Hierarchical vertical graphene nanotube arrays via universal carbon plasma processing strategy : a platform for high-rate performance battery electrodes
Tailoring graphene-based nanostructures with numerous edges and large porosity is critical in developing high-capacity and fast rate-response Na-ion battery. Here, we report a rapid and generalized strategy for preparation of hierarchical vertical graphene nanotube (hVGT) array via carbon plasma pro...
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sg-ntu-dr.10356-926352023-02-28T19:48:31Z Hierarchical vertical graphene nanotube arrays via universal carbon plasma processing strategy : a platform for high-rate performance battery electrodes Ouyang, Bo Chao, Dongliang Jia, Guichong Zhang, Zheng Fan, Hong Jin Rawat, Rajdeep Singh School of Physical and Mathematical Sciences National Institute of Education Science::Physics Vertical Graphene Nanotube Carbon Plasma Tailoring graphene-based nanostructures with numerous edges and large porosity is critical in developing high-capacity and fast rate-response Na-ion battery. Here, we report a rapid and generalized strategy for preparation of hierarchical vertical graphene nanotube (hVGT) array via carbon plasma processing of CuO nanowires. A plausible mechanism is provided with the successful extension of such approach to grow hVGT array on different nanostructure templates such as Ni3S2, NiO and Co3O4. Benefiting from such unique structural advantages including high electrical conductivity, strong mechanical stability and highly porous structure, the self-supported MoS2 nano-crystals anchored hVGT (MVGT) nano-frameworks deliver satisfactory Na-ion storage properties with enhanced rate capability and long-term cycling stability. Hence, it is worth emphasizing that this deterministic and plasma-based dry-synthesis method to fabricate hVGT architecture could provide new avenues in designing and fabricating high-performance carbon-based electrodes for energy storage devices. Ministry of Education (MOE) Nanyang Technological University Accepted version This study was supported by NIE AcRF research grant RI 4/16 RSR provided by National Institute of Education, Nanyang Technological University, Singapore and MOE AcRF Tier 1 and Tier 2 grants (RG98/15, RG12/17and MOE2017-T2-1-073). 2019-06-11T02:27:10Z 2019-12-06T18:26:23Z 2019-06-11T02:27:10Z 2019-12-06T18:26:23Z 2019 Journal Article Ouyang, B., Chao, D., Jia, G., Zhang, Z., Fan, H. J., & Rawat, R. S. (2019). Hierarchical vertical graphene nanotube arrays via universal carbon plasma processing strategy : a platform for high-rate performance battery electrodes. Energy Storage Materials, 18462-469. doi:10.1016/j.ensm.2018.08.007 2405-8297 https://hdl.handle.net/10356/92635 http://hdl.handle.net/10220/48625 10.1016/j.ensm.2018.08.007 18 462 469 en Energy Storage Materials Energy Storage Materials © 2019 Elsevier. All rights reserved. This paper was published in Energy Storage Materials and is made available with permission of Elsevier. 20 p. application/pdf |
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Science::Physics Vertical Graphene Nanotube Carbon Plasma Ouyang, Bo Chao, Dongliang Jia, Guichong Zhang, Zheng Fan, Hong Jin Rawat, Rajdeep Singh Hierarchical vertical graphene nanotube arrays via universal carbon plasma processing strategy : a platform for high-rate performance battery electrodes |
| description |
Tailoring graphene-based nanostructures with numerous edges and large porosity is critical in developing high-capacity and fast rate-response Na-ion battery. Here, we report a rapid and generalized strategy for preparation of hierarchical vertical graphene nanotube (hVGT) array via carbon plasma processing of CuO nanowires. A plausible mechanism is provided with the successful extension of such approach to grow hVGT array on different nanostructure templates such as Ni3S2, NiO and Co3O4. Benefiting from such unique structural advantages including high electrical conductivity, strong mechanical stability and highly porous structure, the self-supported MoS2 nano-crystals anchored hVGT (MVGT) nano-frameworks deliver satisfactory Na-ion storage properties with enhanced rate capability and long-term cycling stability. Hence, it is worth emphasizing that this deterministic and plasma-based dry-synthesis method to fabricate hVGT architecture could provide new avenues in designing and fabricating high-performance carbon-based electrodes for energy storage devices. |
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School of Physical and Mathematical Sciences |
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School of Physical and Mathematical Sciences Ouyang, Bo Chao, Dongliang Jia, Guichong Zhang, Zheng Fan, Hong Jin Rawat, Rajdeep Singh |
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Article |
| author |
Ouyang, Bo Chao, Dongliang Jia, Guichong Zhang, Zheng Fan, Hong Jin Rawat, Rajdeep Singh |
| author_sort |
Ouyang, Bo |
| title |
Hierarchical vertical graphene nanotube arrays via universal carbon plasma processing strategy : a platform for high-rate performance battery electrodes |
| title_short |
Hierarchical vertical graphene nanotube arrays via universal carbon plasma processing strategy : a platform for high-rate performance battery electrodes |
| title_full |
Hierarchical vertical graphene nanotube arrays via universal carbon plasma processing strategy : a platform for high-rate performance battery electrodes |
| title_fullStr |
Hierarchical vertical graphene nanotube arrays via universal carbon plasma processing strategy : a platform for high-rate performance battery electrodes |
| title_full_unstemmed |
Hierarchical vertical graphene nanotube arrays via universal carbon plasma processing strategy : a platform for high-rate performance battery electrodes |
| title_sort |
hierarchical vertical graphene nanotube arrays via universal carbon plasma processing strategy : a platform for high-rate performance battery electrodes |
| publishDate |
2019 |
| url |
https://hdl.handle.net/10356/92635 http://hdl.handle.net/10220/48625 |
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