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Approaches to mechanism reduction for hydrocarbon oxidation: Ethylene
Tianfeng Lu,
Chung King Law
Mechanical & Aerospace Engineering
High Meadows Environmental Institute
Princeton Materials Institute
Research output
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Contribution to conference
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Paper
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peer-review
1
Scopus citations
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Dive into the research topics of 'Approaches to mechanism reduction for hydrocarbon oxidation: Ethylene'. Together they form a unique fingerprint.
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Keyphrases
Hydrocarbon Oxidation
100%
Ethylene
100%
Mechanism Reduction
100%
Skeletal Mechanism
100%
Reduced Mechanism
75%
Detailed Mechanism
50%
Elementary Reaction
50%
High-temperature Chemistry
50%
Laminar Flame Speed
25%
Directed Relation Graph
25%
Computational Singular Perturbation
25%
Nonpremixed Counterflow
25%
Oxidation Mechanism
25%
Pressure-temperature
25%
Equivalence Ratio
25%
Counterflow Combustion
25%
Quasi-steady State
25%
Pressure Ratio
25%
Global Reaction
25%
Autoignition Delay Times
25%
Ethylene Oxidation
25%
Temperature Ratio
25%
Subsequent Generations
25%
Moderately High Temperature
25%
Accuracy Requirements
25%
Engineering
Reduction Mechanism
100%
Elementary Reaction
100%
Ignition
50%
Systematic Approach
50%
Autoignition
50%
Equivalence Ratio
50%
Ignition Delay
50%
Quasi Steady State
50%
Pressure Ratio
50%