Temperature inversion of the action of multilayer fullerenoid structures in the oxidation of N-decan by molecular oxygen

I. Polunkin, V. Pilyavsky, T. Kamenieva, S. Melnykova, О.О. Gajdaj, Yu. I. Bogomolov
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Abstract

It was established that at low temperatures MFS inhibit the oxidation of n-decan, and at temperatures close to the boiling point of the hydrocarbon, on the contrary, accelerate the transformation of the original alkane molecules. The composition of alkane transformation products in the high-temperature two-phase (gas-liquid) oxidation regime was analyzed by gas-liquid chromatography. It is shown that the transformation of n-decan molecules occurs according to the same schemes both in the case of oxidation without the additive of MFS, and in the presence of these compounds in a liquid. The work is devoted to the actual problem of increasing the energy efficiency of liquid motor fuels (gasoline, diesel and jet fuels) in transport power plants. One of the most acceptable ways to solve this problem at the present stage, which does not require capital expenditure, is to improve the processes of chemical transformations of fuel molecules in engines under the action of additives. The use of multilayer fullerene-like structures (MFS) as additives to motor fuels is proposed. The influence of additives modified MFS on the conversion of reagents in the processes of liquid-phase oxidation of n-decan by molecular oxygen at low (70°C) and high (150°C) temperatures has been studied. The change in the direction of the MFS action on chemical transformation of initial reagents depending on process temperature is experimentally revealed. It was established that at low temperatures MFS inhibit the oxidation of n-decan, and at temperatures close to the boiling point of hydrocarbons, on the contrary, accelerate the transformation of the original alkane molecules. The composition of alkane transformation products at high-temperature two-phase (gas-liquid) oxidation regime was analyzed by gas-liquid chromatography. It is shown that the transformation of n-decan molecules occurs according to the same schemes both in the case of oxidation without the additive of MFS, and in the presence of these compounds in a liquid.
多层类富勒烯结构在分子氧氧化n -癸烷过程中作用的温度反演
结果表明,MFS在低温下抑制正癸烷的氧化,而在接近烃类沸点的温度下,MFS则加速了原烷烃分子的转化。采用气液色谱法分析了高温两相(气液)氧化条件下烷烃转化产物的组成。结果表明,在不添加MFS的氧化情况下和在这些化合物存在的液体中,n-癸烷分子的转化都按照相同的方案发生。这项工作致力于提高运输发电厂液体发动机燃料(汽油、柴油和喷气燃料)能源效率的实际问题。现阶段解决这一问题的最可接受的方法之一是改进发动机中燃料分子在添加剂作用下的化学转化过程,这一方法不需要资本支出。提出了多层类富勒烯结构(MFS)作为汽车燃料添加剂的应用。在低(70℃)和高(150℃)条件下,研究了添加剂改性MFS对分子氧液相氧化n-癸烷过程中试剂转化的影响。实验揭示了MFS作用于初始试剂化学转变的方向随工艺温度的变化。结果表明,MFS在低温下抑制正癸烷的氧化,而在接近烃类沸点的温度下,MFS则加速了原烷烃分子的转化。采用气液色谱法分析了高温两相(气液)氧化条件下烷烃转化产物的组成。结果表明,在不添加MFS的氧化情况下和在这些化合物存在的液体中,n-癸烷分子的转化都按照相同的方案发生。
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