The utilization of waste cooking palm oil as a green carbon source for the growth of multilayer graphene
Waste cooking palm oil (WCPO) has been utilized as a green carbon source for the synthesization of graphene by double thermal chemical vapor deposition. The WCPO was placed in the first furnace (precursor furnace) whereas nickel was placed in the second furnace (deposition furnace). The deposition t...
Published in: | Journal of the Australian Ceramic Society |
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2-s2.0-85096491566 Malek M.F.; Robaiah M.; Suriani A.B.; Mamat M.H.; Ahmad M.K.; Soga T.; Rusop M.; Abdullah S.; Khusaimi Z.; Aslam M.; Asli N.A. The utilization of waste cooking palm oil as a green carbon source for the growth of multilayer graphene 2021 Journal of the Australian Ceramic Society 57 2 10.1007/s41779-020-00539-0 https://www.scopus.com/inward/record.uri?eid=2-s2.0-85096491566&doi=10.1007%2fs41779-020-00539-0&partnerID=40&md5=a8b6ec36c1a5d1bf3bb8187f766f3e89 Waste cooking palm oil (WCPO) has been utilized as a green carbon source for the synthesization of graphene by double thermal chemical vapor deposition. The WCPO was placed in the first furnace (precursor furnace) whereas nickel was placed in the second furnace (deposition furnace). The deposition temperatures were varied between 850 and 1100 °C. Raman results reveal the highest 2-D peak for the sample synthesized at 1000 °C, which indicates the high-quality formation of graphene. Besides, the sample also shows good crystallinity with a sharp peak at 26.8° which represents the hexagonal graphite structure and the introduction of graphene sheet formation. On the other hand, the FESEM image displays hexagonal structures since the graphene layers were formed after the precipitation of the carbon. Meanwhile, the UV-Vis result shows the highest reflectance in the visible light region which indicates the presence of the graphene layer on Ni. [Figure not available: see fulltext.] © 2020, Australian Ceramic Society. Springer 25101560 English Article |
author |
Malek M.F.; Robaiah M.; Suriani A.B.; Mamat M.H.; Ahmad M.K.; Soga T.; Rusop M.; Abdullah S.; Khusaimi Z.; Aslam M.; Asli N.A. |
spellingShingle |
Malek M.F.; Robaiah M.; Suriani A.B.; Mamat M.H.; Ahmad M.K.; Soga T.; Rusop M.; Abdullah S.; Khusaimi Z.; Aslam M.; Asli N.A. The utilization of waste cooking palm oil as a green carbon source for the growth of multilayer graphene |
author_facet |
Malek M.F.; Robaiah M.; Suriani A.B.; Mamat M.H.; Ahmad M.K.; Soga T.; Rusop M.; Abdullah S.; Khusaimi Z.; Aslam M.; Asli N.A. |
author_sort |
Malek M.F.; Robaiah M.; Suriani A.B.; Mamat M.H.; Ahmad M.K.; Soga T.; Rusop M.; Abdullah S.; Khusaimi Z.; Aslam M.; Asli N.A. |
title |
The utilization of waste cooking palm oil as a green carbon source for the growth of multilayer graphene |
title_short |
The utilization of waste cooking palm oil as a green carbon source for the growth of multilayer graphene |
title_full |
The utilization of waste cooking palm oil as a green carbon source for the growth of multilayer graphene |
title_fullStr |
The utilization of waste cooking palm oil as a green carbon source for the growth of multilayer graphene |
title_full_unstemmed |
The utilization of waste cooking palm oil as a green carbon source for the growth of multilayer graphene |
title_sort |
The utilization of waste cooking palm oil as a green carbon source for the growth of multilayer graphene |
publishDate |
2021 |
container_title |
Journal of the Australian Ceramic Society |
container_volume |
57 |
container_issue |
2 |
doi_str_mv |
10.1007/s41779-020-00539-0 |
url |
https://www.scopus.com/inward/record.uri?eid=2-s2.0-85096491566&doi=10.1007%2fs41779-020-00539-0&partnerID=40&md5=a8b6ec36c1a5d1bf3bb8187f766f3e89 |
description |
Waste cooking palm oil (WCPO) has been utilized as a green carbon source for the synthesization of graphene by double thermal chemical vapor deposition. The WCPO was placed in the first furnace (precursor furnace) whereas nickel was placed in the second furnace (deposition furnace). The deposition temperatures were varied between 850 and 1100 °C. Raman results reveal the highest 2-D peak for the sample synthesized at 1000 °C, which indicates the high-quality formation of graphene. Besides, the sample also shows good crystallinity with a sharp peak at 26.8° which represents the hexagonal graphite structure and the introduction of graphene sheet formation. On the other hand, the FESEM image displays hexagonal structures since the graphene layers were formed after the precipitation of the carbon. Meanwhile, the UV-Vis result shows the highest reflectance in the visible light region which indicates the presence of the graphene layer on Ni. [Figure not available: see fulltext.] © 2020, Australian Ceramic Society. |
publisher |
Springer |
issn |
25101560 |
language |
English |
format |
Article |
accesstype |
|
record_format |
scopus |
collection |
Scopus |
_version_ |
1809677597396697088 |