Oxygen Vacancy-Rich Cobalt-Doped MnO2 Nanorods for Zn Ion Batteries
Improving electrical conductivity and increasing the active site are important directions for improving the technology of manganese-based cathode materials for zinc ion batteries (ZIBs). In this paper, cobalt-doped and oxygen-vacancy coupled MnO2 nanorods (Vo-CMO) were prepared by defect engineering...
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| Published in | ACS applied materials & interfaces Vol. 17; no. 8; pp. 12074 - 12084 |
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| Main Authors | , , , , , , , , , |
| Format | Journal Article |
| Language | English |
| Published |
American Chemical Society
26.02.2025
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| Subjects | |
| Online Access | Get full text |
| ISSN | 1944-8244 1944-8252 1944-8252 |
| DOI | 10.1021/acsami.4c19746 |
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| Abstract | Improving electrical conductivity and increasing the active site are important directions for improving the technology of manganese-based cathode materials for zinc ion batteries (ZIBs). In this paper, cobalt-doped and oxygen-vacancy coupled MnO2 nanorods (Vo-CMO) were prepared by defect engineering and an ion doping strategy as cathode materials for rechargeable ZIBs. Oxygen vacancies can increase the defect density of the material and provide more migration paths for zinc ions, thereby increasing the electrochemical activity and improving the specific capacity. The introduction of cobalt can adjust the electronic structure of manganese oxide, change the Fermi level of the material, and promote the generation and transmission of charge carriers, thereby increasing the charge transfer rate and increasing the conductivity of the material. The synergistic effect among them can improve the diffusion kinetics of zinc ions, thereby increasing the capacity and cycle stability of the material. The Vo-CMO has better Zn2+ storage capacity of 295.6 mAh·g–1 at 0.1 A·g–1. The reaction mechanism of Vo-CMO material was H+/Zn2+ coinsertion through galvanostatic current intermittent titration (GITT) and ex situ experiments. In addition, the Vo-CMO material assembled the flexible quasi-solid ZIB. The synergistic effect of cobalt doping and oxygen vacancy can provide a new way to develop water-based ZIBs. |
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| AbstractList | Improving electrical conductivity and increasing the active site are important directions for improving the technology of manganese-based cathode materials for zinc ion batteries (ZIBs). In this paper, cobalt-doped and oxygen-vacancy coupled MnO2 nanorods (Vo-CMO) were prepared by defect engineering and an ion doping strategy as cathode materials for rechargeable ZIBs. Oxygen vacancies can increase the defect density of the material and provide more migration paths for zinc ions, thereby increasing the electrochemical activity and improving the specific capacity. The introduction of cobalt can adjust the electronic structure of manganese oxide, change the Fermi level of the material, and promote the generation and transmission of charge carriers, thereby increasing the charge transfer rate and increasing the conductivity of the material. The synergistic effect among them can improve the diffusion kinetics of zinc ions, thereby increasing the capacity and cycle stability of the material. The Vo-CMO has better Zn2+ storage capacity of 295.6 mAh·g-1 at 0.1 A·g-1. The reaction mechanism of Vo-CMO material was H+/Zn2+ coinsertion through galvanostatic current intermittent titration (GITT) and ex situ experiments. In addition, the Vo-CMO material assembled the flexible quasi-solid ZIB. The synergistic effect of cobalt doping and oxygen vacancy can provide a new way to develop water-based ZIBs.Improving electrical conductivity and increasing the active site are important directions for improving the technology of manganese-based cathode materials for zinc ion batteries (ZIBs). In this paper, cobalt-doped and oxygen-vacancy coupled MnO2 nanorods (Vo-CMO) were prepared by defect engineering and an ion doping strategy as cathode materials for rechargeable ZIBs. Oxygen vacancies can increase the defect density of the material and provide more migration paths for zinc ions, thereby increasing the electrochemical activity and improving the specific capacity. The introduction of cobalt can adjust the electronic structure of manganese oxide, change the Fermi level of the material, and promote the generation and transmission of charge carriers, thereby increasing the charge transfer rate and increasing the conductivity of the material. The synergistic effect among them can improve the diffusion kinetics of zinc ions, thereby increasing the capacity and cycle stability of the material. The Vo-CMO has better Zn2+ storage capacity of 295.6 mAh·g-1 at 0.1 A·g-1. The reaction mechanism of Vo-CMO material was H+/Zn2+ coinsertion through galvanostatic current intermittent titration (GITT) and ex situ experiments. In addition, the Vo-CMO material assembled the flexible quasi-solid ZIB. The synergistic effect of cobalt doping and oxygen vacancy can provide a new way to develop water-based ZIBs. Improving electrical conductivity and increasing the active site are important directions for improving the technology of manganese-based cathode materials for zinc ion batteries (ZIBs). In this paper, cobalt-doped and oxygen-vacancy coupled MnO2 nanorods (Vo-CMO) were prepared by defect engineering and an ion doping strategy as cathode materials for rechargeable ZIBs. Oxygen vacancies can increase the defect density of the material and provide more migration paths for zinc ions, thereby increasing the electrochemical activity and improving the specific capacity. The introduction of cobalt can adjust the electronic structure of manganese oxide, change the Fermi level of the material, and promote the generation and transmission of charge carriers, thereby increasing the charge transfer rate and increasing the conductivity of the material. The synergistic effect among them can improve the diffusion kinetics of zinc ions, thereby increasing the capacity and cycle stability of the material. The Vo-CMO has better Zn2+ storage capacity of 295.6 mAh·g–1 at 0.1 A·g–1. The reaction mechanism of Vo-CMO material was H+/Zn2+ coinsertion through galvanostatic current intermittent titration (GITT) and ex situ experiments. In addition, the Vo-CMO material assembled the flexible quasi-solid ZIB. The synergistic effect of cobalt doping and oxygen vacancy can provide a new way to develop water-based ZIBs. Improving electrical conductivity and increasing the active site are important directions for improving the technology of manganese-based cathode materials for zinc ion batteries (ZIBs). In this paper, cobalt-doped and oxygen-vacancy coupled MnO₂ nanorods (Vₒ-CMO) were prepared by defect engineering and an ion doping strategy as cathode materials for rechargeable ZIBs. Oxygen vacancies can increase the defect density of the material and provide more migration paths for zinc ions, thereby increasing the electrochemical activity and improving the specific capacity. The introduction of cobalt can adjust the electronic structure of manganese oxide, change the Fermi level of the material, and promote the generation and transmission of charge carriers, thereby increasing the charge transfer rate and increasing the conductivity of the material. The synergistic effect among them can improve the diffusion kinetics of zinc ions, thereby increasing the capacity and cycle stability of the material. The Vₒ-CMO has better Zn²⁺ storage capacity of 295.6 mAh·g–¹ at 0.1 A·g–¹. The reaction mechanism of Vₒ-CMO material was H⁺/Zn²⁺ coinsertion through galvanostatic current intermittent titration (GITT) and ex situ experiments. In addition, the Vₒ-CMO material assembled the flexible quasi-solid ZIB. The synergistic effect of cobalt doping and oxygen vacancy can provide a new way to develop water-based ZIBs. |
| Author | Wei, Fuxiang Sun, Bo Meng, Qingkun Guo, Sai Qi, Jiqiu Xu, Zihan Li, Qijian Chen, Xiaowen Sui, Yanwei Cao, Peng |
| AuthorAffiliation | University Auckland Department of Chem & Materials Engineering School of Chemical Engineering & Technology Jiangsu Province High-efficiency Energy Storage Technology and Equipment Engineering Laboratory, School of Materials Science and Physics |
| AuthorAffiliation_xml | – name: Department of Chem & Materials Engineering – name: University Auckland – name: Jiangsu Province High-efficiency Energy Storage Technology and Equipment Engineering Laboratory, School of Materials Science and Physics – name: School of Chemical Engineering & Technology |
| Author_xml | – sequence: 1 givenname: Xiaowen surname: Chen fullname: Chen, Xiaowen organization: School of Chemical Engineering & Technology – sequence: 2 givenname: Zihan surname: Xu fullname: Xu, Zihan organization: Jiangsu Province High-efficiency Energy Storage Technology and Equipment Engineering Laboratory, School of Materials Science and Physics – sequence: 3 givenname: Sai surname: Guo fullname: Guo, Sai organization: Jiangsu Province High-efficiency Energy Storage Technology and Equipment Engineering Laboratory, School of Materials Science and Physics – sequence: 4 givenname: Bo surname: Sun fullname: Sun, Bo organization: Jiangsu Province High-efficiency Energy Storage Technology and Equipment Engineering Laboratory, School of Materials Science and Physics – sequence: 5 givenname: Qijian surname: Li fullname: Li, Qijian organization: Jiangsu Province High-efficiency Energy Storage Technology and Equipment Engineering Laboratory, School of Materials Science and Physics – sequence: 6 givenname: Qingkun surname: Meng fullname: Meng, Qingkun organization: Jiangsu Province High-efficiency Energy Storage Technology and Equipment Engineering Laboratory, School of Materials Science and Physics – sequence: 7 givenname: Fuxiang orcidid: 0000-0001-6467-4096 surname: Wei fullname: Wei, Fuxiang organization: Jiangsu Province High-efficiency Energy Storage Technology and Equipment Engineering Laboratory, School of Materials Science and Physics – sequence: 8 givenname: Jiqiu surname: Qi fullname: Qi, Jiqiu organization: Jiangsu Province High-efficiency Energy Storage Technology and Equipment Engineering Laboratory, School of Materials Science and Physics – sequence: 9 givenname: Yanwei orcidid: 0000-0002-5740-6111 surname: Sui fullname: Sui, Yanwei email: wyds123456@outlook.com organization: Jiangsu Province High-efficiency Energy Storage Technology and Equipment Engineering Laboratory, School of Materials Science and Physics – sequence: 10 givenname: Peng orcidid: 0000-0001-6390-6852 surname: Cao fullname: Cao, Peng organization: University Auckland |
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| Keywords | flexible quasi-solid ZIB Vo-CMO nanorods the synergistic effect ZIB cathode materials DFT calculations |
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| SubjectTerms | active sites cathodes cobalt electrical conductivity electrochemistry Energy, Environmental, and Catalysis Applications manganese monoxide nanorods oxygen reaction mechanisms synergism titration zinc |
| Title | Oxygen Vacancy-Rich Cobalt-Doped MnO2 Nanorods for Zn Ion Batteries |
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