Journal article

Kinetics of C5H4 isomer H reactions and incorporation of C5Hx (x = 3 – 5) chemistry into a detailed chemical kinetic model

R Adewale, G da Silva

Combustion and Flame | Published : 2021

DOI: 10.1016/j.combustflame.2020.12.046

Abstract

Although C5H4 isomers are detected in flames, they are not thoroughly incorporated into detailed chemical kinetics models (DCKMs). Here we use RRKM/ME modelling to simulate C5H4 + H reactions on a C5H5 potential energy surface. Kinetic studies indicate that C3H3 + C2H2 is the main fate but fall-off from the initial adduct isomer back to C5H4 + H cannot be ignored at relevant combustion temperatures of 900 to 2000 K. Calculated rate coefficient expressions were incorporated into a DCKM for a toluene flame, along with updates to other relevant reactions from the recent literature, particularly the open-chain 1-vinylpropargyl radical, l-C5H5. Obtained species mole fractions were found to be in ..

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University of Melbourne Researchers

Related Projects (1)

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THE NEW OXIDATION CHEMISTRY OF AMINES

Organic compounds containing nitrogen, including amines, are distributed throughout the atmosphere, where they are removed through oxidation..

Grants

Awarded by Australian Research Council

Funding Acknowledgements

This work was supported by the Australian Research Council (ARC) through Future Fellowship project FT130101304.

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Keywords

Rate Constants
Reaction-Mechanism
Toluene Flame
Engineering, Multidisciplinary
Cyclopentadienyl
Potential Energy Surface
Energy & Fuels
Detailed Chemical Kinetic Models
Science & Technology
Oxidation
Decomposition
Engineering, Mechanical
Thermodynamics
Polycyclic Aromatic-Hydrocarbons
Product Yields
4017 Mechanical Engineering
Toluene
Flames
Technology
Engineering, Chemical
Engineering
40 Engineering
Pyrolysis
Physical Sciences
1-Vinylpropargyl
C5hx Species
4002 Automotive Engineering