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Drag and lift in nonadiabatic transonic flow
Günter H. Schnerr
, Ulrich Dohrmann
University of Karlsruhe
Research output
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Contribution to journal
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Article
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peer-review
46
Scopus citations
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Keyphrases
Non-adiabatic
100%
Transonic Flow
100%
Pressure Drag
100%
Atmospheric Flight
100%
Condensation
66%
Internal Flow
66%
Vapor Quality
66%
Equilibrium Processes
66%
Low Altitude
33%
Non-equilibrium
33%
Numerical Calculation
33%
Growth Law
33%
Finite Volume Method
33%
Condensation Process
33%
Angle of Attack
33%
Explicit Time
33%
Reservoir Conditions
33%
Diabatic
33%
Pressure-temperature
33%
Supersaturation
33%
Phase Transition Process
33%
Homogeneous nucleation
33%
Gas Dynamics
33%
Normal Shock
33%
Airfoil
33%
Heat Addition
33%
Homogeneous Equilibrium Model
33%
Euler Equations
33%
Phase Change Process
33%
Carrier Gas
33%
Turbomachinery
33%
Inert Carrier
33%
Nonequilibrium Phase Transitions
33%
Stationary Flow
33%
Classical nucleation Theory
33%
Droplet Growth
33%
Homogeneous Condensation
33%
Drag Increase
33%
Non-equilibrium Condensation
33%
Transonic Wind Tunnel
33%
Engineering
Transonic Flow
100%
Nonequilibrium
100%
Pressure Drag
100%
Equilibrium Process
66%
Internal Flow
66%
Numerical Calculation
33%
Turbomachinery
33%
Angle-of-Attack
33%
Finite Volume Method
33%
Reservoir Condition
33%
Homogeneous Nucleation
33%
Phase-Change Process
33%
Carrier Gas
33%
Limiting Case
33%
Classical Nucleation Theory
33%
Condensation Process
33%
Droplet Growth
33%
Heat Addition
33%
Airfoil
33%
Supersaturation
33%
Euler Equation
33%