Clarification of soot formation mechanism by experiment and DSM

Tsuyoshi Yamamoto; Norihito Omoto; Fumihiko Shishido; Hideyuki Aoki; Takatoshi Miura

doi:10.1252/kakoronbunshu.30.36

Clarification of soot formation mechanism by experiment and DSM

Tsuyoshi Yamamoto, Norihito Omoto, Fumihiko Shishido, Hideyuki Aoki, Takatoshi Miura

Research output: Contribution to journal › Article › peer-review

3 Citations (Scopus)

Abstract

To clarify the mechanism of soot formation is very important from the viewpoint of reduction of environmental load and energy saving. Despite the large number of experimental and theoretical studies made on soot production, the mechanism of soot formation remains unclear. In this article, benzene pyrolysis was carried out in an alumina tube heated by plasma, and a numerical simulation was performed with a kinetic model that takes into account the reactions of benzene pyrolysis, nucleation formation, surface growth and coagulation and was constructed by adopting the Discrete-Sectional Method. The effects of residence time and initial benzene concentration on soot formation rate were examined. The results show that soot particles have a larger diameter and a narrower size distribution with the increase in residence time and reactive gas concentration.

Original language	English
Pages (from-to)	36-42
Number of pages	7
Journal	kagaku kogaku ronbunshu
Volume	30
Issue number	1
DOIs	https://doi.org/10.1252/kakoronbunshu.30.36
Publication status	Published - Jan 1 2004
Externally published	Yes

All Science Journal Classification (ASJC) codes

Chemistry(all)
Chemical Engineering(all)

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10.1252/kakoronbunshu.30.36

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T1 - Clarification of soot formation mechanism by experiment and DSM

AU - Yamamoto, Tsuyoshi

AU - Omoto, Norihito

AU - Shishido, Fumihiko

AU - Aoki, Hideyuki

AU - Miura, Takatoshi

PY - 2004/1/1

Y1 - 2004/1/1

N2 - To clarify the mechanism of soot formation is very important from the viewpoint of reduction of environmental load and energy saving. Despite the large number of experimental and theoretical studies made on soot production, the mechanism of soot formation remains unclear. In this article, benzene pyrolysis was carried out in an alumina tube heated by plasma, and a numerical simulation was performed with a kinetic model that takes into account the reactions of benzene pyrolysis, nucleation formation, surface growth and coagulation and was constructed by adopting the Discrete-Sectional Method. The effects of residence time and initial benzene concentration on soot formation rate were examined. The results show that soot particles have a larger diameter and a narrower size distribution with the increase in residence time and reactive gas concentration.

AB - To clarify the mechanism of soot formation is very important from the viewpoint of reduction of environmental load and energy saving. Despite the large number of experimental and theoretical studies made on soot production, the mechanism of soot formation remains unclear. In this article, benzene pyrolysis was carried out in an alumina tube heated by plasma, and a numerical simulation was performed with a kinetic model that takes into account the reactions of benzene pyrolysis, nucleation formation, surface growth and coagulation and was constructed by adopting the Discrete-Sectional Method. The effects of residence time and initial benzene concentration on soot formation rate were examined. The results show that soot particles have a larger diameter and a narrower size distribution with the increase in residence time and reactive gas concentration.

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Clarification of soot formation mechanism by experiment and DSM

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