinning technique, have the potential to offer higher reversible capacity through conversion reactions in comparison to that of carbon-based anodes. However, its poor electrical conductivity hinders its usage in lithium-ion batteries (LIBs). Hence, to mitigate this issue, controlled single-step in situ decoration of highly conducting metallic-phase MoS 2 @CMO nanofibers has been achieved for the first time via the electrophoretic deposition (EPD) technique and utilized as a binder-free nanocomposite anode for LIBs. Further, the composition of MoS 2 @CMO nanofibers has also been optimized to attain better electronic and ionic conductivity. The morphological investigation revealed that the flakes of MoS 2 nanoflowers are successfully and uniformly decorated over the CMO nanofibers' surface, forming a cactus-type morphology. As a binder-free nanocomposite LIB anode, CMOMS-7 (7 wt % MoS 2 @ CMO) demonstrates a specific capacity of 674 mA h g −1 after 60 cycles at 50 mA g −1 and maintains a capacity of 454 mA h g −1 even after 300 cycles at 1000 mA g −1 . Further, the good rate performance (102 mA h g −1 at 5000 mA g −1 ) of CMOMS-7 can be ascribed to the enhanced electrical conductivity provided by the metallic-phase MoS 2 . Moreover, the feasibility of CMOMS-7 is thoroughly investigated by using a full Li-ion cell incorporating a binder-free cathode of LiNi 0.3 Mn 0.3 Co 0.3 O 2 (NMC). This configuration showcases an impressive energy density of 154 Wh kg −1 . Thus, the hierarchical and aligned structure of CMO nanofibers combined with highly conductive MoS 2 nanoflowers facilitates charge transportation within the composite electrodes. This synergistic effect significantly enhances the energy density of the conversion-based nanocomposites, making them highly promising anodes for advanced LIBs.

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2D Layered Materials for Fast‐Charging Lithium‐Ion Battery Anodes

Cited by 15 publications

References 185 publications

Recent Progress in Interface Engineering of Nanostructures for Photoelectrochemical Energy Harvesting Applications

Recent Progress in Interface Engineering of Nanostructures for Photoelectrochemical Energy Harvesting Applications

Fast-charging anodes for lithium ion batteries: progress and challenges

In Situ Electrophoretic Decorated Cactus-Type Metallic-Phase MoS₂ on CaMn₂O₄ Nanofibers for Binder-Free Next-Generation LIBs

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2D Layered Materials for Fast‐Charging Lithium‐Ion Battery Anodes

Cited by 15 publications

References 185 publications

Recent Progress in Interface Engineering of Nanostructures for Photoelectrochemical Energy Harvesting Applications

Recent Progress in Interface Engineering of Nanostructures for Photoelectrochemical Energy Harvesting Applications

Fast-charging anodes for lithium ion batteries: progress and challenges

In Situ Electrophoretic Decorated Cactus-Type Metallic-Phase MoS2 on CaMn2O4 Nanofibers for Binder-Free Next-Generation LIBs

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Product

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In Situ Electrophoretic Decorated Cactus-Type Metallic-Phase MoS₂ on CaMn₂O₄ Nanofibers for Binder-Free Next-Generation LIBs