Modelling of the Flame Synthesis of Single-walled Carbon Nanotubes in Non-premixed Flames with Aerosol Catalyst

Muhammad Syafiq Ridhwan Selamat, Muhammad Thalhah Zainal, Mohd Fairus Mohd Yasin, Norikhwan Hamzah, Nor azwadi Che Sidik
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Abstract

The use of aerosol catalyst in the flame synthesis of carbon nanotube (CNT) is known to yield single-walled CNT (SWCNT) that is useful for various applications. Modelling works are needed to optimize operating conditions for SWCNT growth but are unavailable. Therefore, a baseline model for the aerosol-catalyst system in flames is developed and the effect of oxygen on SWCNT growth is investigated. A baseline flame model for a normal diffusion flame with 24% oxygen concentration at the inlet is established via Computational Fluid Dynamic simulation. A dispersed phase model (DPM) is employed to simulate the entrainment of catalyst particles. The flame model is coupled with a published CNT growth rate model to predict the CNT growth rate at each particle. Inlet oxygen concentration is varied from 19% to 27% to study the effect of oxygen on SWCNT growth. Satisfactory validation of the baseline flame shape and temperature is established. Results show that particle 3 for the baseline case yields the highest CNT length compared to other particles due to the suitable path for the synthesis. The particles are classified based on the shortest time residence, moderate and longest time residence. Increasing oxygen concentration from 19% to 27% results in a 30% decrease in CNT length for particle 3 for each inlet condition due to lower carbon precursor and composition in the flame. Furthermore, the results showed that regardless of burner operating conditions, high SWCNT growth is consistently predicted between 120-140 mm HAB, which indicates the existence of an optimum range of species concentration for SWCNT growth in aerosol-based flame synthesis. Thus, it can be inferred that SWCNT growth in the aerosol–based method is highly dependent on carbon source and moderately dependent on temperature
气溶胶催化剂非预混火焰中单壁碳纳米管火焰合成的模拟
在火焰合成碳纳米管(CNT)中使用气溶胶催化剂可以产生单壁碳纳米管(SWCNT),这对各种应用都很有用。需要建模工作来优化swcnts生长的操作条件,但目前还没有。因此,建立了火焰中气溶胶-催化剂体系的基线模型,并研究了氧对swcnts生长的影响。通过计算流体动力学仿真,建立了进口氧浓度为24%时正常扩散火焰的基线火焰模型。采用分散相模型(DPM)来模拟催化剂颗粒的夹带。火焰模型与已发表的碳纳米管生长速率模型相结合,以预测每个粒子的碳纳米管生长速率。入口氧浓度在19% ~ 27%之间变化,研究氧对swcnts生长的影响。建立了令人满意的基线火焰形状和温度验证。结果表明,由于合适的合成路径,基线情况下的粒子3与其他粒子相比产生了最高的碳纳米管长度。按最短停留时间、中等停留时间和最长停留时间对颗粒进行分类。将氧浓度从19%增加到27%,由于火焰中的碳前体和成分降低,在每种入口条件下,颗粒3的碳纳米管长度减少30%。此外,研究结果表明,无论燃烧器的工作条件如何,在120-140 mm的HAB范围内都可以预测到高的swcnts生长,这表明在气溶胶基火焰合成中存在swcnts生长的最佳物种浓度范围。因此,可以推断,在气溶胶为基础的方法中,swcnts的生长高度依赖于碳源,适度依赖于温度
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