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145 results on '"Wu, Langyuan"'

10. Direct Epitaxial Growth of Polycrystalline MOF Membranes on Cu Foils for Uniform Li Deposition in Long‐life Anode‐free Li Metal Batteries.

Author

Wu, Haiyang, Wu, Langyuan, Li, Yang, Dong, Wendi, Ma, Wenyu, Li, Shaopeng, Xiao, Dewei, Huang, Peng, and Zhang, Xiaogang

Subjects
*COPPER, *EPITAXY, *ENERGY storage, *NUCLEATION, *OVERPOTENTIAL, *ELECTRIC batteries
Abstract

Anode‐free Li‐metal battery (AFLMB) is being developed as the next generation of advanced energy storage devices. However, the low plating and stripping reversibility of Li on Cu foil prevents its widespread application. A promising avenue for further improvement is to enhance the lithophilicity of Cu foils and optimise their surfaces through a metal–organic framework (MOF) functional layer. However, excessive binder usage in the current approaches obscures the active plane of the MOF, severely limiting its performance. In response to this challenge, MOF polycrystalline membrane technology has been integrated into the field of AFLMB in this work. The dense and seamless HKUST‐1 polycrystalline membrane was deposited on Cu foil (HKUST‐1 M@Cu) via an epitaxial growth strategy. In contrast to traditional MOF functional layers, this binder‐free polycrystalline membrane fully exposes lithophilic sites, effectively reducing the nucleation overpotential and optimising the deposition quality of Li. Consequently, the Li plating layer becomes denser, eliminating the effects of dendrites. When coupled with LiFePO4 cathodes, the battery based on the HKUST‐1 membrane exhibits excellent rate performance and cycling stability, achieving a high reversible capacity of approximately 160 mAh g−1 and maintaining a capacity retention of 80.9 % after 1100 cycles. [ABSTRACT FROM AUTHOR]

Published
2024
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14. Improving the electrochemical performance of an anionic redox P3-type layered oxide cathode by the synergistic effect by sodium metaborate coating and boron doping.

Author

Ling, Zhenxiao, Wu, Langyuan, Xiang, Yuxuan, Dong, Wendi, Qin, Lunjie, Qi, Xiaodong, Hu, Chaogen, and Zhang, Xiaogang

Abstract

The lattice oxygen redox (LOR) reaction, known for its potential to augment the capacity of layered transition metal oxides in sodium-ion batteries (SIBs), has attracted widespread attention. However, the utilization of the LOR reaction often leads to irreversible release of lattice oxygen, causing damage to the crystal structure and deterioration in electrochemical performance, thereby impeding its practical application. Here, we demonstrate a method to significantly enhance the electrochemical performance of P3-type Na0.6Li0.2Mn0.8O2 cathodes by concurrently applying surface NaBO2 coatings and boron doping. We reveal that the NaBO2 coating efficiently mitigates electrolyte corrosion and side reactions on the electrode surface. In addition, boron doping enhances the involvement of manganese in the redox process, thereby boosting capacity, while inhibiting the irreversible Li migration, thereby stabilizing the crystal structure of the material. The synergistic effect of surface NaBO2 coating and bulk phase boron doping enables 6%B-NLMO to exhibit improved electrochemical performance, achieving a discharge capacity of 98.7 mA h g−1 and 95.8% retention after 100 cycles at 20 mA g−1. This synergistic strategy, employing multiple modification techniques, offers a potential way to improve the performance of anion redox cathode materials. [ABSTRACT FROM AUTHOR]

Published
2024
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15. Engineering Robust Battery Interphases with Dilute Fluorinated Cations

Author

Hong, Chulgi Nathan, primary, Yan, Mengwen, additional, Borodin, Oleg, additional, Pollard, Travis P., additional, Wu, Langyuan, additional, Reiter, Manuel, additional, Vazquez, Dario Gomez, additional, Trapp, Katharina, additional, Yoo, Jimun, additional, Shpigel, Netanel, additional, Feldblyum, Jeremy I., additional, and Lukatskaya, Maria R., additional

Published
2024
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17. To what extent do anions affect the electrodeposition of Zn?

Author

Bergman, Gil, primary, Spanier, Netta, additional, Blumen, Omer, additional, Levy, Noam, additional, Harpaz, Sara, additional, Malchik, Fyodor, additional, Wu, Langyuan, additional, Sonoo, Masato, additional, Chae, Munseok S., additional, Wang, Guoxiu, additional, Mandler, Daniel, additional, Aurbach, Doron, additional, Zhang, Yong, additional, Shpigel, Netanel, additional, and Sharon, Daniel, additional

Published
2024
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28. Prolonging the Cycle Stability of Anion Redox P3-Type Na0.6Li0.2Mn0.8O2through Al2O3Atomic Layer Deposition Surface Modification

Author

Ling, Zhenxiao, Wu, Langyuan, Hu, Chaogen, Qi, Xiaodong, Qin, Lunjie, Pan, Jiaqi, and Zhang, Xiaogang

Abstract

Sodium-ion batteries (SIBs) are becoming an alternative option for large-scale energy storage systems owing to their low cost and abundance. The lattice oxygen redox (LOR), which has the potential to increase the reversible capacity of materials, has promoted the development of high-energy cathode materials in SIBs. However, the utilization of oxygen anion redox reactions usually results in harmful lattice oxygen release, which hastens structural deformation and declines electrochemical performance, severely hindering their practical application. Herein, a ribbon-ordered superstructured P3-type Na0.6Li0.2Mn0.8O2(NLMO) cathode with a uniform Al2O3coating through atomic layer deposition (ALD) was synthesized. The cycling stability and rate capability of the materials were improved by a proper thickness of the Al2O3layer. Differential electrochemical mass spectrometry (DEMS) results clearly suggest that the Al2O3coating can inhibit the CO2release caused by the highly active surface of the NLMO material. Moreover, the results of transmission electron microscopy (TEM) and etching X-ray photoelectron spectroscopy (XPS) show that the Al2O3coating can effectively prevent electrolyte and electrode side reactions and the dissolution of Mn. This surface engineering strategy sheds light on the way to prolong the cycling stability of anionic redox cathode materials.

Published
2024
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34. Rational design of covalent organic frameworks with high capacity and stability as a lithium-ion battery cathode.

Author

Luo, Derong, Zhang, Jing, Zhao, Huizi, Xu, Hai, Dong, Xiaoyu, Wu, Langyuan, Ding, Bing, Dou, Hui, and Zhang, Xiaogang

Subjects
LITHIUM-ion batteries, SUPERCAPACITOR electrodes, CATHODES, DENSITY functional theory
Abstract

A two-dimensional covalent organic framework (NTCDI-COF) with rich redox active sites, high stability and crystallinity was designed and prepared. As a cathode material for lithium-ion batteries (LIBs), NTCDI-COF exhibits excellent electrochemical performance with an outstanding discharge capacity of 210 mA h g−1 at 0.1 A g−1 and high capacity retention of 125 mA h g−1 after 1500 cycles at 2 A g−1. A two-step Li+ insertion/extraction mechanism is proposed based on the ex situ characterization and density functional theory calculation. The constructed NTCDI-COF//graphite full cells can realize a good electrochemical performance. [ABSTRACT FROM AUTHOR]

Published
2023
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38. Revealing the multiple cathodic and anodic involved charge storage mechanism in an FeSe2 cathode for aluminium-ion batteries by in situ magnetometry

Author

Wang, Huaizhi, primary, Zhao, Linyi, additional, Zhang, Hao, additional, Liu, Yongshuai, additional, Yang, Li, additional, Li, Fei, additional, Liu, Wenhao, additional, Dong, Xiaotong, additional, Li, Xiangkun, additional, Li, Zhaohui, additional, Qi, Xiaodong, additional, Wu, Langyuan, additional, Xu, Yunfei, additional, Wang, Yaqun, additional, Wang, Kuikui, additional, Yang, Huicong, additional, Li, Qiang, additional, Yan, Shishen, additional, Zhang, Xiaogang, additional, Li, Feng, additional, and Li, Hongsen, additional

Published
2022
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40. Lithium‐Ion Thermal Charging Cell with Giant Thermopower for Low‐Grade Heat Harvesting.

Author

Xu, Yinghong, Li, Zhiwei, Wu, Langyuan, Dou, Hui, and Zhang, Xiaogang

Subjects
THERMAL batteries, THERMOELECTRIC power, HARVESTING, ENERGY harvesting, LITHIUM cells, ELECTRIC charge, TRIBOELECTRICITY
Abstract

Liquid‐based thermoelectric cells integrate energy harvesting and storage technology, becoming the focus of energy fields. However, the simultaneous implement of high output voltage and heat‐to‐electricity efficiency is still challenging. Herein, we propose a lithium‐ion thermal charging cell using lithium anode and electrospun zinc vanadate@carbon nanofiber cathode. Benefitting from the superior performance of electrode and the significant difference between the size of cation and anion in electrolyte, such system can continuously realize the harvesting and conversion of low‐grade heat into electricity. Consequently, an open‐circuit voltage of about 2.1 V can be generated at a low temperature gradient of 25 K together with an ultrahigh thermopower of 47.9 mV K−1 and a remarkable power density of 9.2 W m−2. Moreover, an impressive Carnot‐related efficiency (5.2 %) can be achieved under same conditions. This work confirms the superiority of organic thermoelectric system and provides a new insight to develop promising thermal charging cell for sustainable applications. [ABSTRACT FROM AUTHOR]

Published
2023
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