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Wave propagation in gaseous small-scale channel flows
J. M. Austin,
D. J. Bodony
Grainger College of Engineering
Aerospace Engineering
Mechanical Science and Engineering
Materials Research Lab
National Center for Supercomputing Applications (NCSA)
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Dive into the research topics of 'Wave propagation in gaseous small-scale channel flows'. Together they form a unique fingerprint.
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Keyphrases
Wave Propagation
100%
Attenuation
100%
Viscous Effects
100%
Velocity Measurement
100%
Channel Flow
100%
Low Pressure
50%
Divergence
50%
Compressible Flow
50%
Existing Data
50%
Boundary Layer
50%
Numerical Model
50%
Pressure Profile
50%
Time Pressure
50%
Wave Velocity
50%
Pressure Rise
50%
Circular Cross-section
50%
Mm-scale
50%
Stream Tube
50%
Wave Front Velocity
50%
Initialization Shock
50%
Entrance Effect
50%
Shock Attenuation
50%
Transition Model
50%
Boundary Layer Behavior
50%
Boundary Layer Transition
50%
Engineering
Boundary Layer
100%
Channel Flow
100%
Compressible Flow
50%
Wave Velocity
50%
Numerical Model
50%
Model Problem
50%
Circular Cross Section
50%
Pressure Profile
50%
Pressure Rise
50%
Streamtubes
50%
Initial Shock
50%
Boundary Layer Transition
50%
Entrance Effect
50%
Earth and Planetary Sciences
Diffraction
100%
Velocity Measurement
100%
Boundary Layer
100%
Channel Flow
100%
Wave Velocity
50%
Shock Wave
50%
Numerical Model
50%
Wave Front
50%
Compressible Flow
50%
Boundary Layer Transition
50%
Physics
Wave Propagation
100%
Velocity Measurement
100%
Boundary Layer
100%
Channel Flow
100%
Shock Wave
50%
Wave Front
50%
Wave Velocity
50%
Numerical Model
50%
Boundary Layer Transition
50%
Compressible Flow
50%