Blending of a 3D cloud-like morphology with a 1D structure in a VO2/MXene nanocomposite to enhance the charge storage capability

Over the years, functional materials have been subject to intense research due mainly to their potential utilities in advancing the realm of nanotechnology. Here, a unique method is emphasized, probably for the first time, in breaking up MXene morphologies into tiny pieces using finer VO2 nanowires...

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Main Authors: Kumar N., Ansari M.N.M., Upadhyay S., Gajraj V., Chetana S., Joshi N.C., Sikiru S., Sen A.
Other Authors: 57201635180
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Published: Royal Society of Chemistry 2024
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spelling my.uniten.dspace-339162024-10-14T11:17:26Z Blending of a 3D cloud-like morphology with a 1D structure in a VO2/MXene nanocomposite to enhance the charge storage capability Kumar N. Ansari M.N.M. Upadhyay S. Gajraj V. Chetana S. Joshi N.C. Sikiru S. Sen A. 57201635180 55489853600 57220664508 57209006338 57220922604 57200496551 57211063469 55620434300 Blending Functional materials Morphology Nanowires X ray spectroscopy 1-D structures Breakings Charge storage Electrode configurations Potential utility Property Scanning microscopy Storage capability Symmetrics X-ray spectroscopy Vanadium dioxide Over the years, functional materials have been subject to intense research due mainly to their potential utilities in advancing the realm of nanotechnology. Here, a unique method is emphasized, probably for the first time, in breaking up MXene morphologies into tiny pieces using finer VO2 nanowires as templates. Scanning microscopy and X-ray spectroscopy techniques are used to describe this newly developed distinctive morphology. The morphological tension formed between the VO2 and the MXene surface significantly enhances the supercapacitive properties of VO2 at 286.0 F g?1, 2 A g?1 in a symmetric electrode configuration. The VO2 nanowire capacity increases by almost double on blending with MXene. An appreciable amount of energy is stored at 128 W h kg?1 and 1800 W kg?1. Better stability is also encountered with 97% capacity retention after the 10 000th cycle of galvanostic charge-discharge metrics. The three-dimensional cloud-like morphology of MXene surrounding VO2 nanowires helps in synergistically advancing their surface activity and safeguarding them against any pulverization. A promising good capacitive behavior can thus be built out of vanadium-based materials. � 2023 The Royal Society of Chemistry. Final 2024-10-14T03:17:26Z 2024-10-14T03:17:26Z 2023 Article 10.1039/d3tc02738d 2-s2.0-85180766585 https://www.scopus.com/inward/record.uri?eid=2-s2.0-85180766585&doi=10.1039%2fd3tc02738d&partnerID=40&md5=298b9e1e40992f2847a74e513902fa94 https://irepository.uniten.edu.my/handle/123456789/33916 11 48 17022 17033 Royal Society of Chemistry Scopus
institution Universiti Tenaga Nasional
building UNITEN Library
collection Institutional Repository
continent Asia
country Malaysia
content_provider Universiti Tenaga Nasional
content_source UNITEN Institutional Repository
url_provider http://dspace.uniten.edu.my/
topic Blending
Functional materials
Morphology
Nanowires
X ray spectroscopy
1-D structures
Breakings
Charge storage
Electrode configurations
Potential utility
Property
Scanning microscopy
Storage capability
Symmetrics
X-ray spectroscopy
Vanadium dioxide
spellingShingle Blending
Functional materials
Morphology
Nanowires
X ray spectroscopy
1-D structures
Breakings
Charge storage
Electrode configurations
Potential utility
Property
Scanning microscopy
Storage capability
Symmetrics
X-ray spectroscopy
Vanadium dioxide
Kumar N.
Ansari M.N.M.
Upadhyay S.
Gajraj V.
Chetana S.
Joshi N.C.
Sikiru S.
Sen A.
Blending of a 3D cloud-like morphology with a 1D structure in a VO2/MXene nanocomposite to enhance the charge storage capability
description Over the years, functional materials have been subject to intense research due mainly to their potential utilities in advancing the realm of nanotechnology. Here, a unique method is emphasized, probably for the first time, in breaking up MXene morphologies into tiny pieces using finer VO2 nanowires as templates. Scanning microscopy and X-ray spectroscopy techniques are used to describe this newly developed distinctive morphology. The morphological tension formed between the VO2 and the MXene surface significantly enhances the supercapacitive properties of VO2 at 286.0 F g?1, 2 A g?1 in a symmetric electrode configuration. The VO2 nanowire capacity increases by almost double on blending with MXene. An appreciable amount of energy is stored at 128 W h kg?1 and 1800 W kg?1. Better stability is also encountered with 97% capacity retention after the 10 000th cycle of galvanostic charge-discharge metrics. The three-dimensional cloud-like morphology of MXene surrounding VO2 nanowires helps in synergistically advancing their surface activity and safeguarding them against any pulverization. A promising good capacitive behavior can thus be built out of vanadium-based materials. � 2023 The Royal Society of Chemistry.
author2 57201635180
author_facet 57201635180
Kumar N.
Ansari M.N.M.
Upadhyay S.
Gajraj V.
Chetana S.
Joshi N.C.
Sikiru S.
Sen A.
format Article
author Kumar N.
Ansari M.N.M.
Upadhyay S.
Gajraj V.
Chetana S.
Joshi N.C.
Sikiru S.
Sen A.
author_sort Kumar N.
title Blending of a 3D cloud-like morphology with a 1D structure in a VO2/MXene nanocomposite to enhance the charge storage capability
title_short Blending of a 3D cloud-like morphology with a 1D structure in a VO2/MXene nanocomposite to enhance the charge storage capability
title_full Blending of a 3D cloud-like morphology with a 1D structure in a VO2/MXene nanocomposite to enhance the charge storage capability
title_fullStr Blending of a 3D cloud-like morphology with a 1D structure in a VO2/MXene nanocomposite to enhance the charge storage capability
title_full_unstemmed Blending of a 3D cloud-like morphology with a 1D structure in a VO2/MXene nanocomposite to enhance the charge storage capability
title_sort blending of a 3d cloud-like morphology with a 1d structure in a vo2/mxene nanocomposite to enhance the charge storage capability
publisher Royal Society of Chemistry
publishDate 2024
_version_ 1814061094749077504
score 13.222552