Burn Time Of Aluminum Nanoparticles: Strong Effect Of The Heating Rate And Melt-dispersion Mechanism

Valery I. Levitas

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Burn Time Of Aluminum Nanoparticles: Strong Effect Of The Heating Rate And Melt-dispersion Mechanism

机译：铝纳米粒子的燃烧时间：加热速率和熔体分散机理的强烈影响

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A puzzling results were reported for burn time of Al nanoparticles at T = 1100 ℃. At a heating rate of 10~3 C/s, the burn time exceeds 1 s [K. Park, D. Lee, A. Rai, D. Mukherjee, M. Zachariah, J. Phys. Chem. B 109 (2005) 7290-7299; M. Zachariah, private communication], while after fast heating (10~7 C/s), the burn time was only 500 μs [T. Bazyn, H. Krier, N. GIumac, Combust. Flame 145 (4) (2006) 703-713; T. Bazyn, H. Krier, N. Glumac, Proc. Combust. Inst. 31 (2007) 2021-2028]. This result is explained by the melt dispersion oxidation mechanism that operates for rapid heating only. Some characteristic parameters of this mechanism (critical heating rate, characteristic cluster size) are estimated.

机译：令人费解的结果报道了铝纳米颗粒在T = 1100℃下的燃烧时间。在10〜3 C / s的加热速率下，燃烧时间超过1 s [K。 Park，D。Lee，A。Rai，D。Mukherjee，M。Zachariah，J。Phys。化学B 109（2005）7290-7299； M. Zachariah，私人通讯]，在快速加热（10〜7 C / s）之后，燃烧时间仅为500μs[T. Bazyn，H。Krier，N。GIumac，Combust。火焰145（4）（2006）703-713; T. Bazyn，H.Krier，N.Glumac，Proc。燃烧研究所31（2007）2021-2028]。该结果由仅用于快速加热的熔体分散氧化机理解释。估计了该机制的一些特征参数（临界加热速率，特征簇大小）。

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《Combustion and Flame》 |2009年第2期|p.543-546|共4页
作者
Valery I. Levitas;
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Iowa State University, Departments of Mechanical Engineering, Aerospace Engineering, and Material Science and Engineering, 2028 Black Engineering Building, Ames, IA 50011, USA;

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收录信息美国《科学引文索引》(SCI);美国《工程索引》(EI);美国《生物学医学文摘》(MEDLINE);
原文格式 PDF
正文语种 eng
中图分类燃料与燃烧;
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Burn Time Of Aluminum Nanoparticles: Strong Effect Of The Heating Rate And Melt-dispersion Mechanism

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