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2020年 第3卷 第1期    刊出日期：2020-03-20

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REVIEW ARTICLE

Building Safe Lithium-Ion Batteries for Electric Vehicles: A Review

Jian Duan, Xuan Tang, Haifeng Dai, Ying Yang, Wangyan Wu, Xuezhe Wei, Yunhui Huang

2020, 3(1):  1-42.  doi:10.1007/s41918-019-00060-4

摘要 ( 777 )   PDF  

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Lithium-ion batteries (LIBs), with relatively high energy density and power density, have been considered as a vital energy source in our daily life, especially in electric vehicles. However, energy density and safety related to thermal runaways are the main concerns for their further applications. In order to deeply understand the development of high energy density and safe LIBs, we comprehensively review the safety features of LIBs and the failure mechanisms of cathodes, anodes, separators and electrolyte. The corresponding solutions for designing safer components are systematically proposed. Additionally, the in situ or operando techniques, such as microscopy and spectrum analysis, the fiber Bragg grating sensor and the gas sensor, are summarized to monitor the internal conditions of LIBs in real time. The main purpose of this review is to provide some general guidelines for the design of safe and high energy density batteries from the views of both material and cell levels.




Full-text：https://link.springer.com/article/10.1007/s41918-019-00060-4



Degradation Mechanisms and Mitigation Strategies of Nickel-Rich NMC-Based Lithium-Ion Batteries

Tianyu Li, Xiao-Zi Yuan, Lei Zhang, Datong Song, Kaiyuan Shi, Christina Bock

2020, 3(1):  43-80.  doi:10.1007/s41918-019-00053-3

摘要 ( 492 )   PDF  

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The demand for lithium-ion batteries(LIBs) with high mass-specific capacities, high rate capabilities and long-term cyclabilities is driving the research and development of LIBs with nickel-rich NMC(LiNi_xMn_yCo_1-x-yO₂, x ≥ 0.5) cathodes and graphite(Li_xC₆) anodes. Based on this, this review will summarize recently reported and widely recognized studies of the degradation mechanisms of Ni-rich NMC cathodes and graphite anodes. And with a broad collection of proposed mechanisms on both atomic and micrometer scales, this review can supplement previous degradation studies of Ni-rich NMC batteries. In addition, this review will categorize advanced mitigation strategies for both electrodes based on different modifications in which Ni-rich NMC cathode improvement strategies involve dopants, gradient layers, surface coatings, carbon matrixes and advanced synthesis methods, whereas graphite anode improvement strategies involve surface coatings, charge/discharge protocols and electrolyte volume estimations. Electrolyte components that can facilitate the stabilization of anodic solid electrolyte interfaces are also reviewed, and trade-offs between modification techniques as well as controversies are discussed for a deeper understanding of the mitigation strategies of Ni-rich NMC/graphite LIBs. Furthermore, this review will present various physical and electrochemical diagnostic tools that are vital in the elucidation of degradation mechanisms during operation to supplement future degradation studies. Finally, this review will summarize current research focuses and propose future research directions.




Full-text：https://link.springer.com/article/10.1007/s41918-019-00053-3



MOFs and COFs for Batteries and Supercapacitors

Xing Gao, Yu Dong, Siwu Li, Junwen Zhou, Lu Wang, Bo Wang

2020, 3(1):  81-126.  doi:10.1007/s41918-019-00055-1

摘要 ( 670 )   PDF  

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Metal-organic frameworks (MOFs) and covalent organic frameworks (COFs) as two burgeoning families of crystalline porous materials (CPMs) have been extensively investigated and applied in various fields on account of their enticing features as large surface area, controllable crystalline structure and highly ordered pores/channels. However, the greatest stumbling block to their widespread application in electrochemical energy storage systems is the inferior electrical conductivity. Therefore, numerous efforts have been exerted on exploiting the advantages and remedying the disadvantages. In this review, we mainly focus on pristine MOFs and COFs, emphasize the recent progress and highlight the milestones of their applications in the fields of lithium-ion batteries, lithium-sulfur batteries, lithium-air batteries and supercapacitors. We hope to provide a constructive view of the structure-activity relationship between CPMs and energy storage systems and promote their future development.




Full-text：https://link.springer.com/article/10.1007/s41918-019-00055-1



Multi-metal–Organic Frameworks and Their Derived Materials for Li/Na-Ion Batteries

Weiwei Sun, Xuxu Tang, Yong Wang

2020, 3(1):  127-154.  doi:10.1007/s41918-019-00056-0

摘要 ( 454 )   PDF  

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Lithium-ion and sodium-ion batteries are widely regarded as green energy storage power devices to support the development of modern electronic and information technology systems. Therefore, the design of advanced cathode and anode materials with higher energy and power densities is crucial to satisfy the increasing demand for next-generation high-performance batteries. To address this, researchers have explored metal-organic frameworks that possess extremely large surface areas, uniform ordered pores and controllable functional groups for application in the fields of energy storage, adsorption, catalysis, separation, etc. In addition, multi-metal-organic frameworks (MMOFs) and their derivatives have also been reported to provide better tunability to allow for the control of size, porosity, structure and composition, resulting in enhanced electronic and ion conductivities and richer redox chemistries at desirable potentials. Moreover, the synergistic effects between two or more metal components in MMOFs and their derivatives can accommodate large volume expansions during stepwise Li-/Na-ion insertion and extraction processes to allow for the improvement of structural stability in electrodes as well as enhanced cyclability. Based on all of this, this review will discuss and summarize the most recent progress in the synthesis, electrochemical performance and design of MMOFs and their derivatives. In addition, future trends and prospects in the development of MMOF-based materials and their application as high-performance Li/Na storage electrode materials are presented.




Full-text：https://link.springer.com/article/10.1007/s41918-019-00056-0



Materials and Fabrication Methods for Electrochemical Supercapacitors: Overview

Prasad Eknath Lokhande, Umesh S. Chavan, Abhishek Pandey

2020, 3(1):  155-186.  doi:10.1007/s41918-019-00057-z

摘要 ( 443 )   PDF  

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The rapid economic development and immense growth in the portable electronic market create tremendous demand for clean energy sources and energy storage and conversion technologies. To meet this demand, supercapacitors have emerged as a promising technology to store renewable energy resources. Based on this, this review will provide a detailed and current overview of the various materials explored as potential electrodes and electrolytes in the development of efficient supercapacitors along with corresponding synthesis routes and electrochemical properties. In addition, this review will provide introductions into the various types of supercapacitors as well as fundamental parameters that affect supercapacitor performance. Finally, this review will conclude with presentations on the role of electrolytes in supercapacitors and corresponding materials along with challenges and perspectives to guide future development.




Full-text：https://link.springer.com/article/10.1007/s41918-019-00057-z



Advanced Characterizations of Solid Electrolyte Interphases in Lithium-Ion Batteries

Yanli Chu, Yanbin Shen, Feng Guo, Xuan Zhao, Qingyu Dong, Qingyong Zhang, Wei Li, Hui Chen, Zhaojun Luo, Liwei Chen

2020, 3(1):  187-219.  doi:10.1007/s41918-019-00058-y

摘要 ( 644 )   PDF  

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Solid electrolyte interphases (SEIs) in lithium-ion batteries (LIBs) are ionically conducting but electronically insulating layers on electrode/electrolyte interfaces that form through the decomposition of electrolytes. And although SEIs can protect electrodes from the co-intercalation of solvent molecules and prevent the continued decomposition of electrolytes, their formation can consume active lithium and electrolytes and build up impedance for ion conduction. Therefore, the control of SEI structures and properties to allow for stability and ionic conductivity has become a critical but highly challenging task in battery designs. However, several factors contribute to the difficulty in SEI research. First, the chemical and electrochemical reactions leading to SEI formation are immensely complex and heavily influenced by numerous factors including electrolyte solvents, lithium salts, additives, electrode materials and charge/discharge conditions. Second, the chemical nature of film-formation products such as SEI constituents and their distribution and arrangement in the SEI are complex. Finally, SEIs are in situ formed at the electrode/electrolyte interface in assembled batteries, making the direct observation of SEIs difficult. To address these challenges, the development of advanced characterization techniques is key in the fundamental understanding of SEIs in LIBs. Based on this, this review will provide an overview of the progress in SEI characterization, including methods to investigate electrochemical performance, surface morphology, chemical composition, and structure and mechanical properties, with state-of-the-art characterization techniques developed in recent years being emphasized. And overall, the scientific insights obtained by using these advanced methods will help researchers to better understand electrode/electrolyte interfaces toward the development of high-performance secondary batteries.




Full-text：https://link.springer.com/article/10.1007/s41918-019-00058-y