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Transient numerical modeling of carbon particle ignition and oxidation
Jerry C. Lee
,
Richard A. Yetter
, Frederick L. Dryer
Mechanical Engineering
Research output
:
Contribution to journal
›
Article
›
peer-review
72
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Scopus citations
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Dive into the research topics of 'Transient numerical modeling of carbon particle ignition and oxidation'. Together they form a unique fingerprint.
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Keyphrases
Small Particles
100%
Carbon Particles
100%
Particle Oxidation
100%
Particle Ignition
100%
Particle Surface
66%
Large Particle
66%
Boundary Layer
33%
Transport Properties
33%
Gasification
33%
Phase Boundary
33%
Kinetic Rate
33%
Gas Phase
33%
Reaction Mechanism
33%
Combustion Characteristics
33%
Heterogeneous Surface
33%
Liquid Droplet
33%
Surface Kinetics
33%
Spherically Symmetric
33%
Transient Behavior
33%
Chemically Reacting Flows
33%
Gas-phase Reactions
33%
Quasi-steady
33%
Five Steps
33%
Diffusion Limit
33%
Response Surface Regression
33%
Burning Characteristics
33%
Symmetric Systems
33%
Typical Behavior
33%
CO Oxidation
33%
Gas-phase Oxidation
33%
Reactive Gas
33%
Engineering
Transients
100%
Numerical Modeling
100%
Ignition
100%
Gas-Phase
75%
Particle Surface
50%
Gasification
25%
Phase Boundary
25%
Flow Field
25%
Surface Kinetics
25%
Boundary Layer
25%
Characteristic Time
25%
Size Range
25%
Reacting Flow
25%
Phase Reaction
25%
Liquid Droplet
25%
Symmetric System
25%
Physics
Transients
100%
Vapor Phase
50%
Flow Distribution
25%
Transport Property
25%
Gas Phase Reaction
25%
Boundary Layer
25%
Reacting Flow
25%
Material Science
Oxidation Reaction
100%
Carbon Particle
100%
Boundary Layer
33%