Autoignition chemistry of the hexane isomers: An experimental and kinetic modeling study

Henry J. Curran; Paolo Gaffuri; William J. Pitz; Charles K. Westbrook; William R. Leppard

doi:10.4271/952406

Autoignition chemistry of the hexane isomers: An experimental and kinetic modeling study

Henry J. Curran
, Paolo Gaffuri
, William J. Pitz
, Charles K. Westbrook
, William R. Leppard

Research output: Contribution to a Journal (Peer & Non Peer) › Conference article › peer-review

35 Citations (Scopus)

Abstract

Autoignition of the five distinct isomers of hexane is studied experimentally under motored engine conditions and computationally using a detailed chemical kinetic reaction mechanism. Computed and experimental results are compared and used to help understand the chemical factors leading to engine knock in spark-ignited engines and the molecular structure factors contributing to octane rating for hydrocarbon fuels. The kinetic model reproduces observed variations in critical compression ratio with fuel structure, and it also provides intermediate and final product species concentrations in much better agreement with observed results than has been possible previously. In addition, the computed results provide insights into the kinetic origins of fuel octane sensitivity.

Original language	English
Journal	SAE Technical Papers
DOIs	https://doi.org/10.4271/952406
Publication status	Published - 1995
Externally published	Yes
Event	Fuels and Lubricants Meeting and Exposition - Toronto, ON, Canada Duration: 16 Oct 1995 → 19 Oct 1995

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title = "Autoignition chemistry of the hexane isomers: An experimental and kinetic modeling study",

abstract = "Autoignition of the five distinct isomers of hexane is studied experimentally under motored engine conditions and computationally using a detailed chemical kinetic reaction mechanism. Computed and experimental results are compared and used to help understand the chemical factors leading to engine knock in spark-ignited engines and the molecular structure factors contributing to octane rating for hydrocarbon fuels. The kinetic model reproduces observed variations in critical compression ratio with fuel structure, and it also provides intermediate and final product species concentrations in much better agreement with observed results than has been possible previously. In addition, the computed results provide insights into the kinetic origins of fuel octane sensitivity.",

author = "Curran, \{Henry J.\} and Paolo Gaffuri and Pitz, \{William J.\} and Westbrook, \{Charles K.\} and Leppard, \{William R.\}",

year = "1995",

doi = "10.4271/952406",

language = "English",

journal = "SAE Technical Papers",

issn = "0148-7191",

publisher = "SAE International",

note = "Fuels and Lubricants Meeting and Exposition ; Conference date: 16-10-1995 Through 19-10-1995",

}

TY - JOUR

T1 - Autoignition chemistry of the hexane isomers

T2 - Fuels and Lubricants Meeting and Exposition

AU - Curran, Henry J.

AU - Gaffuri, Paolo

AU - Pitz, William J.

AU - Westbrook, Charles K.

AU - Leppard, William R.

PY - 1995

Y1 - 1995

N2 - Autoignition of the five distinct isomers of hexane is studied experimentally under motored engine conditions and computationally using a detailed chemical kinetic reaction mechanism. Computed and experimental results are compared and used to help understand the chemical factors leading to engine knock in spark-ignited engines and the molecular structure factors contributing to octane rating for hydrocarbon fuels. The kinetic model reproduces observed variations in critical compression ratio with fuel structure, and it also provides intermediate and final product species concentrations in much better agreement with observed results than has been possible previously. In addition, the computed results provide insights into the kinetic origins of fuel octane sensitivity.

AB - Autoignition of the five distinct isomers of hexane is studied experimentally under motored engine conditions and computationally using a detailed chemical kinetic reaction mechanism. Computed and experimental results are compared and used to help understand the chemical factors leading to engine knock in spark-ignited engines and the molecular structure factors contributing to octane rating for hydrocarbon fuels. The kinetic model reproduces observed variations in critical compression ratio with fuel structure, and it also provides intermediate and final product species concentrations in much better agreement with observed results than has been possible previously. In addition, the computed results provide insights into the kinetic origins of fuel octane sensitivity.

UR - https://www.scopus.com/pages/publications/85072436382

U2 - 10.4271/952406

DO - 10.4271/952406

M3 - Conference article

AN - SCOPUS:85072436382

SN - 0148-7191

JO - SAE Technical Papers

JF - SAE Technical Papers

Y2 - 16 October 1995 through 19 October 1995

ER -

Autoignition chemistry of the hexane isomers: An experimental and kinetic modeling study

Abstract

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