Numerical Study on the Effect of Insulator and Wire Mesh Toward Carbon Nanotubes Growth Region in Quasi Pyrolysis Chamber
Keywords:
Carbon nanotubes, Computational fluid dynamics, Insulator, Quasi-pyrolysis chamber, Flame synthesisAbstract
Flame synthesis is known to be a more energy- and time-efficient method for producing carbon nanotubes (CNTs) compared to other techniques. However, due to the presence of soot formation and highly oxidizing flame sheet in diffusion flame, synthesized CNT in flame suffers low growth rate and low CNT morphology quality. In this study, feasibility of utilising a quasi-pyrolysis chamber (QPC) with and without wire-mesh at the inlet, located on top of methane diffusion flame which separates the CNT growth region from the flame sheet was numerically simulated. Flame quenching effect by the wire-mesh at the inlet of QPC creating a pyrolysis condition within the chamber with methane flame formed outside the chamber, producing the required high temperature for CNT growth. Furthermore, application of insulator surrounding the flame was also numerically tested to evaluate its effect on temperature distribution within the QPC. The study found that the quasi-pyrolysis condition inside the chamber can be established without using wire-mesh only up to chamber with 12 mm diameter before oxygen starts to seep into the QPC and formed flame inside the chamber. Nevertheless, the temperature increase inside the QPC is minimal with removal of wire-mesh. Besides that, the addition of insulation surrounding the flame has significantly increased the predicted synthesized CNT length by 2.5 times. This is due to the increment of CO concentration more than 3 times inside QPC with application of insulator. Consequently, higher CO concentration helps to enhance the CNT growth region within the QPC from initially confined to the region near to the inlet of QPC, to all areas within the QPC. Hence, to ensure high energy efficiency and robustness, utilization of QPC with wire-mesh and insulator should be incorporated in the future development of practical CNT synthesis process in flame.References
[1] S. Rathinavel, K. Priyadharshini and D. Panda, A review on carbon nanotube: An overview of synthesis, properties, functionalization, characterization, and the application, Materials Today: Proceedings, 45, 2021, 5316-5322.
[2] W. Merchan-Merchan, A. V. Saveliev, L. Kennedy and W. C. Jimenez, Combustion synthesis of carbon nanotubes and related nanostructures, Progress in Energy and Combustion Science, 36(6), 2010, 696-727.
[3] Y. H. Tang, Y. F. Zheng, C. S. Lee, N. Wang, S. T. Lee and T. K. Sham, Carbon monoxide-assisted growth of carbon nanotubes, Chemical Physics Letters, 342, 2001, 259-264.
[4] A. G. Nasibulin, A. Moisala, D. P. Brown and E. I. Kauppinen, Carbon nanotubes and onions from carbon monoxide using Ni(acac)₂ and Cu(acac)₂ as catalyst precursors, Carbon, 41, 2003, 2711-2724.
[5] H. Chu, W. Han, F. Ren, L. Xiang, Y. Wei and C. Zhang, Flame synthesis of carbon nanotubes on different substrates in methane diffusion flames, ES Energy & Environment, 2, 2018, 73-81.
[6] N. Hamzah, M. F. M. Yasin, M. Z. M. Yusop, A. Saat and N. A. M. Subha, Rapid production of carbon nanotubes: A review on advancement in growth control and morphology manipulations of flame synthesis, Journal of Materials Chemistry A, 5, 2017, 25144-25170.
[7] N. Hamzah, M. F. M. Yasin, M. Z. M. Yusop, M. A. S. M. Haniff, M. F. Hasan, K. F. Tamrin and N. A. M. Subha, Effect of fuel and oxygen concentration toward catalyst encapsulation in water-assisted flame synthesis of carbon nanotubes, Combustion and Flame, 220, 2020, 272-287.
[8] Y. Mo, H. Zhou, B. Zhang, X. Du, Z. Lin, W. Li, H. Y. Liu and Y. W. Mai, Facile flame catalytic growth of carbon nanomaterials on the surface of carbon nanotubes, Applied Surface Science, 465, 2019, 23-30.
[9] C. Weise, A. Faccinetto, S. Kluge, T. Kasper, H. Wiggers, C. Schulz, I. Wlokas and A. Kempf, Buoyancy induced limits for nanoparticle synthesis experiments in horizontal premixed low-pressure flat-flame reactors, Combustion Theory and Modelling, 17, 2013, 504-521.
[10] M. T. Zainal, M. F. Mohd Yasin, M. Abdul Wahid and M. Mohd Sies, A flame structure approach for controlling carbon nanotube growth in flame synthesis, Combustion Science and Technology, 193, 2021, 1326-1342.
[11] R. Waelder, C. Park, A. Sloan, J. Carpena-Núñez, J. Yoho, S. Gorsse, R. Rao and B. Maruyama, Improved understanding of carbon nanotube growth via autonomous jump regression targeting of catalyst activity, Carbon, 228, 2024, 119356.
[12] E. Blurock and F. Battin-Leclerc, Modeling combustion with detailed kinetic mechanisms, Green Energy and Technology, Springer, 2013, 17-57.
[13] S. Naha, S. Sen, A. K. De and I. K. Puri, A detailed model for the flame synthesis of carbon nanotubes and nanofibers, Proceedings of the Combustion Institute, 31(II), 2007, 1821-1829.
[14] M. T. Zainal, M. Fairus, M. Yasin, M. Abid, I. Irawan, M. F. Roslan, N. Hamzah, M. Zamri and M. Yusop, Investigation on the deactivation of cobalt and iron catalysts in catalytic growth of carbon nanotube using a growth rate model, Journal of Advanced Research in Materials Science, 51, 2018, 11-22.
[15] P. Młynarczyk, The influence of the numerical solver selection on the nozzle impulse flow simulation results, MATEC Web of Conferences, 240, 2018, 03008.
[16] K. Fukumoto and Y. Oka, Simulation of turbulent non-premixed and partially premixed, Journal of Thermal Science and Technology, 9(1), 2014, 1-13.
[17] K. J. Kim, W. R. Yu, J. H. Youk and J. Lee, Factors governing the growth mode of carbon nanotubes on carbon-based substrates, Physical Chemistry Chemical Physics, 14, 2012, 14041-14048.
[18] W. Guanghai, S. Haoran, W. Chunpeng, Z. Jian, H. Yanli, Z. Shichao and C. Yufeng, High temperature microstructural evolution of ZrO₂ fibers thermal insulation materials, Key Engineering Materials, Trans Tech Publications Ltd, 2014, 319-322.
[19] L. S. Tao, Y. F. Chen, S. C. Zhang, K. W. Deng, H. R. Sun, X. K. Sun, D. C. Yan, K. Fang and N. Li, Preparation and performance of zirconia fiber board, Solid State Phenomena, Trans Tech Publications Ltd, 2018, 912-917.
[20] Y. Jaluria, Use of experimentation in the accurate numerical simulation of thermal processes, WIT Transactions on Engineering Sciences, 2010, 241-252.
[21] D. V. Krasnikov, S. N. Bokova-Sirosh, T. O. Tsendsuren, A. I. Romanenko, E. D. Obraztsova, V. A. Volodin and V. L. Kuznetsov, Influence of the growth temperature on the defective structure of the multi-walled carbon nanotubes, Physica Status Solidi B: Basic Research, 255(1), 2018, 1870101.
[22] M. H. Ibrahim, N. Hamzah, M. Z. M. Yusop, N. L. W. Septiani and M. F. M. Yasin, Control of morphology and crystallinity of CNTs in flame synthesis with one-dimensional reaction zone, Beilstein Journal of Nanotechnology, 14, 2023, 741-750.
[23] M. Li, Z. Xu, Z. Li, Y. Chen, J. Guo, H. Huo, H. Zhou, H. Huangfu, Z. Cao and H. Wang, An experimental and CFD study on gas flow field distribution in the growth process of multi-walled carbon nanotube arrays by thermal chemical vapor deposition, Crystal Research and Technology, 51, 2016, 702-707.
[24] Y. C. Yue, W. Ren, M. L. Zhao, M. X. Guo, Y. T. Zhang, J. Xia and D. J. Li, Effect of reaction temperature on carbon nanotubes, Advanced Materials Research, 2011, 1383-1386.
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Copyright (c) 2025 Jia Yong Chong, Muhammad Amirrul Amin Moen, Mohd Fairus Mohd Yasin; Tarit Das; Muhammad Thalhah Zainal, Nurul Adilla Mohd Subha, Norikhwan Hamzah
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