Transient chemical composition analysis in HCCI of n-heptane fuel

Keyphrases

• Heptane 100%
• Chemical Composition Analysis 100%
• Fuel Consumption 75%
• Transient Species 50%
• Heat Release 50%
• Dimethyl Ether 25%
• Crank Angle 25%
• Angle-resolved 25%
• Formaldehyde 25%
• Aldehydes 25%
• Olefins 25%
• Formic Acid 25%
• Low Temperature 25%
• Methanol 25%
• Oxides 25%
• Hydrogen Peroxide 25%
• Ethylene 25%
• Mass Spectrometry 25%
• Two-species 25%
• Product Yield 25%
• Exhaust Gas Analysis 25%
• Chain Reaction Mechanism 25%
• Compression Ignition 25%
• Ignition Stages 25%
• Primary Reference Fuel 25%
• Fourier Transform Infrared Spectrometer 25%
• Engine Cylinder 25%
• Fuel Quantity 25%
• Two-stage Ignition 25%
• Chemical Mechanism 25%
• Fuel Combustion 25%
• Equivalence Ratio 25%
• High-temperature Ignition 25%
• Mass Spectrometry Detection 25%
• Homogeneous Chemical Reaction 25%
• Fuel Products 25%
• Detailed Chemical Kinetics 25%
• Numerical Prediction 25%
• Low Temperature Ignition 25%
• Single Cylinder Engine 25%

Engineering

• Transients 100%
• Ignition 100%
• Heptane 100%
• Low-Temperature 66%
• Heat Release 66%
• Engine Cylinders 66%
• Crank Angle 33%
• Single Cylinder 33%
• Alkene 33%
• Compression Ignition 33%
• Chain Reaction 33%
• Kinetic Model 33%
• Reference Fuel 33%
• Fourier Transform Infrared Spectrometer 33%
• Chemical Mechanism 33%
• Equivalence Ratio 33%
• Product Yield 33%
• N-Heptane 33%
• Numerical Prediction 33%
• Exhaust Gas 33%

Chemical Engineering

• Heptane 100%
• Olefin 33%
• Formic Acid 33%
• Methanol 33%
• Hydrogen Peroxide 33%
• Mass Spectrometry 33%
• Ethylene 33%
• Chemical Kinetics Characteristics 33%