Surface refinement of aluminium oxide by carbon-based reinforcement.
This paper clarifies the surface difference and tribological performance of anodic oxide coating reinforced with three different carbon-based sources. With the rising age of oxide coating as one of the strongest metal surface protectors, modification and improvement of this coating have been rapidly...
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Semarak Ilmu Publishing
2023
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| Online Access: | http://eprints.utm.my/106020/1/NoorAyumaMatTahir2023_SurfaceRefinementofAlumuniumOxidebyCarbonBasedReinforcement.pdf http://eprints.utm.my/106020/ http://dx.doi.org/10.37934/aram.105.1.2840 |
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my.utm.1060202024-05-29T06:35:19Z http://eprints.utm.my/106020/ Surface refinement of aluminium oxide by carbon-based reinforcement. Kamis, Shahira Liza Mat Tahir, Noor Ayuma Yaakob, Yazid Md. Ghazazi, Nur Afieqah TJ Mechanical engineering and machinery This paper clarifies the surface difference and tribological performance of anodic oxide coating reinforced with three different carbon-based sources. With the rising age of oxide coating as one of the strongest metal surface protectors, modification and improvement of this coating have been rapidly explored, including reinforcing carbon-based materials. The lack of literature on how the correlation between the particles' size improves the surface condition and its tribological properties opens up the gap in expanding this coating's potential. In this study, aluminium alloy AA2017 has been chosen as the substrate to be anodized with three different carbon sources: micro-sized graphite, nano-sized graphite, and graphite plate. With a constant 2A current on the DC power supply, the substrate was anodized for 60 minutes in a 20% sulphuric acid electrolyte. The finding shows that the anodic oxide with nano-sized graphite produces the highest hardness surface with almost 50% improvement compared to the unreinforced anodic oxide coating with no visible micro-cracks on the surface observed. Tribologically, the anodic oxide reinforced with micro-sized graphite produced the lowest coefficient of friction and wear rate at 0.4 and 1.25x10-5 mm3/Nm, respectively. The wear track image shows traces of debris that are different for each type of anodic coating that might be influenced by the surface roughness and hardness of the coating. Semarak Ilmu Publishing 2023-05 Article PeerReviewed application/pdf en http://eprints.utm.my/106020/1/NoorAyumaMatTahir2023_SurfaceRefinementofAlumuniumOxidebyCarbonBasedReinforcement.pdf Kamis, Shahira Liza and Mat Tahir, Noor Ayuma and Yaakob, Yazid and Md. Ghazazi, Nur Afieqah (2023) Surface refinement of aluminium oxide by carbon-based reinforcement. Journal of Advanced Research in Applied Mechanics, 105 (1). pp. 28-40. ISSN 2289-7895 http://dx.doi.org/10.37934/aram.105.1.2840 DOI: 10.37934/aram.105.1.2840 |
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TJ Mechanical engineering and machinery Kamis, Shahira Liza Mat Tahir, Noor Ayuma Yaakob, Yazid Md. Ghazazi, Nur Afieqah Surface refinement of aluminium oxide by carbon-based reinforcement. |
| description |
This paper clarifies the surface difference and tribological performance of anodic oxide coating reinforced with three different carbon-based sources. With the rising age of oxide coating as one of the strongest metal surface protectors, modification and improvement of this coating have been rapidly explored, including reinforcing carbon-based materials. The lack of literature on how the correlation between the particles' size improves the surface condition and its tribological properties opens up the gap in expanding this coating's potential. In this study, aluminium alloy AA2017 has been chosen as the substrate to be anodized with three different carbon sources: micro-sized graphite, nano-sized graphite, and graphite plate. With a constant 2A current on the DC power supply, the substrate was anodized for 60 minutes in a 20% sulphuric acid electrolyte. The finding shows that the anodic oxide with nano-sized graphite produces the highest hardness surface with almost 50% improvement compared to the unreinforced anodic oxide coating with no visible micro-cracks on the surface observed. Tribologically, the anodic oxide reinforced with micro-sized graphite produced the lowest coefficient of friction and wear rate at 0.4 and 1.25x10-5 mm3/Nm, respectively. The wear track image shows traces of debris that are different for each type of anodic coating that might be influenced by the surface roughness and hardness of the coating. |
| format |
Article |
| author |
Kamis, Shahira Liza Mat Tahir, Noor Ayuma Yaakob, Yazid Md. Ghazazi, Nur Afieqah |
| author_facet |
Kamis, Shahira Liza Mat Tahir, Noor Ayuma Yaakob, Yazid Md. Ghazazi, Nur Afieqah |
| author_sort |
Kamis, Shahira Liza |
| title |
Surface refinement of aluminium oxide by carbon-based reinforcement. |
| title_short |
Surface refinement of aluminium oxide by carbon-based reinforcement. |
| title_full |
Surface refinement of aluminium oxide by carbon-based reinforcement. |
| title_fullStr |
Surface refinement of aluminium oxide by carbon-based reinforcement. |
| title_full_unstemmed |
Surface refinement of aluminium oxide by carbon-based reinforcement. |
| title_sort |
surface refinement of aluminium oxide by carbon-based reinforcement. |
| publisher |
Semarak Ilmu Publishing |
| publishDate |
2023 |
| url |
http://eprints.utm.my/106020/1/NoorAyumaMatTahir2023_SurfaceRefinementofAlumuniumOxidebyCarbonBasedReinforcement.pdf http://eprints.utm.my/106020/ http://dx.doi.org/10.37934/aram.105.1.2840 |
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1800714787416440832 |
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13.212271 |