Simultaneously improved surface hardness and thermal diffusivity of carbon nanotube/zinc silicate composites via colloidal processing
Materials with ideal thermal dissipation can prevent electronic devices from overheating and sustaining internal damage. However, obtaining passive heat sink materials with a well-distributed thermal transport network remained challenging. In this study, carbon nanotubes (CNTs) reinforced zinc silic...
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2023
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my.utm.1055492024-05-02T02:59:33Z http://eprints.utm.my/105549/ Simultaneously improved surface hardness and thermal diffusivity of carbon nanotube/zinc silicate composites via colloidal processing Kar, Fei Chan Mohd. Zaid, Mohd. Hafiz Mamat, Md. Shuhazlly Tanemura, Masaki Miyazaki, Hidetoshi Kamis, Shahira Liza Maruyama, Takahiro Sako, Katsuya Sharma, Kamal Prasad Osman, Nurul Huda Mazu, Nurul Najiha Yaakob, Yazid Q Science (General) Materials with ideal thermal dissipation can prevent electronic devices from overheating and sustaining internal damage. However, obtaining passive heat sink materials with a well-distributed thermal transport network remained challenging. In this study, carbon nanotubes (CNTs) reinforced zinc silicate (Zn2SiO4) composites (CNTs/ZS) were fabricated via colloidal processing and pressureless sintering. The CNTs was first dispersed in 1,2,3,4-tetrahydronapathalene (C10H12) through sonication, before composite-mixing and densification with zinc silicate ceramic. It revealed that the dispersed CNTs simultaneously improved the mechanical and thermal properties of the composites, along with reducing relative density. The Vickers hardness, thermal diffusivity, and thermal conductivity of the optimized composite containing 1.0 wt% CNTs increased by 42%, 179%, and 537%, respectively, compared to the pristine ZS. The SEM observation on the 1.0 wt% CNTs/ZS composite surface determined that the area fraction of the CNTs inclusions was approximately 60%, which was advantageous for phonon propagation and electron transmission path. The combined effect of the phonon and electron transmission path outperformed the polycrystalline-induced Umklapp scattering and porosity-induced phonon-pore scattering, which were identified as obstacles to the heat-transfer process. Thus, this CNTs reinforcement through colloidal processing can be a strategy for designing of efficient silicate-based heatsink candidates in optoelectronic applications. Elsevier B.V. 2023-11-01 Article PeerReviewed Kar, Fei Chan and Mohd. Zaid, Mohd. Hafiz and Mamat, Md. Shuhazlly and Tanemura, Masaki and Miyazaki, Hidetoshi and Kamis, Shahira Liza and Maruyama, Takahiro and Sako, Katsuya and Sharma, Kamal Prasad and Osman, Nurul Huda and Mazu, Nurul Najiha and Yaakob, Yazid (2023) Simultaneously improved surface hardness and thermal diffusivity of carbon nanotube/zinc silicate composites via colloidal processing. Materials Chemistry and Physics, 309 (NA). NA. ISSN 0254-0584 http://dx.doi.org/10.1016/j.matchemphys.2023.128357 DOI:10.1016/j.matchemphys.2023.128357 |
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Q Science (General) Kar, Fei Chan Mohd. Zaid, Mohd. Hafiz Mamat, Md. Shuhazlly Tanemura, Masaki Miyazaki, Hidetoshi Kamis, Shahira Liza Maruyama, Takahiro Sako, Katsuya Sharma, Kamal Prasad Osman, Nurul Huda Mazu, Nurul Najiha Yaakob, Yazid Simultaneously improved surface hardness and thermal diffusivity of carbon nanotube/zinc silicate composites via colloidal processing |
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Materials with ideal thermal dissipation can prevent electronic devices from overheating and sustaining internal damage. However, obtaining passive heat sink materials with a well-distributed thermal transport network remained challenging. In this study, carbon nanotubes (CNTs) reinforced zinc silicate (Zn2SiO4) composites (CNTs/ZS) were fabricated via colloidal processing and pressureless sintering. The CNTs was first dispersed in 1,2,3,4-tetrahydronapathalene (C10H12) through sonication, before composite-mixing and densification with zinc silicate ceramic. It revealed that the dispersed CNTs simultaneously improved the mechanical and thermal properties of the composites, along with reducing relative density. The Vickers hardness, thermal diffusivity, and thermal conductivity of the optimized composite containing 1.0 wt% CNTs increased by 42%, 179%, and 537%, respectively, compared to the pristine ZS. The SEM observation on the 1.0 wt% CNTs/ZS composite surface determined that the area fraction of the CNTs inclusions was approximately 60%, which was advantageous for phonon propagation and electron transmission path. The combined effect of the phonon and electron transmission path outperformed the polycrystalline-induced Umklapp scattering and porosity-induced phonon-pore scattering, which were identified as obstacles to the heat-transfer process. Thus, this CNTs reinforcement through colloidal processing can be a strategy for designing of efficient silicate-based heatsink candidates in optoelectronic applications. |
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Article |
| author |
Kar, Fei Chan Mohd. Zaid, Mohd. Hafiz Mamat, Md. Shuhazlly Tanemura, Masaki Miyazaki, Hidetoshi Kamis, Shahira Liza Maruyama, Takahiro Sako, Katsuya Sharma, Kamal Prasad Osman, Nurul Huda Mazu, Nurul Najiha Yaakob, Yazid |
| author_facet |
Kar, Fei Chan Mohd. Zaid, Mohd. Hafiz Mamat, Md. Shuhazlly Tanemura, Masaki Miyazaki, Hidetoshi Kamis, Shahira Liza Maruyama, Takahiro Sako, Katsuya Sharma, Kamal Prasad Osman, Nurul Huda Mazu, Nurul Najiha Yaakob, Yazid |
| author_sort |
Kar, Fei Chan |
| title |
Simultaneously improved surface hardness and thermal diffusivity of carbon nanotube/zinc silicate composites via colloidal processing |
| title_short |
Simultaneously improved surface hardness and thermal diffusivity of carbon nanotube/zinc silicate composites via colloidal processing |
| title_full |
Simultaneously improved surface hardness and thermal diffusivity of carbon nanotube/zinc silicate composites via colloidal processing |
| title_fullStr |
Simultaneously improved surface hardness and thermal diffusivity of carbon nanotube/zinc silicate composites via colloidal processing |
| title_full_unstemmed |
Simultaneously improved surface hardness and thermal diffusivity of carbon nanotube/zinc silicate composites via colloidal processing |
| title_sort |
simultaneously improved surface hardness and thermal diffusivity of carbon nanotube/zinc silicate composites via colloidal processing |
| publisher |
Elsevier B.V. |
| publishDate |
2023 |
| url |
http://eprints.utm.my/105549/ http://dx.doi.org/10.1016/j.matchemphys.2023.128357 |
| _version_ |
1800082627711991808 |
| score |
13.223943 |