Your search keyword '"Xia Yonggao"' showing total 29 results

1. In Situ Formation of a LiBO2 Coating Layer and Spinel Phase for Ni-Rich Cathode Materials from a Boric Acid-Etched Precursor

Author

Guo, Ziyin, Shi, Xiaotang, Cao, Longhao, Zhang, Jing, Zhang, Xiaosong, Yao, Jiang, Cheng, Ya-Jun, Xia, Yonggao, Guo, Ziyin, Shi, Xiaotang, Cao, Longhao, Zhang, Jing, Zhang, Xiaosong, Yao, Jiang, Cheng, Ya-Jun, and Xia, Yonggao

Abstract

Ni-rich cathode materials exhibit superior energy densities and have attracted interest among both research and industrial fields; whereas, their practical application is hindered by the intrinsic drawbacks brought by the high nickel content such as structural instability and rapid capacity fading. Herein, in situ formation of a LiBO2 coating layer and spinel phase layer is achieved on the surface of a Ni-rich cathode material via a boric acid etching method at the precursor state. The spinel phase is considered to have a 3D lithium diffusion tunnel and hence faster diffusion kinetics. Moreover, the LiBO2 layer possesses excellent (electro)-chemical inertness and can suppress electrolyte decomposition, resulting in a more inorganic and stable cathode-electrolyte interface. The surface reconstructed sample exhibits better cyclic stability (93.3% capacity retention vs 85.3% for the pristine sample at 1 C for 100 cycles) and rate performance. The superiority of this surface reconstruction is demonstrated by a series of electrochemical techniques and characterization methods including high-angle annular dark-field scanning transmission electron microscopy (HAADF-STEM), post-mortem X-ray photoelectron spectroscopy (XPS) analysis, and density functional theory (DFT) calculations.

Published

2024

2. Bronze-Phase TiO2 as Anode Materials in Lithium and Sodium-Ion Batteries

Author

Liang, Suzhe, Wang, Xiaoyan, Qi, Ruoxuan, Cheng, Ya-Jun, Xia, Yonggao, Mueller-Buschbaum, Peter, Hu, Xile, Liang, Suzhe, Wang, Xiaoyan, Qi, Ruoxuan, Cheng, Ya-Jun, Xia, Yonggao, Mueller-Buschbaum, Peter, and Hu, Xile

Abstract

Titanium dioxide of bronze phase (TiO2(B)) has attracted considerable attention as a promising alternative lithium/sodium-ion battery anode due to its excellent operation safety, good reversible capacity, and environmental friendliness. However, several intrinsic critical drawbacks, including moderate electrochemical kinetics and unsatisfactory long cyclic stability, significantly limit its practical applications. It is crucial to develop reliable strategies to resolve these issues to advance the TiO2(B) based materials into practical applications in lithium/sodium-ion batteries. In this review, both the theoretical and experimental investigations on the TiO2(B) based materials over the last few decades are chronically elaborated. Insights on the general and detailed evolution trends of the research on TiO2(B) anodes are provided. The review also points to future directions for the TiO2(B) anode research to advance the practical application of TiO2(B) anodes.

Published

2022

3. Bronze-Phase TiO2 as Anode Materials in Lithium and Sodium-Ion Batteries

Author

Liang, Suzhe, Wang, Xiaoyan, Qi, Ruoxuan, Cheng, Ya-Jun, Xia, Yonggao, Mueller-Buschbaum, Peter, Hu, Xile, Liang, Suzhe, Wang, Xiaoyan, Qi, Ruoxuan, Cheng, Ya-Jun, Xia, Yonggao, Mueller-Buschbaum, Peter, and Hu, Xile

Abstract

Titanium dioxide of bronze phase (TiO2(B)) has attracted considerable attention as a promising alternative lithium/sodium-ion battery anode due to its excellent operation safety, good reversible capacity, and environmental friendliness. However, several intrinsic critical drawbacks, including moderate electrochemical kinetics and unsatisfactory long cyclic stability, significantly limit its practical applications. It is crucial to develop reliable strategies to resolve these issues to advance the TiO2(B) based materials into practical applications in lithium/sodium-ion batteries. In this review, both the theoretical and experimental investigations on the TiO2(B) based materials over the last few decades are chronically elaborated. Insights on the general and detailed evolution trends of the research on TiO2(B) anodes are provided. The review also points to future directions for the TiO2(B) anode research to advance the practical application of TiO2(B) anodes.

Published

2022

4. Identifying the chemical and structural irreversibility in LiNi0.8Co0.15Al0.05O2 - a model compound for classical layered intercalation

Author

Liu, Haodong, Liu, Haodong, Liu, Hao, Seymour, Ieuan D, Chernova, Natasha, Wiaderek, Kamila M, Trease, Nicole M, Hy, Sunny, Chen, Yan, An, Ke, Zhang, Minghao, Borkiewicz, Olaf J, Lapidus, Saul H, Qiu, Bao, Xia, Yonggao, Liu, Zhaoping, Chupas, Peter J, Chapman, Karena W, Whittingham, M Stanley, Grey, Clare P, Meng, Ying Shirley, Liu, Haodong, Liu, Haodong, Liu, Hao, Seymour, Ieuan D, Chernova, Natasha, Wiaderek, Kamila M, Trease, Nicole M, Hy, Sunny, Chen, Yan, An, Ke, Zhang, Minghao, Borkiewicz, Olaf J, Lapidus, Saul H, Qiu, Bao, Xia, Yonggao, Liu, Zhaoping, Chupas, Peter J, Chapman, Karena W, Whittingham, M Stanley, Grey, Clare P, and Meng, Ying Shirley

Abstract

Anisotropic disorder along the c-axis results from static disorder.

Published

2018

5. Identifying the chemical and structural irreversibility in LiNi0.8Co0.15Al0.05O2 - a model compound for classical layered intercalation

Author

Liu, Haodong, Liu, Haodong, Liu, Hao, Seymour, Ieuan D, Chernova, Natasha, Wiaderek, Kamila M, Trease, Nicole M, Hy, Sunny, Chen, Yan, An, Ke, Zhang, Minghao, Borkiewicz, Olaf J, Lapidus, Saul H, Qiu, Bao, Xia, Yonggao, Liu, Zhaoping, Chupas, Peter J, Chapman, Karena W, Whittingham, M Stanley, Grey, Clare P, Meng, Ying Shirley, Liu, Haodong, Liu, Haodong, Liu, Hao, Seymour, Ieuan D, Chernova, Natasha, Wiaderek, Kamila M, Trease, Nicole M, Hy, Sunny, Chen, Yan, An, Ke, Zhang, Minghao, Borkiewicz, Olaf J, Lapidus, Saul H, Qiu, Bao, Xia, Yonggao, Liu, Zhaoping, Chupas, Peter J, Chapman, Karena W, Whittingham, M Stanley, Grey, Clare P, and Meng, Ying Shirley

Abstract

Anisotropic disorder along the c-axis results from static disorder.

Published

2018

6. Understanding and Controlling Anionic Electrochemical Activity in High-Capacity Oxides for Next Generation Li-Ion Batteries

Author

Qiu, Bao, Qiu, Bao, Zhang, Minghao, Xia, Yonggao, Liu, Zhaoping, Meng, Ying Shirley, Qiu, Bao, Qiu, Bao, Zhang, Minghao, Xia, Yonggao, Liu, Zhaoping, and Meng, Ying Shirley

Published

2017

7. Understanding and Controlling Anionic Electrochemical Activity in High-Capacity Oxides for Next Generation Li-Ion Batteries

Author

Qiu, Bao, Qiu, Bao, Zhang, Minghao, Xia, Yonggao, Liu, Zhaoping, Meng, Ying Shirley, Qiu, Bao, Qiu, Bao, Zhang, Minghao, Xia, Yonggao, Liu, Zhaoping, and Meng, Ying Shirley

Published

2017

8. Gas-solid interfacial modification of oxygen activity in layered oxide cathodes for lithium-ion batteries.

Author

Qiu, Bao, Qiu, Bao, Zhang, Minghao, Wu, Lijun, Wang, Jun, Xia, Yonggao, Qian, Danna, Liu, Haodong, Hy, Sunny, Chen, Yan, An, Ke, Zhu, Yimei, Liu, Zhaoping, Meng, Ying Shirley, Qiu, Bao, Qiu, Bao, Zhang, Minghao, Wu, Lijun, Wang, Jun, Xia, Yonggao, Qian, Danna, Liu, Haodong, Hy, Sunny, Chen, Yan, An, Ke, Zhu, Yimei, Liu, Zhaoping, and Meng, Ying Shirley

Abstract

Lattice oxygen can play an intriguing role in electrochemical processes, not only maintaining structural stability, but also influencing electron and ion transport properties in high-capacity oxide cathode materials for Li-ion batteries. Here, we report the design of a gas-solid interface reaction to achieve delicate control of oxygen activity through uniformly creating oxygen vacancies without affecting structural integrity of Li-rich layered oxides. Theoretical calculations and experimental characterizations demonstrate that oxygen vacancies provide a favourable ionic diffusion environment in the bulk and significantly suppress gas release from the surface. The target material is achievable in delivering a discharge capacity as high as 301 mAh g(-1) with initial Coulombic efficiency of 93.2%. After 100 cycles, a reversible capacity of 300 mAh g(-1) still remains without any obvious decay in voltage. This study sheds light on the comprehensive design and control of oxygen activity in transition-metal-oxide systems for next-generation Li-ion batteries.

Published

2016

9. Gas-solid interfacial modification of oxygen activity in layered oxide cathodes for lithium-ion batteries.

Author

Qiu, Bao, Qiu, Bao, Zhang, Minghao, Wu, Lijun, Wang, Jun, Xia, Yonggao, Qian, Danna, Liu, Haodong, Hy, Sunny, Chen, Yan, An, Ke, Zhu, Yimei, Liu, Zhaoping, Meng, Ying Shirley, Qiu, Bao, Qiu, Bao, Zhang, Minghao, Wu, Lijun, Wang, Jun, Xia, Yonggao, Qian, Danna, Liu, Haodong, Hy, Sunny, Chen, Yan, An, Ke, Zhu, Yimei, Liu, Zhaoping, and Meng, Ying Shirley

Abstract

Lattice oxygen can play an intriguing role in electrochemical processes, not only maintaining structural stability, but also influencing electron and ion transport properties in high-capacity oxide cathode materials for Li-ion batteries. Here, we report the design of a gas-solid interface reaction to achieve delicate control of oxygen activity through uniformly creating oxygen vacancies without affecting structural integrity of Li-rich layered oxides. Theoretical calculations and experimental characterizations demonstrate that oxygen vacancies provide a favourable ionic diffusion environment in the bulk and significantly suppress gas release from the surface. The target material is achievable in delivering a discharge capacity as high as 301 mAh g(-1) with initial Coulombic efficiency of 93.2%. After 100 cycles, a reversible capacity of 300 mAh g(-1) still remains without any obvious decay in voltage. This study sheds light on the comprehensive design and control of oxygen activity in transition-metal-oxide systems for next-generation Li-ion batteries.

Published

2016

10. Dental resin monomer enables unique NbO2/carbon lithium‐ion battery negative electrode with exceptional performance

Author

Ji, Qing, Gao, Xiangwen, Zhang, Qiuju, Jin, Liyu, Wang, Da, Xia, Yonggao, Yin, Shanshan, Xia, Senlin, Hohn, Nuri, Zuo, Xiuxia, Wang, Xiaoyan, Xie, Shuang, Xu, Zhuijun, Ma, Liujia, Chen, Liang, Chen, George Z., Zhu, Jin, Hu, Binjie, Müller‐Buschbaum, Peter, Bruce, Peter G., Cheng, Ya‐Jun, Ji, Qing, Gao, Xiangwen, Zhang, Qiuju, Jin, Liyu, Wang, Da, Xia, Yonggao, Yin, Shanshan, Xia, Senlin, Hohn, Nuri, Zuo, Xiuxia, Wang, Xiaoyan, Xie, Shuang, Xu, Zhuijun, Ma, Liujia, Chen, Liang, Chen, George Z., Zhu, Jin, Hu, Binjie, Müller‐Buschbaum, Peter, Bruce, Peter G., and Cheng, Ya‐Jun

Abstract

Niobium dioxide (NbO2) features a high theoretical capacity and an outstanding electron conductivity, which makes it a promising alternative to the commercial graphite negative electrode. However, studies on NbO2 based lithium-ion battery negative electrodes have been rarely reported. In the present work, NbO2 nanoparticles homogeneously embedded in a carbon matrix are synthesized through calcination using a dental resin monomer (bisphenol A glycidyl dimethacrylate, Bis-GMA) as the solvent and a carbon source and niobium ethoxide (NbETO) as the precursor. It is revealed that a low Bis-GMA/NbETO mass ratio (from 1:1 to 1:2) enables the conversion of Nb (V) to Nb (IV) due to increased porosity induced by an alcoholysis reaction between the NbETO and Bis-GMA. The as-prepared NbO2/carbon nanohybrid delivers a reversible capacity of 225 mAh g−1 after 500 cycles at a 1 C rate with a Coulombic efficiency of more than 99.4% in the cycles. Various experimental and theoretical approaches including solid state nuclear magnetic resonance, ex situ X-ray diffraction, differential electrochemical mass spectrometry, and density functional theory are utilized to understand the fundamental lithiation/delithiation mechanisms of the NbO2/carbon nanohybrid. The results suggest that the NbO2/carbon nanohybrid bearing high capacity, long cycle life, and low gas evolution is promising for lithium storage applications.

11. Oxidation decomposition mechanism of fluoroethylene carbonate-based electrolytes for high-voltage lithium ion batteries: a DFT calculation and experimental study

Author

Xia, Lan, Tang, Bencan, Yao, Linbin, Wang, Kai, Cheris, Anastasia, Pan, Yueyang, Lee, Saixi, Xia, Yonggao, Chen, George Z., Liu, Zhaoping, Xia, Lan, Tang, Bencan, Yao, Linbin, Wang, Kai, Cheris, Anastasia, Pan, Yueyang, Lee, Saixi, Xia, Yonggao, Chen, George Z., and Liu, Zhaoping

Abstract

The oxidative decomposition mechanism of fluoroethylene carbonate (FEC) used in high-voltage batteries is investigated by using density functional theory (DFT). Radical cation FEC•+ is formed from FEC by transferring one electron to electrode and the most likely decomposition products are CO2 and 2-fluoroacetaldehyde radical cation. Other possible products are CO, formaldehyde and formyl fluoride radical cations. These radical cations are surrounded by much FEC solvent and their radical center may attack the carbonyl carbon of FEC to form aldehyde and oligomers of alkyl carbonates, which is similar with the oxidative decomposition of EC. Then, our experimental result reveals that FEC-based electrolyte has rather high anodic stability. It can form a robust SEI film on the positive electrode surface, which can inhibit unwanted electrolyte solvent and LiPF6 salts decomposition, alleviate Mn/Ni dissolution and therefore, improve the coulombic efficiency and the cycling stability of high voltage LiNi0.5Mn1.5O4 positive electrodes. This work displays that FEC-based electrolyte systems have considerable potential replacement of the EC-based electrolyte for the applications in 5 V Li-ion batteries.

12. Impact of CO2 activation on the structure, composition, and performance of Sb/C nanohybrid lithium/sodium-ion battery anodes

Author

Liang, Suzhe, Cheng, Ya-Jun, Wang, Xiaoyan, Xu, Zhuijun, Ma, Liujia, Xu, Hewei, Ji, Qing, Zuo, Xiuxia, Müller-Buschbaum, Peter, Xia, Yonggao, Liang, Suzhe, Cheng, Ya-Jun, Wang, Xiaoyan, Xu, Zhuijun, Ma, Liujia, Xu, Hewei, Ji, Qing, Zuo, Xiuxia, Müller-Buschbaum, Peter, and Xia, Yonggao

Abstract

Antimony (Sb) has been regarded as one of the most promising anode materials for both lithium-ion batteries (LIBs) and sodium-ion batteries (SIBs) and attracted much attention in recent years. Alleviating the volumetric effect of Sb during charge and discharge processes is the key point to promote Sb-based anodes to practical applications. Carbon dioxide (CO2) activation is applied to improve the rate performance of the Sb/C nanohybrid anodes caused by the limited diffusion of Li/Na ions in excessive carbon components. Based on the reaction between CO2 and carbon, CO2 activation can not only reduce the excess carbon content of the Sb/C nanohybrid but also create abundant mesopores inside the carbon matrix, leading to enhanced rate performance. Additionally, CO2 activation is also a fast and facile method, which is perfectly suitable for the fabrication system we proposed. As a result, after CO2 activation, the average capacity of the Sb/C nanohybrid LIB anode is increased by about 18 times (from 9 mA h g−1 to 160 mA h g−1) at a current density of 3300 mA g−1. Moreover, the application of the CO2-activated Sb/C nanohybrid as a SIB anode is also demonstrated, showing good electrochemical performance.

13. Dental resin monomer enables unique NbO2/carbon lithium‐ion battery negative electrode with exceptional performance

Author

Ji, Qing, Gao, Xiangwen, Zhang, Qiuju, Jin, Liyu, Wang, Da, Xia, Yonggao, Yin, Shanshan, Xia, Senlin, Hohn, Nuri, Zuo, Xiuxia, Wang, Xiaoyan, Xie, Shuang, Xu, Zhuijun, Ma, Liujia, Chen, Liang, Chen, George Z., Zhu, Jin, Hu, Binjie, Müller‐Buschbaum, Peter, Bruce, Peter G., Cheng, Ya‐Jun, Ji, Qing, Gao, Xiangwen, Zhang, Qiuju, Jin, Liyu, Wang, Da, Xia, Yonggao, Yin, Shanshan, Xia, Senlin, Hohn, Nuri, Zuo, Xiuxia, Wang, Xiaoyan, Xie, Shuang, Xu, Zhuijun, Ma, Liujia, Chen, Liang, Chen, George Z., Zhu, Jin, Hu, Binjie, Müller‐Buschbaum, Peter, Bruce, Peter G., and Cheng, Ya‐Jun

Abstract

Niobium dioxide (NbO2) features a high theoretical capacity and an outstanding electron conductivity, which makes it a promising alternative to the commercial graphite negative electrode. However, studies on NbO2 based lithium-ion battery negative electrodes have been rarely reported. In the present work, NbO2 nanoparticles homogeneously embedded in a carbon matrix are synthesized through calcination using a dental resin monomer (bisphenol A glycidyl dimethacrylate, Bis-GMA) as the solvent and a carbon source and niobium ethoxide (NbETO) as the precursor. It is revealed that a low Bis-GMA/NbETO mass ratio (from 1:1 to 1:2) enables the conversion of Nb (V) to Nb (IV) due to increased porosity induced by an alcoholysis reaction between the NbETO and Bis-GMA. The as-prepared NbO2/carbon nanohybrid delivers a reversible capacity of 225 mAh g−1 after 500 cycles at a 1 C rate with a Coulombic efficiency of more than 99.4% in the cycles. Various experimental and theoretical approaches including solid state nuclear magnetic resonance, ex situ X-ray diffraction, differential electrochemical mass spectrometry, and density functional theory are utilized to understand the fundamental lithiation/delithiation mechanisms of the NbO2/carbon nanohybrid. The results suggest that the NbO2/carbon nanohybrid bearing high capacity, long cycle life, and low gas evolution is promising for lithium storage applications.

14. Fluorinated electrolytes for li-ion batteries: the lithium difluoro(oxalato)borate additive for stabilizing the solid electrolyte interphase

Author

Xia, Lan, Lee, Saixi, Jiang, Yabei, Xia, Yonggao, Chen, George Z., Liu, Zhaoping, Xia, Lan, Lee, Saixi, Jiang, Yabei, Xia, Yonggao, Chen, George Z., and Liu, Zhaoping

Abstract

Fluorinated electrolytes based on fluoroethylene carbonate (FEC) have been considered as promising alternative electrolytes for high-voltage and high-energy capacity lithium-ion batteries (LIBs). However, the compatibility of the fluorinated electrolytes with graphite negative electrodes is unclear. In this paper, we have systematically investigated, for the first time, the stability of fluorinated electrolytes with graphite negative electrodes, and the result shows that unlike the ethylene carbonate (EC)-based electrolyte, the FEC-based electrolyte (EC was totally replaced by FEC) is incapable of forming a protective and effective solid electrolyte interphase (SEI) that protects the electrolyte from runaway reduction on the graphite surface. The reason is that the lowest unoccupied molecular orbital energy levels are also lowered by the introduction of fluorine into the solvent, and the FEC solvent has poorer resistance against reduction, leading to instability on the graphite negative electrode. To tackle this problem, two lithium salts of lithium bis(oxalato)borate and lithium difluoro(oxalato)borate (LiDFOB) have been investigated as negative-electrode film-forming additives. Incorporation of only 0.5 wt % LiDFOB to a FEC-based electrolyte [1.0 M LiPF6 in 3:7 (FEC−ethyl methyl carbonate)] results in excellent cycling performance of the graphite negative electrode. This improved property originates from the generation of a thinner and better quality SEI film with little LiF by the sacrificial reduction of the LiDFOB additive on the graphite negative electrode surface. On the other hand, this additive can stabilize the electrolyte by scavenging HF. Meanwhile, the incorporated LiDFOB additive has positive influence on the interphase layer on the positive electrode surface and significantly decreases the amount of HF formation, finally leading to improved cycling stability and rate capability of LiNi0.5Mn1.5O4 electrodes at a high cutoff voltage of 5 V. The data dem

15. Oxidation decomposition mechanism of fluoroethylene carbonate-based electrolytes for high-voltage lithium ion batteries: a DFT calculation and experimental study

Author

Xia, Lan, Tang, Bencan, Yao, Linbin, Wang, Kai, Cheris, Anastasia, Pan, Yueyang, Lee, Saixi, Xia, Yonggao, Chen, George Z., Liu, Zhaoping, Xia, Lan, Tang, Bencan, Yao, Linbin, Wang, Kai, Cheris, Anastasia, Pan, Yueyang, Lee, Saixi, Xia, Yonggao, Chen, George Z., and Liu, Zhaoping

Abstract

The oxidative decomposition mechanism of fluoroethylene carbonate (FEC) used in high-voltage batteries is investigated by using density functional theory (DFT). Radical cation FEC•+ is formed from FEC by transferring one electron to electrode and the most likely decomposition products are CO2 and 2-fluoroacetaldehyde radical cation. Other possible products are CO, formaldehyde and formyl fluoride radical cations. These radical cations are surrounded by much FEC solvent and their radical center may attack the carbonyl carbon of FEC to form aldehyde and oligomers of alkyl carbonates, which is similar with the oxidative decomposition of EC. Then, our experimental result reveals that FEC-based electrolyte has rather high anodic stability. It can form a robust SEI film on the positive electrode surface, which can inhibit unwanted electrolyte solvent and LiPF6 salts decomposition, alleviate Mn/Ni dissolution and therefore, improve the coulombic efficiency and the cycling stability of high voltage LiNi0.5Mn1.5O4 positive electrodes. This work displays that FEC-based electrolyte systems have considerable potential replacement of the EC-based electrolyte for the applications in 5 V Li-ion batteries.

16. Impact of CO2 activation on the structure, composition, and performance of Sb/C nanohybrid lithium/sodium-ion battery anodes

Author

Liang, Suzhe, Cheng, Ya-Jun, Wang, Xiaoyan, Xu, Zhuijun, Ma, Liujia, Xu, Hewei, Ji, Qing, Zuo, Xiuxia, Müller-Buschbaum, Peter, Xia, Yonggao, Liang, Suzhe, Cheng, Ya-Jun, Wang, Xiaoyan, Xu, Zhuijun, Ma, Liujia, Xu, Hewei, Ji, Qing, Zuo, Xiuxia, Müller-Buschbaum, Peter, and Xia, Yonggao

Abstract

Antimony (Sb) has been regarded as one of the most promising anode materials for both lithium-ion batteries (LIBs) and sodium-ion batteries (SIBs) and attracted much attention in recent years. Alleviating the volumetric effect of Sb during charge and discharge processes is the key point to promote Sb-based anodes to practical applications. Carbon dioxide (CO2) activation is applied to improve the rate performance of the Sb/C nanohybrid anodes caused by the limited diffusion of Li/Na ions in excessive carbon components. Based on the reaction between CO2 and carbon, CO2 activation can not only reduce the excess carbon content of the Sb/C nanohybrid but also create abundant mesopores inside the carbon matrix, leading to enhanced rate performance. Additionally, CO2 activation is also a fast and facile method, which is perfectly suitable for the fabrication system we proposed. As a result, after CO2 activation, the average capacity of the Sb/C nanohybrid LIB anode is increased by about 18 times (from 9 mA h g−1 to 160 mA h g−1) at a current density of 3300 mA g−1. Moreover, the application of the CO2-activated Sb/C nanohybrid as a SIB anode is also demonstrated, showing good electrochemical performance.

17. Dental resin monomer enables unique NbO2/carbon lithium‐ion battery negative electrode with exceptional performance

Author

Ji, Qing, Gao, Xiangwen, Zhang, Qiuju, Jin, Liyu, Wang, Da, Xia, Yonggao, Yin, Shanshan, Xia, Senlin, Hohn, Nuri, Zuo, Xiuxia, Wang, Xiaoyan, Xie, Shuang, Xu, Zhuijun, Ma, Liujia, Chen, Liang, Chen, George Z., Zhu, Jin, Hu, Binjie, Müller‐Buschbaum, Peter, Bruce, Peter G., Cheng, Ya‐Jun, Ji, Qing, Gao, Xiangwen, Zhang, Qiuju, Jin, Liyu, Wang, Da, Xia, Yonggao, Yin, Shanshan, Xia, Senlin, Hohn, Nuri, Zuo, Xiuxia, Wang, Xiaoyan, Xie, Shuang, Xu, Zhuijun, Ma, Liujia, Chen, Liang, Chen, George Z., Zhu, Jin, Hu, Binjie, Müller‐Buschbaum, Peter, Bruce, Peter G., and Cheng, Ya‐Jun

Abstract

Niobium dioxide (NbO2) features a high theoretical capacity and an outstanding electron conductivity, which makes it a promising alternative to the commercial graphite negative electrode. However, studies on NbO2 based lithium-ion battery negative electrodes have been rarely reported. In the present work, NbO2 nanoparticles homogeneously embedded in a carbon matrix are synthesized through calcination using a dental resin monomer (bisphenol A glycidyl dimethacrylate, Bis-GMA) as the solvent and a carbon source and niobium ethoxide (NbETO) as the precursor. It is revealed that a low Bis-GMA/NbETO mass ratio (from 1:1 to 1:2) enables the conversion of Nb (V) to Nb (IV) due to increased porosity induced by an alcoholysis reaction between the NbETO and Bis-GMA. The as-prepared NbO2/carbon nanohybrid delivers a reversible capacity of 225 mAh g−1 after 500 cycles at a 1 C rate with a Coulombic efficiency of more than 99.4% in the cycles. Various experimental and theoretical approaches including solid state nuclear magnetic resonance, ex situ X-ray diffraction, differential electrochemical mass spectrometry, and density functional theory are utilized to understand the fundamental lithiation/delithiation mechanisms of the NbO2/carbon nanohybrid. The results suggest that the NbO2/carbon nanohybrid bearing high capacity, long cycle life, and low gas evolution is promising for lithium storage applications.

18. Impact of CO2 activation on the structure, composition, and performance of Sb/C nanohybrid lithium/sodium-ion battery anodes

Author

Liang, Suzhe, Cheng, Ya-Jun, Wang, Xiaoyan, Xu, Zhuijun, Ma, Liujia, Xu, Hewei, Ji, Qing, Zuo, Xiuxia, Müller-Buschbaum, Peter, Xia, Yonggao, Liang, Suzhe, Cheng, Ya-Jun, Wang, Xiaoyan, Xu, Zhuijun, Ma, Liujia, Xu, Hewei, Ji, Qing, Zuo, Xiuxia, Müller-Buschbaum, Peter, and Xia, Yonggao

Abstract

Antimony (Sb) has been regarded as one of the most promising anode materials for both lithium-ion batteries (LIBs) and sodium-ion batteries (SIBs) and attracted much attention in recent years. Alleviating the volumetric effect of Sb during charge and discharge processes is the key point to promote Sb-based anodes to practical applications. Carbon dioxide (CO2) activation is applied to improve the rate performance of the Sb/C nanohybrid anodes caused by the limited diffusion of Li/Na ions in excessive carbon components. Based on the reaction between CO2 and carbon, CO2 activation can not only reduce the excess carbon content of the Sb/C nanohybrid but also create abundant mesopores inside the carbon matrix, leading to enhanced rate performance. Additionally, CO2 activation is also a fast and facile method, which is perfectly suitable for the fabrication system we proposed. As a result, after CO2 activation, the average capacity of the Sb/C nanohybrid LIB anode is increased by about 18 times (from 9 mA h g−1 to 160 mA h g−1) at a current density of 3300 mA g−1. Moreover, the application of the CO2-activated Sb/C nanohybrid as a SIB anode is also demonstrated, showing good electrochemical performance.

19. Dental resin monomer enables unique NbO2/carbon lithium‐ion battery negative electrode with exceptional performance

Author

Ji, Qing, Gao, Xiangwen, Zhang, Qiuju, Jin, Liyu, Wang, Da, Xia, Yonggao, Yin, Shanshan, Xia, Senlin, Hohn, Nuri, Zuo, Xiuxia, Wang, Xiaoyan, Xie, Shuang, Xu, Zhuijun, Ma, Liujia, Chen, Liang, Chen, George Z., Zhu, Jin, Hu, Binjie, Müller‐Buschbaum, Peter, Bruce, Peter G., Cheng, Ya‐Jun, Ji, Qing, Gao, Xiangwen, Zhang, Qiuju, Jin, Liyu, Wang, Da, Xia, Yonggao, Yin, Shanshan, Xia, Senlin, Hohn, Nuri, Zuo, Xiuxia, Wang, Xiaoyan, Xie, Shuang, Xu, Zhuijun, Ma, Liujia, Chen, Liang, Chen, George Z., Zhu, Jin, Hu, Binjie, Müller‐Buschbaum, Peter, Bruce, Peter G., and Cheng, Ya‐Jun

Abstract

Niobium dioxide (NbO2) features a high theoretical capacity and an outstanding electron conductivity, which makes it a promising alternative to the commercial graphite negative electrode. However, studies on NbO2 based lithium-ion battery negative electrodes have been rarely reported. In the present work, NbO2 nanoparticles homogeneously embedded in a carbon matrix are synthesized through calcination using a dental resin monomer (bisphenol A glycidyl dimethacrylate, Bis-GMA) as the solvent and a carbon source and niobium ethoxide (NbETO) as the precursor. It is revealed that a low Bis-GMA/NbETO mass ratio (from 1:1 to 1:2) enables the conversion of Nb (V) to Nb (IV) due to increased porosity induced by an alcoholysis reaction between the NbETO and Bis-GMA. The as-prepared NbO2/carbon nanohybrid delivers a reversible capacity of 225 mAh g−1 after 500 cycles at a 1 C rate with a Coulombic efficiency of more than 99.4% in the cycles. Various experimental and theoretical approaches including solid state nuclear magnetic resonance, ex situ X-ray diffraction, differential electrochemical mass spectrometry, and density functional theory are utilized to understand the fundamental lithiation/delithiation mechanisms of the NbO2/carbon nanohybrid. The results suggest that the NbO2/carbon nanohybrid bearing high capacity, long cycle life, and low gas evolution is promising for lithium storage applications.

20. Fluorinated electrolytes for li-ion batteries: the lithium difluoro(oxalato)borate additive for stabilizing the solid electrolyte interphase

Author

Xia, Lan, Lee, Saixi, Jiang, Yabei, Xia, Yonggao, Chen, George Z., Liu, Zhaoping, Xia, Lan, Lee, Saixi, Jiang, Yabei, Xia, Yonggao, Chen, George Z., and Liu, Zhaoping

Abstract

Fluorinated electrolytes based on fluoroethylene carbonate (FEC) have been considered as promising alternative electrolytes for high-voltage and high-energy capacity lithium-ion batteries (LIBs). However, the compatibility of the fluorinated electrolytes with graphite negative electrodes is unclear. In this paper, we have systematically investigated, for the first time, the stability of fluorinated electrolytes with graphite negative electrodes, and the result shows that unlike the ethylene carbonate (EC)-based electrolyte, the FEC-based electrolyte (EC was totally replaced by FEC) is incapable of forming a protective and effective solid electrolyte interphase (SEI) that protects the electrolyte from runaway reduction on the graphite surface. The reason is that the lowest unoccupied molecular orbital energy levels are also lowered by the introduction of fluorine into the solvent, and the FEC solvent has poorer resistance against reduction, leading to instability on the graphite negative electrode. To tackle this problem, two lithium salts of lithium bis(oxalato)borate and lithium difluoro(oxalato)borate (LiDFOB) have been investigated as negative-electrode film-forming additives. Incorporation of only 0.5 wt % LiDFOB to a FEC-based electrolyte [1.0 M LiPF6 in 3:7 (FEC−ethyl methyl carbonate)] results in excellent cycling performance of the graphite negative electrode. This improved property originates from the generation of a thinner and better quality SEI film with little LiF by the sacrificial reduction of the LiDFOB additive on the graphite negative electrode surface. On the other hand, this additive can stabilize the electrolyte by scavenging HF. Meanwhile, the incorporated LiDFOB additive has positive influence on the interphase layer on the positive electrode surface and significantly decreases the amount of HF formation, finally leading to improved cycling stability and rate capability of LiNi0.5Mn1.5O4 electrodes at a high cutoff voltage of 5 V. The data dem

21. Oxidation decomposition mechanism of fluoroethylene carbonate-based electrolytes for high-voltage lithium ion batteries: a DFT calculation and experimental study

Author

Xia, Lan, Tang, Bencan, Yao, Linbin, Wang, Kai, Cheris, Anastasia, Pan, Yueyang, Lee, Saixi, Xia, Yonggao, Chen, George Z., Liu, Zhaoping, Xia, Lan, Tang, Bencan, Yao, Linbin, Wang, Kai, Cheris, Anastasia, Pan, Yueyang, Lee, Saixi, Xia, Yonggao, Chen, George Z., and Liu, Zhaoping

Abstract

The oxidative decomposition mechanism of fluoroethylene carbonate (FEC) used in high-voltage batteries is investigated by using density functional theory (DFT). Radical cation FEC•+ is formed from FEC by transferring one electron to electrode and the most likely decomposition products are CO2 and 2-fluoroacetaldehyde radical cation. Other possible products are CO, formaldehyde and formyl fluoride radical cations. These radical cations are surrounded by much FEC solvent and their radical center may attack the carbonyl carbon of FEC to form aldehyde and oligomers of alkyl carbonates, which is similar with the oxidative decomposition of EC. Then, our experimental result reveals that FEC-based electrolyte has rather high anodic stability. It can form a robust SEI film on the positive electrode surface, which can inhibit unwanted electrolyte solvent and LiPF6 salts decomposition, alleviate Mn/Ni dissolution and therefore, improve the coulombic efficiency and the cycling stability of high voltage LiNi0.5Mn1.5O4 positive electrodes. This work displays that FEC-based electrolyte systems have considerable potential replacement of the EC-based electrolyte for the applications in 5 V Li-ion batteries.

22. Dental resin monomer enables unique NbO2/carbon lithium‐ion battery negative electrode with exceptional performance

Author

Ji, Qing, Gao, Xiangwen, Zhang, Qiuju, Jin, Liyu, Wang, Da, Xia, Yonggao, Yin, Shanshan, Xia, Senlin, Hohn, Nuri, Zuo, Xiuxia, Wang, Xiaoyan, Xie, Shuang, Xu, Zhuijun, Ma, Liujia, Chen, Liang, Chen, George Z., Zhu, Jin, Hu, Binjie, Müller‐Buschbaum, Peter, Bruce, Peter G., Cheng, Ya‐Jun, Ji, Qing, Gao, Xiangwen, Zhang, Qiuju, Jin, Liyu, Wang, Da, Xia, Yonggao, Yin, Shanshan, Xia, Senlin, Hohn, Nuri, Zuo, Xiuxia, Wang, Xiaoyan, Xie, Shuang, Xu, Zhuijun, Ma, Liujia, Chen, Liang, Chen, George Z., Zhu, Jin, Hu, Binjie, Müller‐Buschbaum, Peter, Bruce, Peter G., and Cheng, Ya‐Jun

Abstract

Niobium dioxide (NbO2) features a high theoretical capacity and an outstanding electron conductivity, which makes it a promising alternative to the commercial graphite negative electrode. However, studies on NbO2 based lithium-ion battery negative electrodes have been rarely reported. In the present work, NbO2 nanoparticles homogeneously embedded in a carbon matrix are synthesized through calcination using a dental resin monomer (bisphenol A glycidyl dimethacrylate, Bis-GMA) as the solvent and a carbon source and niobium ethoxide (NbETO) as the precursor. It is revealed that a low Bis-GMA/NbETO mass ratio (from 1:1 to 1:2) enables the conversion of Nb (V) to Nb (IV) due to increased porosity induced by an alcoholysis reaction between the NbETO and Bis-GMA. The as-prepared NbO2/carbon nanohybrid delivers a reversible capacity of 225 mAh g−1 after 500 cycles at a 1 C rate with a Coulombic efficiency of more than 99.4% in the cycles. Various experimental and theoretical approaches including solid state nuclear magnetic resonance, ex situ X-ray diffraction, differential electrochemical mass spectrometry, and density functional theory are utilized to understand the fundamental lithiation/delithiation mechanisms of the NbO2/carbon nanohybrid. The results suggest that the NbO2/carbon nanohybrid bearing high capacity, long cycle life, and low gas evolution is promising for lithium storage applications.

23. Impact of CO2 activation on the structure, composition, and performance of Sb/C nanohybrid lithium/sodium-ion battery anodes

Author

Liang, Suzhe, Cheng, Ya-Jun, Wang, Xiaoyan, Xu, Zhuijun, Ma, Liujia, Xu, Hewei, Ji, Qing, Zuo, Xiuxia, Müller-Buschbaum, Peter, Xia, Yonggao, Liang, Suzhe, Cheng, Ya-Jun, Wang, Xiaoyan, Xu, Zhuijun, Ma, Liujia, Xu, Hewei, Ji, Qing, Zuo, Xiuxia, Müller-Buschbaum, Peter, and Xia, Yonggao

Abstract

Antimony (Sb) has been regarded as one of the most promising anode materials for both lithium-ion batteries (LIBs) and sodium-ion batteries (SIBs) and attracted much attention in recent years. Alleviating the volumetric effect of Sb during charge and discharge processes is the key point to promote Sb-based anodes to practical applications. Carbon dioxide (CO2) activation is applied to improve the rate performance of the Sb/C nanohybrid anodes caused by the limited diffusion of Li/Na ions in excessive carbon components. Based on the reaction between CO2 and carbon, CO2 activation can not only reduce the excess carbon content of the Sb/C nanohybrid but also create abundant mesopores inside the carbon matrix, leading to enhanced rate performance. Additionally, CO2 activation is also a fast and facile method, which is perfectly suitable for the fabrication system we proposed. As a result, after CO2 activation, the average capacity of the Sb/C nanohybrid LIB anode is increased by about 18 times (from 9 mA h g−1 to 160 mA h g−1) at a current density of 3300 mA g−1. Moreover, the application of the CO2-activated Sb/C nanohybrid as a SIB anode is also demonstrated, showing good electrochemical performance.

24. Fluorinated electrolytes for li-ion batteries: the lithium difluoro(oxalato)borate additive for stabilizing the solid electrolyte interphase

Author

Xia, Lan, Lee, Saixi, Jiang, Yabei, Xia, Yonggao, Chen, George Z., Liu, Zhaoping, Xia, Lan, Lee, Saixi, Jiang, Yabei, Xia, Yonggao, Chen, George Z., and Liu, Zhaoping

Abstract

Fluorinated electrolytes based on fluoroethylene carbonate (FEC) have been considered as promising alternative electrolytes for high-voltage and high-energy capacity lithium-ion batteries (LIBs). However, the compatibility of the fluorinated electrolytes with graphite negative electrodes is unclear. In this paper, we have systematically investigated, for the first time, the stability of fluorinated electrolytes with graphite negative electrodes, and the result shows that unlike the ethylene carbonate (EC)-based electrolyte, the FEC-based electrolyte (EC was totally replaced by FEC) is incapable of forming a protective and effective solid electrolyte interphase (SEI) that protects the electrolyte from runaway reduction on the graphite surface. The reason is that the lowest unoccupied molecular orbital energy levels are also lowered by the introduction of fluorine into the solvent, and the FEC solvent has poorer resistance against reduction, leading to instability on the graphite negative electrode. To tackle this problem, two lithium salts of lithium bis(oxalato)borate and lithium difluoro(oxalato)borate (LiDFOB) have been investigated as negative-electrode film-forming additives. Incorporation of only 0.5 wt % LiDFOB to a FEC-based electrolyte [1.0 M LiPF6 in 3:7 (FEC−ethyl methyl carbonate)] results in excellent cycling performance of the graphite negative electrode. This improved property originates from the generation of a thinner and better quality SEI film with little LiF by the sacrificial reduction of the LiDFOB additive on the graphite negative electrode surface. On the other hand, this additive can stabilize the electrolyte by scavenging HF. Meanwhile, the incorporated LiDFOB additive has positive influence on the interphase layer on the positive electrode surface and significantly decreases the amount of HF formation, finally leading to improved cycling stability and rate capability of LiNi0.5Mn1.5O4 electrodes at a high cutoff voltage of 5 V. The data dem

25. Oxidation decomposition mechanism of fluoroethylene carbonate-based electrolytes for high-voltage lithium ion batteries: a DFT calculation and experimental study

Author

Xia, Lan, Tang, Bencan, Yao, Linbin, Wang, Kai, Cheris, Anastasia, Pan, Yueyang, Lee, Saixi, Xia, Yonggao, Chen, George Z., Liu, Zhaoping, Xia, Lan, Tang, Bencan, Yao, Linbin, Wang, Kai, Cheris, Anastasia, Pan, Yueyang, Lee, Saixi, Xia, Yonggao, Chen, George Z., and Liu, Zhaoping

Abstract

The oxidative decomposition mechanism of fluoroethylene carbonate (FEC) used in high-voltage batteries is investigated by using density functional theory (DFT). Radical cation FEC•+ is formed from FEC by transferring one electron to electrode and the most likely decomposition products are CO2 and 2-fluoroacetaldehyde radical cation. Other possible products are CO, formaldehyde and formyl fluoride radical cations. These radical cations are surrounded by much FEC solvent and their radical center may attack the carbonyl carbon of FEC to form aldehyde and oligomers of alkyl carbonates, which is similar with the oxidative decomposition of EC. Then, our experimental result reveals that FEC-based electrolyte has rather high anodic stability. It can form a robust SEI film on the positive electrode surface, which can inhibit unwanted electrolyte solvent and LiPF6 salts decomposition, alleviate Mn/Ni dissolution and therefore, improve the coulombic efficiency and the cycling stability of high voltage LiNi0.5Mn1.5O4 positive electrodes. This work displays that FEC-based electrolyte systems have considerable potential replacement of the EC-based electrolyte for the applications in 5 V Li-ion batteries.

26. Impact of CO2 activation on the structure, composition, and performance of Sb/C nanohybrid lithium/sodium-ion battery anodes

Author

Liang, Suzhe, Cheng, Ya-Jun, Wang, Xiaoyan, Xu, Zhuijun, Ma, Liujia, Xu, Hewei, Ji, Qing, Zuo, Xiuxia, Müller-Buschbaum, Peter, Xia, Yonggao, Liang, Suzhe, Cheng, Ya-Jun, Wang, Xiaoyan, Xu, Zhuijun, Ma, Liujia, Xu, Hewei, Ji, Qing, Zuo, Xiuxia, Müller-Buschbaum, Peter, and Xia, Yonggao

Abstract

Antimony (Sb) has been regarded as one of the most promising anode materials for both lithium-ion batteries (LIBs) and sodium-ion batteries (SIBs) and attracted much attention in recent years. Alleviating the volumetric effect of Sb during charge and discharge processes is the key point to promote Sb-based anodes to practical applications. Carbon dioxide (CO2) activation is applied to improve the rate performance of the Sb/C nanohybrid anodes caused by the limited diffusion of Li/Na ions in excessive carbon components. Based on the reaction between CO2 and carbon, CO2 activation can not only reduce the excess carbon content of the Sb/C nanohybrid but also create abundant mesopores inside the carbon matrix, leading to enhanced rate performance. Additionally, CO2 activation is also a fast and facile method, which is perfectly suitable for the fabrication system we proposed. As a result, after CO2 activation, the average capacity of the Sb/C nanohybrid LIB anode is increased by about 18 times (from 9 mA h g−1 to 160 mA h g−1) at a current density of 3300 mA g−1. Moreover, the application of the CO2-activated Sb/C nanohybrid as a SIB anode is also demonstrated, showing good electrochemical performance.

27. Dental resin monomer enables unique NbO2/carbon lithium‐ion battery negative electrode with exceptional performance

Author

Ji, Qing, Gao, Xiangwen, Zhang, Qiuju, Jin, Liyu, Wang, Da, Xia, Yonggao, Yin, Shanshan, Xia, Senlin, Hohn, Nuri, Zuo, Xiuxia, Wang, Xiaoyan, Xie, Shuang, Xu, Zhuijun, Ma, Liujia, Chen, Liang, Chen, George Z., Zhu, Jin, Hu, Binjie, Müller‐Buschbaum, Peter, Bruce, Peter G., Cheng, Ya‐Jun, Ji, Qing, Gao, Xiangwen, Zhang, Qiuju, Jin, Liyu, Wang, Da, Xia, Yonggao, Yin, Shanshan, Xia, Senlin, Hohn, Nuri, Zuo, Xiuxia, Wang, Xiaoyan, Xie, Shuang, Xu, Zhuijun, Ma, Liujia, Chen, Liang, Chen, George Z., Zhu, Jin, Hu, Binjie, Müller‐Buschbaum, Peter, Bruce, Peter G., and Cheng, Ya‐Jun

Abstract

Niobium dioxide (NbO2) features a high theoretical capacity and an outstanding electron conductivity, which makes it a promising alternative to the commercial graphite negative electrode. However, studies on NbO2 based lithium-ion battery negative electrodes have been rarely reported. In the present work, NbO2 nanoparticles homogeneously embedded in a carbon matrix are synthesized through calcination using a dental resin monomer (bisphenol A glycidyl dimethacrylate, Bis-GMA) as the solvent and a carbon source and niobium ethoxide (NbETO) as the precursor. It is revealed that a low Bis-GMA/NbETO mass ratio (from 1:1 to 1:2) enables the conversion of Nb (V) to Nb (IV) due to increased porosity induced by an alcoholysis reaction between the NbETO and Bis-GMA. The as-prepared NbO2/carbon nanohybrid delivers a reversible capacity of 225 mAh g−1 after 500 cycles at a 1 C rate with a Coulombic efficiency of more than 99.4% in the cycles. Various experimental and theoretical approaches including solid state nuclear magnetic resonance, ex situ X-ray diffraction, differential electrochemical mass spectrometry, and density functional theory are utilized to understand the fundamental lithiation/delithiation mechanisms of the NbO2/carbon nanohybrid. The results suggest that the NbO2/carbon nanohybrid bearing high capacity, long cycle life, and low gas evolution is promising for lithium storage applications.

28. Fluorinated electrolytes for li-ion batteries: the lithium difluoro(oxalato)borate additive for stabilizing the solid electrolyte interphase

Author

Xia, Lan, Lee, Saixi, Jiang, Yabei, Xia, Yonggao, Chen, George Z., Liu, Zhaoping, Xia, Lan, Lee, Saixi, Jiang, Yabei, Xia, Yonggao, Chen, George Z., and Liu, Zhaoping

Abstract

Fluorinated electrolytes based on fluoroethylene carbonate (FEC) have been considered as promising alternative electrolytes for high-voltage and high-energy capacity lithium-ion batteries (LIBs). However, the compatibility of the fluorinated electrolytes with graphite negative electrodes is unclear. In this paper, we have systematically investigated, for the first time, the stability of fluorinated electrolytes with graphite negative electrodes, and the result shows that unlike the ethylene carbonate (EC)-based electrolyte, the FEC-based electrolyte (EC was totally replaced by FEC) is incapable of forming a protective and effective solid electrolyte interphase (SEI) that protects the electrolyte from runaway reduction on the graphite surface. The reason is that the lowest unoccupied molecular orbital energy levels are also lowered by the introduction of fluorine into the solvent, and the FEC solvent has poorer resistance against reduction, leading to instability on the graphite negative electrode. To tackle this problem, two lithium salts of lithium bis(oxalato)borate and lithium difluoro(oxalato)borate (LiDFOB) have been investigated as negative-electrode film-forming additives. Incorporation of only 0.5 wt % LiDFOB to a FEC-based electrolyte [1.0 M LiPF6 in 3:7 (FEC−ethyl methyl carbonate)] results in excellent cycling performance of the graphite negative electrode. This improved property originates from the generation of a thinner and better quality SEI film with little LiF by the sacrificial reduction of the LiDFOB additive on the graphite negative electrode surface. On the other hand, this additive can stabilize the electrolyte by scavenging HF. Meanwhile, the incorporated LiDFOB additive has positive influence on the interphase layer on the positive electrode surface and significantly decreases the amount of HF formation, finally leading to improved cycling stability and rate capability of LiNi0.5Mn1.5O4 electrodes at a high cutoff voltage of 5 V. The data dem

29. Oxidation decomposition mechanism of fluoroethylene carbonate-based electrolytes for high-voltage lithium ion batteries: a DFT calculation and experimental study

Author

Xia, Lan, Tang, Bencan, Yao, Linbin, Wang, Kai, Cheris, Anastasia, Pan, Yueyang, Lee, Saixi, Xia, Yonggao, Chen, George Z., Liu, Zhaoping, Xia, Lan, Tang, Bencan, Yao, Linbin, Wang, Kai, Cheris, Anastasia, Pan, Yueyang, Lee, Saixi, Xia, Yonggao, Chen, George Z., and Liu, Zhaoping

Abstract

The oxidative decomposition mechanism of fluoroethylene carbonate (FEC) used in high-voltage batteries is investigated by using density functional theory (DFT). Radical cation FEC•+ is formed from FEC by transferring one electron to electrode and the most likely decomposition products are CO2 and 2-fluoroacetaldehyde radical cation. Other possible products are CO, formaldehyde and formyl fluoride radical cations. These radical cations are surrounded by much FEC solvent and their radical center may attack the carbonyl carbon of FEC to form aldehyde and oligomers of alkyl carbonates, which is similar with the oxidative decomposition of EC. Then, our experimental result reveals that FEC-based electrolyte has rather high anodic stability. It can form a robust SEI film on the positive electrode surface, which can inhibit unwanted electrolyte solvent and LiPF6 salts decomposition, alleviate Mn/Ni dissolution and therefore, improve the coulombic efficiency and the cycling stability of high voltage LiNi0.5Mn1.5O4 positive electrodes. This work displays that FEC-based electrolyte systems have considerable potential replacement of the EC-based electrolyte for the applications in 5 V Li-ion batteries.