Investigating the influence of processing parameters on bimetallic catalysts for high-yield carbon nanotube synthesis
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Abstract
The efficient synthesis of carbon nanotubes (CNTs) remains a challenge, and optimizing processing conditions for high-quality CNT production is a subject of ongoing research. In this study, the influence of processing parameters on the structure-property relationships of synthesized Fe-Ni bimetallic catalysts and the yield of carbon nanotubes (CNTs) was investigated. The study also aimed to optimize the synthesis conditions for the Fe-Ni bimetallic catalyst supported on CaCO3 and examine the effect of CNT purification on the final product. The CNTs were synthesized using a chemical vapor deposition process with an Fe-Ni bimetallic catalyst supported on CaCO3, and the effects of processing parameters such as pre-calcination temperature, stirring speed, support mass, and pre-calcination time on the yield and properties of the CNTs were analyzed. The synthesized CNTs were then characterized using SEM, FT-IR, BET, XRD, and Raman spectrometers to assess their structure and properties. The study revealed that optimizing the synthesis conditions led to increased graphitization and crystallinity of the CNTs. A maximum CNT yield of 376% was obtained under the optimal conditions of a reaction temperature of 700°C, a time of reaction of 90 min, and nitrogen and C2H2 flow rates of 294 mL/min and 193 mL/min, respectively. CNT purification was found to be effective in reducing impurities and functionalizing the CNTs for easy dispersion. The findings provide valuable insights for the development of efficient methods for the large-scale production of high-quality CNTs.
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References
Gupta N, Gupta SM, Sharma SK. Carbon nanotubes: synthesis, properties and engineering applications. Carbon Lett. 2019;29:419-447.
Maślana K, Kaleńczuk RJ, Zielińska B, Mijowska E. Synthesis and characterization of nitrogen-doped carbon nanotubes derived from g-C3N4. Materials. 2020;16(6):1-12.
Ali E, Hadis D, Hamzeh K, Kouhi M, Zarghami N, Akbarzadeh A, et al. Carbon nanotubes: properties, synthesis, purification, and medical applications. Nanoscale Res Lett. 2014;9:393:1-13.
Aliyu A, Abdulkareem AS, Kovo AS, Abubakre OK, Oladejo JT, Kariim I. Synthesize multi-walled carbon nanotubes via catalytic chemical vapour deposition method on fe-ni bimetallic catalyst supported on kaolin. Carbon Lett. 2017;21:33-50.
Arora N, Sharma NN. Arc discharge synthesis of carbon nanotubes: comprehensive review. Diam Relat Mater. 2014;50:135-150.
Prasek J, Drbohlavova J, Chomoucka J, Hubalek J, Jasek O, Adam V, et al. Methods for carbon nanotubes synthesis - review. J Mater Chem. 2011;21:15872-15884.
Cheng Y, Jiang SP. Advances in electrocatalysts for oxygen evolution reaction of water electrolysis-from metal oxides to carbon nanotubes. Prog Nat Sci Mater Int. 2015;25(6):545-553.
Kavecký Š, Valúchová J, Čaplovičová M, Heissler S, Šajgalík P, Janek M. Nontronites as catalyst for synthesis of carbon nanotubes by catalytic chemical vapor deposition. Appl Clay Sci. 2015;114:170-178.
Kumar U, Yadav BC. Synthesis of carbon nanotubes by direct liquid injection chemical vapor deposition method and its relevance for developing an ultra-sensitive room temperature based CO 2 sensor. J Taiwan Inst Chem Eng. 2019;96:652-663.
Arunkumar T, Karthikeyan R, Subramani RR, Viswanathan K, Anish M. Synthesis and characterisation of multi-walled carbon nanotubes (MWCNTs). Int J Ambient Energy. 2020;41:452-456.
Bankole MT, Mohammed IA, Abdulkareem AS, Tijani JO, Ochigbo SS, Abubakre OK, et al. Optimization of supported bimetallic (Fe-Co/CaCO3) catalyst synthesis parameters for carbon nanotubes growth using factorial experimental design. J Alloys Compd. 2018;749:85-102.
Purohit R, Purohit K, Rana S, Rana RS, Patel V. Carbon nanotubes and their growth methods. Procedia Mater Sci. 2014;6:716-728.
Chiwaye N, Jewell LL, Billing DG, Naidoo D, Ncube M, Coville NJ. In situ powder XRD and Mössbauer study of Fe-Co supported on CaCO3. Mater Res Bull. 2014;56:98-106.
Abdulkareem AS, Kariim I, Temitope BM, Oladejo JT, Abodunrin T, Olu SC. Synthesis and characterization of tri-metallic Fe-Co-Ni catalyst Supported on CaCO3 for multi-walled carbon nanotubes growth via chemical vapor deposition technique. Arab J Sci Eng. 2017;42(6):4365-4381.
Ratković S, Kiss E, Bošković G. Synthesis of high-purity carbon nanotubes over alumina and silica supported bimetallic catalysts. Chem Ind Chem Eng Q. 2009;15:263-270.
Shah KA, Tali BA. Synthesis of carbon nanotubes by catalytic chemical vapour deposition: A review on carbon sources, catalysts and substrates. Mater Sci Semicond Process. 2016;41:67-82.
Bajad G, Guguloth V, Vijayakumar RP, Bose S. Conversion of plastic waste into CNTs using Ni/Mo/MgO catalyst - an optimization approach by mixture experiment. Fuller Nanotub Carbon Nanostructures.2016; 24(2):162-169.
Liu H, Zhang Y, Li R, Sun XL, Rachid HA. Effects of bimetallic catalysts on synthesis of nitrogen-doped carbon nanotubes as nanoscale energetic materials. Particuology 2011;9(5):465-470.
Ayillath Kutteri D, Wang IW, Samanta A, Li L, Hu JL. Methane decomposition to tip and base grown carbon nanotubes and COx-free H2 over mono- and bimetallic 3d transition metal catalysts. Catal Sci Technol. 2018;8(3):858-869.
Magrez A, Seo JW, Smajda R, Mioni M, Forró L. Catalytic CVD synthesis of carbon nanotubes: towards high yield and low temperature growth. Materials. 2010;3(11):4871-4891.
Voelskow K, Becker MJ, Xia W, Muhler M, Turek T. The influence of kinetics, mass transfer and catalyst deactivation on the growth rate of multiwalled carbon nanotubes from ethene on a cobalt-based catalyst. Chem Eng J. 2014;244:68-74.
Ismail AF, Goh PS, Tee JC, Sanip SM, Aziz M. A review of purification techniques for carbon nanotubes. Nano. 2008;3:127-143.
McCarty JG, Gusman M, Lowe DM, Hildenbrand DL, Lau KN. Stability of supported metal and supported metal oxide combustion catalysts. Catal Today. 1999;47(1-4):5-17.
Kumar R, Singh RK, Singh DP, Vaz AR, Yadav RR, Rout CS, et al. Synthesis of self-assembled and hierarchical palladium-CNTs-reduced graphene oxide composites for enhanced field emission properties. Mater Des. 2017;122:110-117.