Mohamed Hammida , Antonio Fonseca , Roger Doome , Edmond De Hoffmann , Paul A. Thiry , Janos B. Nagy
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引用次数: 4
Abstract
The use of hydrocarbons for fullerenes synthesis has been described in the literature. In this study, the formation of fullerenes C60, C60O, C70, and C70O is investigated in premixed benzene-oxygen flames operated under a pressure of 7.5 kPa by systematically varying two physicochemical parameters: the initial velocity of the fresh gas mixture (at 298 K) at the burner, which is varied between 40 and 50 cm s−1, and the atomic C/O ratio, which is varied from 0.7 to 1.15. The objective of running each flame at different sets of conditions is to assess the sensitivity of reaching an optimum in the process of fullerenes production in flames.
A higher production rate of fullerenes Cn under different conditions is achieved at an optimal level of C/O ratio of 1.05 and 45 cm s−1 of gas velocity. In addition, the highest production rate of fullerenes is 786.7 mg/h, and the highest yield of carbon transformed to fullerenes, obtained is 0.22%. Flame synthesis of fullerenes would seem to offer potential for large-scale production. Different patterns for the production of fullerene and fullerenes oxide are obtained. This result seems to challenge the notion of complexity of the combustion, which accompanies the formation of these carbon molecules in flames. The mass spectrometer shows that heavy fullerenes containing more than 150 atoms are present in the production process. Peaks of PAH at m/e smaller than 500 amu suggest that the reaction of combining the polycyclic aromatic hydrocarbons in burned gases may play an important role in the formation of fullerenes in burned gas flames.
在文献中已经描述了碳氢化合物用于富勒烯合成。在本研究中,通过系统地改变两个物理化学参数,研究了富勒烯C60、C60O、C70和C70O在7.5kPa压力下运行的预混苯氧火焰中的形成:燃烧器处新鲜气体混合物(298K)的初始速度(在40和50 cm s−1之间变化)和原子C/O比(在0.7到1.15之间变化)。在不同的条件下运行每个火焰的目的是评估在火焰中生产富勒烯的过程中达到最佳的灵敏度。在C/O比为1.05和气体速度为45cm s−1的最佳水平下,在不同条件下获得了更高的富勒烯Cn产率。此外,富勒烯的最高生产率为786.7mg/h,转化为富勒烯的碳的最高产率为0.22%。富勒烯的火焰合成似乎具有大规模生产的潜力。获得了富勒烯和富勒烯氧化物的不同生产模式。这一结果似乎挑战了燃烧复杂性的概念,燃烧复杂性伴随着这些碳分子在火焰中的形成。质谱仪显示,在生产过程中存在含有150个以上原子的重富勒烯。m/e小于500amu的PAH峰值表明,燃烧气体中多环芳烃的结合反应可能在燃烧气体火焰中富勒烯的形成中发挥重要作用。