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Artículos de revistas sobre el tema "Battery Materials (Lithium"

Autor: Grafiati
Publicado: 7 de junio de 2025
Última modificación: 2 de agosto de 2025

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1

Moog, Reviewed by Iona, and Sarah Ball. "Lithium Battery Discussions ‐ Electrode Materials." Johnson Matthey Technology Review 60, no. 3 (2016): 204–8. http://dx.doi.org/10.1595/205651316x691979.

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2

D'Andrea, S., S. Panero, P. Reale, and B. Scrosati. "Advanced lithium ion battery materials." Ionics 6, no. 1-2 (2000): 127–32. http://dx.doi.org/10.1007/bf02375556.

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3

Zhu, Xiaoxiao. "Application metal oxide cathode materials for lithium ion batteries." Highlights in Science, Engineering and Technology 90 (April 8, 2024): 69–73. http://dx.doi.org/10.54097/vx5md855.

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The popularity of portable electronic devices has boosted the speedy advancement of devices for storing electrical energy. At the same time, the development of electric vehicles urgently requires lithium batteries to have higher power density and performance. The strong points of lithium ion battery are environmental friendliness, also specific capacity of high level. Lithium cathode material is one of the key factors affecting battery performance. The requirements for positive electrode materials are good safety, good service life, and less self-discharge. Among all cathode materials, metal o
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4

Yu, Yicheng. "Status and Development of Cathode Materials for Lithium-Ion Batteries." Highlights in Science, Engineering and Technology 90 (April 8, 2024): 74–80. http://dx.doi.org/10.54097/hvg1zz63.

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Driven by the energy transition and the wave of electrification, efficient battery technology is a core requirement in today's society. Lithium-ion batteries, with their high energy density and long lifespan, occupy an important place in sustainable energy storage solutions. However, the overall performance and economics of the batteries greatly depend on the cathode materials used in them, and innovations in this area are critical to the advancement of battery technology. This study focuses on the latest research findings on cathode materials for lithium-ion batteries, providing an in-depth a
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5

Liu, Run Yu. "Recent Progress of Anode and Cathode Materials for Lithium Ion Battery." Materials Science Forum 1027 (April 2021): 69–75. http://dx.doi.org/10.4028/www.scientific.net/msf.1027.69.

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Lithium ion battery is a kind of secondary battery that mainly relies on lithium ions moving between a positive electrode and a negative electrode. Lithium-ion batteries are considered to be the most ideal automotive power battery and has been widely applied in EV industry due to the outstanding advantages including but not limited to high energy density, high open circuit voltage and wide operating temperature range. The technical bottleneck of lithium-ion power batteries is how to further increase the energy density and optimize operating performance at low temperature. Besides, how to decre
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6

Sun, Weihao. "Comparison of Different Nanomaterials in Anode Materials of Lithium Battery." Applied and Computational Engineering 126, no. 1 (2025): 176–81. https://doi.org/10.54254/2755-2721/2025.20078.

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The increasing demand for sustainable energy necessitates the enhancement of lithium-ion battery technology, especially in the advancement of superior anode materials. Contemporary lithium-ion batteries exhibit specific constraints, including comparatively poor energy density and restricted cycle life, which have stimulated growing interest in alternative battery materials with superior performance. This research conducts a literature analysis to investigate the potential of several nanomaterialsgraphene, clay mineral-derived materials, and transition metal sulfidesas improved anode materials
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7

Huang, Xudong. "Cathode Materials of Lithium Ion Battery." Highlights in Science, Engineering and Technology 43 (April 14, 2023): 521–26. http://dx.doi.org/10.54097/hset.v43i.7472.

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Lithium ion battery (LIB) technology is getting more and more attention for its superior electrochemical property in recent years and has begun to gradually enter the market occupying a certain part of market. The cathode conducts as an important part of LIB, its material will influence the overall performance of the battery greatly. This paper classifies and introduces multiple cathode material already basic applied commercially of LIB including LCO, LMO, Ternary Lithium Oxide (mainly introduce NCM and NCA) and LFP, showing their structure, physical property, chemical property (mainly the ele
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8

Ouvrard, G., M. Zerrouki, C. Masquelier, M. Morcrette, S. Hamelet, and S. Belin. "Operandocharacterization of lithium battery electrode materials." Acta Crystallographica Section A Foundations of Crystallography 68, a1 (2012): s44. http://dx.doi.org/10.1107/s0108767312099151.

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9

Jamnik, Janez, and Joachim Maier. "Nanocrystallinity effects in lithium battery materials." Physical Chemistry Chemical Physics 5, no. 23 (2003): 5215. http://dx.doi.org/10.1039/b309130a.

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10

Liu, Kai, Yayuan Liu, Dingchang Lin, Allen Pei, and Yi Cui. "Materials for lithium-ion battery safety." Science Advances 4, no. 6 (2018): eaas9820. http://dx.doi.org/10.1126/sciadv.aas9820.

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11

Deng, Yilong, Haoze Wang, and Yiguo Zhang. "Different cathode materials for lithium-ion batteries." Highlights in Science, Engineering and Technology 83 (February 27, 2024): 248–52. http://dx.doi.org/10.54097/m3vv3549.

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Due to the increasing need for electronic products like smartphones and electric vehicles, lithium-ion battery research has long been a prominent field of study. Lithium-ion batteries are a growing battery technology that is widely used in industries such as power, electronic equipment, communication, civil aviation, and the military as an efficient, dependable, and long-lasting energy storage system. Lithium-ion batteries' cathode materials are an essential component, and how well they function has a significant impact on how well and how long the battery will survive. Based on their structur
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12

Zhou, Hong-Jie, Chun-Lei Song, Li-Ping Si, Xu-Jia Hong, and Yue-Peng Cai. "The Development of Catalyst Materials for the Advanced Lithium–Sulfur Battery." Catalysts 10, no. 6 (2020): 682. http://dx.doi.org/10.3390/catal10060682.

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The lithium–sulfur battery is considered as one of the most promising next-generation energy storage systems owing to its high theoretical capacity and energy density. However, the shuttle effect in lithium–sulfur battery leads to the problems of low sulfur utilization, poor cyclability, and rate capability, which has attracted the attention of a large number of researchers in the recent years. Among them, the catalysts with efficient catalytic function for lithium polysulfides (LPSs) can effectively inhibit the shuttle effect. This review outlines the progress of catalyst materials for lithiu
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13

Andreas Arie, Arenst, Shealyn Lenora, Hans Kristianto, Ratna Frida Susanti, and Joong Kee Lee. "Potato Peel Based Carbon–Sulfur Composite as Cathode Materials for Lithium Sulfur Battery." Journal of Nanoscience and Nanotechnology 21, no. 12 (2021): 6243–47. http://dx.doi.org/10.1166/jnn.2021.19288.

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Lithium sulfur battery has become one of the promising rechargeable battery systems to replace the conventional lithium ion battery. Commonly, it uses carbon–sulfur composites as cathode materials. Biomass based carbons has an important role in enhancing its electrochemical characteristics due to the high conductivity and porous structures. Here, potato peel wastes have been utilized to prepare porous carbon lithium sulfur battery through hydrothermal carbonization followed by the chemical activation method using KOH. After sulfur loading, as prepared carbon–sulfur composite shows stable coulo
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14

He, Yong Tai, Li Xian Xiao, Yue Hong Peng, and Jin Hao Liu. "Research on the Solid Thin Film Lithium-Ion Battery Integrated on-Chip." Advanced Materials Research 915-916 (April 2014): 1153–57. http://dx.doi.org/10.4028/www.scientific.net/amr.915-916.1153.

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the solid thin film lithium-ion battery integrated on chip was designed and analyzed based on solid lithium-ion battery structure, materials and microelectronics processing technology. The design model of the solid lithium-ion battery consists of Li negative electrode, Li3PO4 electrolyte and LiCoO2 positive electrode. The preparation process of the solid lithium-ion battery integrated on chip was researched, and the process consists of seven main steps. In addition, the characteristics of the design model of the solid lithium-ion battery were analyzed using COMSOL. The results show that the so
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15

Yusuf, A. S., A. M. Ramalan, M. Umar, and A. D. A. Buba. "Recent Progress in Lithium Ion Battery Technology." American Based Research Journal - ISSN (2304-7151) 10, no. 08 (2021): 01–18. https://doi.org/10.5281/zenodo.5341957.

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<em>This paper is aimed at giving a detailed review on the recent advancements in lithium ion battery technology focusing on the underlying principle; design and configuration; materials; fabrication techniques; application; and challenges of lithium ion batteries (LIBs). The first rechargeable Li-ion batteries with cathode of layered TiS2 and anode of metallic Li was reported by Whittingham while working at Exxon in 1976 but this invention was not successful due to the problems of Li dendrite formation and short circuit upon extensive cycling and safety concern. However, there was a turnaroun
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16

Sharma, Neeraj. "Time-resolved in situ neutron diffraction studies of Li-ion battery materials." Acta Crystallographica Section A Foundations and Advances 70, a1 (2014): C353. http://dx.doi.org/10.1107/s2053273314096466.

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Lithium-ion batteries are ubiquitous in society, used in everything from children's toys to mobile electronic devices, providing portable power solutions. There is a continuous drive for the improvement of these batteries to meet the demands of higher power devices and uses. A large proportion of the function of lithium-ion batteries arises from the electrodes, and these are in turn mediated by the atomic-scale perturbations or changes in the crystal structure during an electrochemical process (e.g. battery use). Therefore, a method to both understand battery function and propose ideas to impr
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17

Lv, Cheng Xue, Xi Kun Gai, Rui Qin Yang, Jian Zhong Wang, and Hui Zhong Jiang. "Study on Ge-Sn Metal Composite Powder as Lithium Ion Battery Anode Materials." Advanced Materials Research 953-954 (June 2014): 1082–86. http://dx.doi.org/10.4028/www.scientific.net/amr.953-954.1082.

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The Sn-Ge metal composite powder was obtained by reduction of the SnGeO3. The XRD and SEM analysis of Sn-Ge were completed. The simulation battery was prepared by using the Sn-Ge as lithium ion battery anode material, and its electrochemical properties were characterized. The results indicate that the SnGeO3 was reduced at 723K to generate the Sn-Ge composite powder instead of the alloy. The first embedding lithium capacity (discharge capacity) was 625 mAh·g-1, the first taking off lithium capacity (charge capacity) was 590 mAh·g-1 for the simulation battery. The capacity gradually decreased w
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18

Guigang Cheng. "Electrical Properties of Porous Nano Modified Lithium-ion Battery Negative Electrode Materials." Journal of Electrical Systems 20, no. 7s (2024): 1617–24. http://dx.doi.org/10.52783/jes.3739.

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The negative electrode material of lithium-ion batteries is one of the key factors affecting the overall performance of the battery. Traditional carbon/graphite materials are prone to safety issues such as capacity loss and metal precipitation during application. Due to its high conductivity and flexibility, as well as its excellent properties in battery energy density, cycle life, and other aspects, Ti3C2 nanomaterials have brought new opportunities for the lithium-ion batteries development. The development of convenient electronic products and power equipment has put forward higher requireme
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19

Ahmed, Sabbir, Anil Kumar Madikere Raghunatha Reddy, and Karim Zaghib. "Transformations of Critical Lithium Ores to Battery-Grade Materials: From Mine to Precursors." Batteries 10, no. 11 (2024): 379. http://dx.doi.org/10.3390/batteries10110379.

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The escalating demand for lithium has intensified the need to process critical lithium ores into battery-grade materials efficiently. This review paper overviews the transformation processes and cost of converting critical lithium ores, primarily spodumene and brine, into high-purity battery-grade precursors. We systematically examine the study findings on various approaches for lithium recovery from spodumene and brine. Dense media separation (DMS) and froth flotation are the most often used processes for spodumene beneficiation. Magnetic separation (MS) and ore gravity concentration techniqu
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20

Ahmed, Sabbir, Anil Kumar M R, and Karim Zaghib. "Transformations of Critical Lithium OREs to Battery-Grade Materials: From Mine to Precursors." ECS Meeting Abstracts MA2025-01, no. 3 (2025): 394. https://doi.org/10.1149/ma2025-013394mtgabs.

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The escalating demand for lithium has intensified the need to process critical lithium ores into battery-grade materials efficiently. This review paper overviews the transformation processes and cost of converting critical lithium ores, primarily spodumene and brine, into high-purity battery-grade precursors. We systematically examine the study findings on various approaches for lithium recovery from spodumene and brine. Dense media separation (DMS) and froth flotation are the most often used processes for spodumene beneficiation. Magnetic separation (MS) and ore gravity concentration techniqu
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21

Zhanabayeva, A. K., G. K. Bishimbayeva, D. S. Zhumabayeva, A. M. Nalibayeva, and Ye N. Abdikalykov. "A technology for producing electrode materials for lithium-ion batteries from Kazakhstan spodumene raw materials." Proceedings of Universities. Applied Chemistry and Biotechnology 12, no. 1 (2022): 141–52. http://dx.doi.org/10.21285/2227-2925-2022-12-1-141-152.

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This study aims to develop a technology for producing innovative electrode materials for modern lithium batteries. An efficient technology for post-purifying of technical lithium carbonate to reach the level of battery quality (99.95%) was developed. This technology involves causticiziation of technical lithium carbonate, ultrafiltration and ion-exchange sorption of a lithium hydroxide solution, followed by precipitation of lithium carbonate with ammonium carbonate. Cation-exchange resins of the brands Purolite S930Plus, Purolite S940 and Purolite S950 were studied for sorption purification of
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22

Qiu, Lei, Zi Qiang Shao, Ming Long Liu, and Yan Hua Liu. "Electrospinning Carboxymethyl Cellulose Lithium (CMC-Li) Nano Composite Material for High-Rate Lithium-Ion Battery." Advanced Materials Research 924 (April 2014): 69–72. http://dx.doi.org/10.4028/www.scientific.net/amr.924.69.

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New cellulose derivative CMC-Li was synthesized, and nanometer fiber composite material was applied to lithium-ion battery and coated with AQ by electrospinning. Under the protection of inert gas, modified AQ/ carbon nanofibers (CNF) /Li nanometer composite material was obtained by carbonization in 280OC as lithium battery anode materials for the first time. The morphologies and structure performance of materials were characterized by using IR, SEM, CV and EIS, respectively. Specific capacity was increased to226.4 mAh.g-1after modification for the first discharge at the rate of 2C. Performance
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23

Naseer, Saima, Usman Aziz, Asnad khan, et al. "Advancing Energy Storage: Carbon Nanotubes as Catalysts in Battery Innovation and Materials Science." Scholars Academic Journal of Biosciences 13, no. 04 (2025): 445–50. https://doi.org/10.36347/sajb.2025.v13i04.009.

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Carbon-based nanomaterials, particularly carbon nanotubes (CNTs), have gained significant attention in energy storage applications due to their excellent mechanical, electrical, and thermal properties. CNTs function as elemental components for lithium-ion, lithium-sulfur and lithium-air batteries since they boost charge flow and strengthen electrodes and elevate battery performance rates. The electrical conductivity of modified electrodes rises by 30% and their charge-discharge cycle stability improves by 20% based on experimental findings compared to typical electrode materials. Lithium-sulfu
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24

Gu, Jiadong, and Funa Yang. "Application of cathode materials in lithium ion phosphate battery and its modification." Journal of Physics: Conference Series 2798, no. 1 (2024): 012050. http://dx.doi.org/10.1088/1742-6596/2798/1/012050.

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Abstract Lithium ion batteries have been widely used in various fields, such as electric vehicles, due to their excellent electrochemical performance. Especially, introducing some functional materials into batteries can further improve battery performance. This research analyses the application of lithium-ion phosphate as the cathode materials of the batteries, with a particular focus on the structural characteristics and various indices of the modification of lithium iron phosphate battery cathode materials. The electrode material is systematically described, highlighting its advantages, disa
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25

Kirwa, Cyrus Kibichi, Jaclyn Coyle, and Hongmei Luo. "Direct Recycling of End-of-Life Li-Ion Cathode Materials through Redox Chemistry Mediators." ECS Meeting Abstracts MA2022-02, no. 26 (2022): 1029. http://dx.doi.org/10.1149/ma2022-02261029mtgabs.

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Recycled lithium-ion (Li-Ion) battery materials are pivotal for the sustainability of the renewable energy industry. Widespread consumer and municipal adoption of electric vehicles (EVs) directly correlates to the increased demand for Li-Ion batteries. Increasing Li-Ion battery production to meet the demand presents two challenges: end-of-life (EoL) Li-Ion management through recycling and mineral depletion. Li-Ion batteries are manufactured with hazardous and volatile materials, hence, cannot be sent to landfills. Therefore, recycling is vital in preserving the environment and securing resourc
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26

Shi, Jiayuan, and Bin Shi. "Environment-Friendly Design of Lithium Batteries Starting from Biopolymer-Based Electrolyte." Nano 16, no. 05 (2021): 2130006. http://dx.doi.org/10.1142/s1793292021300061.

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The nondegradable nature and toxicity of organic liquid electrolytes reveal the design deficiency of lithium batteries in environmental protection. Biopolymers can be extracted from biomass under mild conditions, thus they are usually low cost and renewable. The unique characteristics of biopolymers such as water solubility, film-forming capability and adhesive property are of importance for lithium battery. The studies on the biopolymer materials for lithium batteries have been reviewed in this work. Although a lot of work on the biopolymer-based battery materials has been reported, it is sti
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27

Kaya, Elif, and Alessandro d’Adamo. "Numerical Modelling of 1d Isothermal Lithium-Ion Battery with Varied Electrolyte and Electrode Materials." Energies 18, no. 13 (2025): 3288. https://doi.org/10.3390/en18133288.

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In this study, the lithium-ion (Li-ion) battery type, which has a high-power density and utilizes lithium as the primary conductive terminal, has been employed. Within the scope of this research, a one-dimensional isothermal Li-ion battery model has been investigated under various electrolyte (both liquid and solid) and electrode materials using the COMSOL Multiphysics software. The obtained simulation results have been corroborated with information sourced from the literature and establish a foundational framework for future studies. The average range of electrolyte salt concentration in batt
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28

Grey, Clare P., and Steve G. Greenbaum. "Nuclear Magnetic Resonance Studies of Lithium-Ion Battery Materials." MRS Bulletin 27, no. 8 (2002): 613–18. http://dx.doi.org/10.1557/mrs2002.197.

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AbstractSolid-state nuclear magnetic resonance (NMR) spectroscopy has been employed to characterize a variety of phenomena that are central to the functioning of lithium and lithium-ion batteries. These include Li insertion and de-insertion mechanisms in carbonaceous and other anode materials and in transition-metal oxide cathodes, and ion-transport mechanisms in polymer and gel electrolytes. Investigations carried out over the last several years by the authors and other groups are reviewed in this article. Results for lithium manganese oxide spinel cathodes, carbon-based and SnO anodes, and p
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29

Yoshino, Akira. "Next Generation Lithium Battery and Polymer Materials." Seikei-Kakou 22, no. 6 (2010): 274–78. http://dx.doi.org/10.4325/seikeikakou.22.274.

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30

Wan, Jianfeng, Jianan Lyu, Wenyan Bi, et al. "Regeneration of spent lithium-ion battery materials." Journal of Energy Storage 51 (July 2022): 104470. http://dx.doi.org/10.1016/j.est.2022.104470.

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31

Park, Hye-Jin, Seong-Ju Sim, Bong-Soo Jin, and Hyun-Soo Kim. "LiFePO4 Cathode Materials for Lithium Secondary Battery." Journal of the Korean Battery Society 1, no. 2 (2021): 118–31. http://dx.doi.org/10.53619/kobs.2021.12.1.2.118.

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32

Jung, W. I., M. Nagao, A. Ochiai, A. Yamada, and R. Kanno. "Structures of Li2MnO3for lithium battery electrode materials." Acta Crystallographica Section A Foundations of Crystallography 64, a1 (2008): C473. http://dx.doi.org/10.1107/s0108767308084808.

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33

Scrosati, Bruno. "Recent advances in lithium ion battery materials." Electrochimica Acta 45, no. 15-16 (2000): 2461–66. http://dx.doi.org/10.1016/s0013-4686(00)00333-9.

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34

Yang, Guang, Xinghua Xie, Xiangdong Meng, Weiguo Wang, and Jiahua Yang. "Active electrode materials for lithium-ion battery." Ferroelectrics 607, no. 1 (2023): 96–105. http://dx.doi.org/10.1080/00150193.2023.2198376.

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35

Mori, Ryohei. "Separator Materials for Lithium Sulfur Battery—A Review." Electrochem 4, no. 4 (2023): 485–522. http://dx.doi.org/10.3390/electrochem4040032.

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In the recent rechargeable battery industry, lithium sulfur batteries (LSBs) have demonstrated to be a promising candidate battery to serve as the next-generation secondary battery, owing to its enhanced theoretical specific energy, economy, and environmental friendliness. Its inferior cyclability, however, which is primarily due to electrode deterioration caused by the lithium polysulfide shuttle effect, is still a major problem for the real industrial usage of LSBs. The optimization of the separator and functional barrier layer is an effective strategy for remedying these issues. In this art
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36

Tao, Haisheng, Zhizhong Feng, Hao Liu, Xianwen Kan, and P. Chen. "Reality and Future of Rechargeable Lithium Batteries." Open Materials Science Journal 5, no. 1 (2011): 204–14. http://dx.doi.org/10.2174/1874088x01105010204.

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Compared to other types of rechargeable batteries, the rechargeable lithium battery has many advantages, such as: higher energy density, lower self-discharge rate, higher voltages and longer cycle life. This article provides an overview of the cathode, anode, electrolyte and separator materials used in rechargeable lithium batteries. The advantages and challenges of various materials used in rechargeable lithium batteries will be discussed, followed by a highlight of developing trends in lithium battery research.
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37

Li, Yi Xia, Rui Lian Guo, Yan Qin Zhang, and Da Sen Zhou. "Study on Reuse of Power Lithium Ion Battery Recycling." Advanced Materials Research 937 (May 2014): 515–19. http://dx.doi.org/10.4028/www.scientific.net/amr.937.515.

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This paper takes the waste lithium ion battery materials, lithium, cobalt metal recovery of cathode materials, the anode sheet and method makes the volatile burning binder, water brush technique separates powder materials and aluminum foil; then with sulfuric acid and hydrogen peroxide system makes lithium, cobalt black slag with ion dissolving status the leaching liquid obtained by precipitation, cobalt and lithium carbonate products.
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38

Chen, Tianrui. "Investigation of 2D material anodes with different anions for lithium ion batteries: comparison of MoO2, MoS2 and MoSe2." Journal of Physics: Conference Series 2331, no. 1 (2022): 012005. http://dx.doi.org/10.1088/1742-6596/2331/1/012005.

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Abstract The energy storage devices used in today’s society are mainly lithium batteries. At present, the anode material of commercial lithium batteries is generally graphite. Although lithium battery has superior performance compared with other energy storage methods, it still has many problems, such as poor safety, low specific capacity, and slow charging speed. In recent years, although some researchers have proposed graphene as anode material, the results show that although graphene can partly alleviate the above problems, it cannot meet the needs of industrial and domestic applications. T
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39

Li, Tonglin. "Application of sulfur-based composite materials in the positive electrode of lithium-sulfur batteries." E3S Web of Conferences 553 (2024): 01013. http://dx.doi.org/10.1051/e3sconf/202455301013.

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Traditional lithium-ion batteries are no longer able to keep up with the growing need for energy storage efficiency in areas like electric cars and renewable energy storage. Because of their great energy density, affordability, and environmental friendliness, lithium-sulfur batteries are regarded as a very promising solution for secondary battery systems. Sulfur-based compounds are an essential part of lithium-sulfur batteries and have a direct impact on the battery’s energy density and performance. However, sulfur-based compounds are easily soluble in electrolytes and have low conductivity, w
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40

He, Hao, Jingjing Huang, Jiarui Wang, and Xin Xu. "Research status and prospect of electrode materials for lithium-ion battery." Applied and Computational Engineering 23, no. 1 (2023): 1–9. http://dx.doi.org/10.54254/2755-2721/23/20230601.

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The lithium-ion battery has become one of the most widely used green energy sources, and the materials used in its electrodes have become a research hotspot. There are many different types of electrode materials, and negative electrode materials have developed to a higher level of perfection and maturity than positive electrode materials. Enhancing the electrochemical capabilities of positive electrode materials is therefore crucial. In addition to exploring and choosing the preparation or modification methods of various materials, this study describes the positive and negative electrode mater
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41

Qin, Haonan. "The Impact of Nanotechnology on Lithium-Ion Battery Used in Electric Vehicles." Highlights in Science, Engineering and Technology 43 (April 14, 2023): 563–68. http://dx.doi.org/10.54097/hset.v43i.7477.

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The global environment has already been polluted by the traditional fuel vehicles and become more and more serious. In this situation, the electric vehicles (EVs) came to the attention of the worldwide people. In recent years, the electric vehicles have developed rapidly. As a result, the components of the electric vehicles were logically achieved great success, particularly the rechargeable lithium-ion battery. Fortunately, the nanotechnology, at the same time, made a great deal of huge achievements and appeared in numerous fields. Nanotechnology obviously plays a critical role in the field o
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42

Bazarbay, Tanirbergenov, Alauatdinova Ainagul Inyatdinovna, and Niyetova Aliya Polatovna. "Use of Inorganic Materials as Energy Storage: New Electrode Materials in Lithium-Ion Batteries." American Journal of Applied Science and Technology 5, no. 6 (2025): 80–82. https://doi.org/10.37547/ajast/volume05issue06-17.

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The rapid advancement of lithium-ion battery (LIB) technology demands the development of new electrode materials to improve energy density, safety, and longevity. Inorganic materials, including transition metal oxides, silicon-based alloys, and olivine phosphates, have shown great potential as next-generation electrode candidates due to their superior electrochemical properties and structural stability. This article reviews recent progress in inorganic electrode materials, emphasizing their advantages, challenges such as volume expansion and conductivity issues, and strategies like nanostructu
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Xu, Shenzhen, Ryan M. Jacobs, Ha M. Nguyen, et al. "Lithium transport through lithium-ion battery cathode coatings." Journal of Materials Chemistry A 3, no. 33 (2015): 17248–72. http://dx.doi.org/10.1039/c5ta01664a.

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He, Hao. "Research status and prospect of electrode materials for lithium-ion battery." Applied and Computational Engineering 23, no. 7 (2023): 1–9. http://dx.doi.org/10.54254/2755-2721/23/ojs/20230601.

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&#x0D; The lithium-ion battery has become one of the most widely used green energy sources, and the materials used in its electrodes have become a research hotspot. There are many different types of electrode materials, and negative electrode materials have developed to a higher level of perfection and maturity than positive electrode materials. Enhancing the electrochemical capabilities of positive electrode materials is therefore crucial. In addition to exploring and choosing the preparation or modification methods of various materials, this study describes the positive and negative electrod
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Rana, Kuldeep, Anjan Sil, and Subrata Ray. "Ball-Milled Graphite-Tin Composite Anode Materials for Lithium-Ion Battery." Materials Science Forum 736 (December 2012): 127–32. http://dx.doi.org/10.4028/www.scientific.net/msf.736.127.

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Lithium alloying compounds as an anode materials have been a focused for high capacity lithium ion battery due to their highenergy capacity and safety characteristics. Here we report on the preparation of graphite-tin composite by using ball-milling in liquid media. The composite material has been characterized by scanning electron microscope, energy depressive X-ray spectroscopy, X-ray diffraction and Raman spectra. The lithium-ion cell made from graphite-tin composite presented initial discharge capacity of 1065 mAh/g and charge capacity 538 mAh/g, which becomes 528 mAh/g in the second cycle
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46

Pu, Changsheng. "Highly Ordered Silicon/Carbon Composite Materials Based on Biomass and Their Application in Lithium Batteries." Non-Metallic Material Science 6, no. 1 (2024): 1–6. http://dx.doi.org/10.30564/nmms.v6i1.6387.

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With the rapid development of electric vehicles and mobile devices, the performance and safety of energy storage and conversion devices mainly with lithium-ion batteries have been paid attention to. Negative electrode material is an important component of lithium-ion battery, which has an important influence on the overall performance of the battery. In recent years, the research of highly ordered silicon / carbon composites as the negative electrode has been significantly developed. Highly ordered silicon / carbon composites have great potential to increase the energy density of lithium-ion b
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He, Jinya. "Classification and Application Research of Lithium Electronic Batteries." MATEC Web of Conferences 386 (2023): 03008. http://dx.doi.org/10.1051/matecconf/202338603008.

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In recent years, the damaging effects of burning fossil fuels on the environment and petrol has started to decline, the demand for sustainable energy has risen sharply, and lithium electronic batteries have become a hot spot today due to their high specific capacity, high self-discharge rate, long life and high safety performance. Since lithium metal is an active metal, its preparation and preservation have high requirements on the environment. This paper discusses the development history, working principle, classification and practical application of lithium electronic batteries in real life.
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Hosono, Eiji, Hirofumi Matsuda, Masashi Okubo, et al. "Development of Positive Electrode Materials for the High Rate Lithium Ion Battery by Nanostructure Control." Key Engineering Materials 445 (July 2010): 109–12. http://dx.doi.org/10.4028/www.scientific.net/kem.445.109.

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Previously, we reported the fabrication of Na0.44MnO2 and LiMn2O4 single crystalline nanowire structure. Moreover, these electrodes showed good high rate property as lithium ion battery, because the nanostructure electrode is suitable for high rate lithium ion battery. Especially, the fabrication of LiMn2O4 single crystalline nanowire was very interesting results because the synthesis of 1-dimesional single crystal structure of LiMn2O4 is very difficult based on cubic crystal structure without anisotropic structure. The LiMn2O4 single crystalline nanowire was obtained thorough the self templat
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Qiu, Tian A., Valeria Guidolin, Khoi Nguyen L. Hoang, et al. "Nanoscale battery cathode materials induce DNA damage in bacteria." Chemical Science 11, no. 41 (2020): 11244–58. http://dx.doi.org/10.1039/d0sc02987d.

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The increasing use of nanoscale lithium nickel manganese cobalt oxide (LixNiyMnzCo<sub>1−y−z</sub>O<sub>2</sub>, NMC) as a cathode material in lithium-ion batteries poses risk to the environment. We report DNA damage that occurs in bacteria after nano-NMC exposure with rich chemical details.
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Li, Zihao. "Research Status of Lithium-ion battery anode materials." Applied and Computational Engineering 127, no. 1 (2025): 154–61. https://doi.org/10.54254/2755-2721/2025.20265.

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This article presents a summary of recent developments in the field of lithium-ion battery anode materials. It first emphasises the pivotal role that anode materials play in determining the total efficiency of lithium-ion batteries. Furthermore, the article examines the diverse range of anode materials and highlights the distinct performance characteristics of each in real-world applications. Additionally, it synthesizes and assesses the pivotal research constraints and challenges that have emerged during the development process. Finally, it presents recommendations for future research directi
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