Role of Surface Reactions in Hydrogen-Oxygen Explosion Limits

Jianhang Li; Wenkai Liang; Jinliang Chen; Wenhu Han; Chung K. Law

doi:10.1021/acs.energyfuels.2c02693

Role of Surface Reactions in Hydrogen-Oxygen Explosion Limits

Jianhang Li, Wenkai Liang^*, Jinliang Chen, Wenhu Han^*, Chung K. Law

^*Corresponding author for this work

School of Mechatronical Engineering

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

10 Citations (Scopus)

Abstract

In this paper, the role of surface reactions in the explosion limits of hydrogen-oxygen mixtures was investigated, which was found to substantially affect the limits. Specifically, we compared situations with and without surface reactions by considering various sticking coefficients, with the temperature exponents of the radicals varying simultaneously and individually, site density of surface and no surface reactions, dilutions of four gases, equivalence ratio of H₂and O₂, reactor size (sphere radii), and residence time. The specific roles of these factors were identified, demonstrating that the existence of surface reactions can substantially modify the explosion limits and that the simulation can accurately predict the experimental data from both the closed vessel and flow reactor by accounting for the surface reactions.

Original language	English
Pages (from-to)	12729-12736
Number of pages	8
Journal	Energy and Fuels
Volume	36
Issue number	20
DOIs	https://doi.org/10.1021/acs.energyfuels.2c02693
Publication status	Published - 20 Oct 2022

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10.1021/acs.energyfuels.2c02693

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abstract = "In this paper, the role of surface reactions in the explosion limits of hydrogen-oxygen mixtures was investigated, which was found to substantially affect the limits. Specifically, we compared situations with and without surface reactions by considering various sticking coefficients, with the temperature exponents of the radicals varying simultaneously and individually, site density of surface and no surface reactions, dilutions of four gases, equivalence ratio of H2and O2, reactor size (sphere radii), and residence time. The specific roles of these factors were identified, demonstrating that the existence of surface reactions can substantially modify the explosion limits and that the simulation can accurately predict the experimental data from both the closed vessel and flow reactor by accounting for the surface reactions.",

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AU - Li, Jianhang

AU - Liang, Wenkai

AU - Chen, Jinliang

AU - Han, Wenhu

AU - Law, Chung K.

PY - 2022/10/20

Y1 - 2022/10/20

N2 - In this paper, the role of surface reactions in the explosion limits of hydrogen-oxygen mixtures was investigated, which was found to substantially affect the limits. Specifically, we compared situations with and without surface reactions by considering various sticking coefficients, with the temperature exponents of the radicals varying simultaneously and individually, site density of surface and no surface reactions, dilutions of four gases, equivalence ratio of H2and O2, reactor size (sphere radii), and residence time. The specific roles of these factors were identified, demonstrating that the existence of surface reactions can substantially modify the explosion limits and that the simulation can accurately predict the experimental data from both the closed vessel and flow reactor by accounting for the surface reactions.

AB - In this paper, the role of surface reactions in the explosion limits of hydrogen-oxygen mixtures was investigated, which was found to substantially affect the limits. Specifically, we compared situations with and without surface reactions by considering various sticking coefficients, with the temperature exponents of the radicals varying simultaneously and individually, site density of surface and no surface reactions, dilutions of four gases, equivalence ratio of H2and O2, reactor size (sphere radii), and residence time. The specific roles of these factors were identified, demonstrating that the existence of surface reactions can substantially modify the explosion limits and that the simulation can accurately predict the experimental data from both the closed vessel and flow reactor by accounting for the surface reactions.

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VL - 36

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EP - 12736

JO - Energy and Fuels

JF - Energy and Fuels

IS - 20

ER -

Role of Surface Reactions in Hydrogen-Oxygen Explosion Limits

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