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Role of low-temperature chemistry in detonation of n-heptane/oxygen/diluent mixtures
Wenkai Liang
, Rémy Mével
,
Chung K. Law
Mechanical & Aerospace Engineering
High Meadows Environmental Institute
Princeton Materials Institute
Research output
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Contribution to conference
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peer-review
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Dive into the research topics of 'Role of low-temperature chemistry in detonation of n-heptane/oxygen/diluent mixtures'. Together they form a unique fingerprint.
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Keyphrases
Heptane
100%
Detonation
100%
Low-temperature Chemistry
100%
Diluents Mixture
100%
Negative Reactivity
100%
Numerical Simulation
50%
Low Temperature
50%
High Mach number
50%
Cell Size
50%
Increased Temperature
50%
Negative Temperature Coefficient
50%
Shock Waves
50%
Energy Release
50%
Detailed Chemistry
50%
Temperature Decrease
50%
First-stage Ignition
50%
Exothermicity
50%
High-temperature Chemistry
50%
Induction Length
50%
Shock Temperature
50%
Detonation Structure
50%
Engineering
Low-Temperature
100%
Heptane
100%
Length Scale
66%
Ignition
33%
Computer Simulation
33%
Dilution
33%
Increasing Temperature
33%
Temperature Coefficient
33%
Energy Release
33%
High Mach Number
33%