Skip to main navigation
Skip to search
Skip to main content
Welcome to DTU Research Database Home
About DTU Orbit
Home
Profiles
Research units
Publications
Activities
Projects
Prizes
Press/Media
Datasets
Search by expertise, name or affiliation
Physics of microparticle acoustophoresis: Bridging theory and experiment
Rune Barnkob
Department of Physics
Biophysics and Fluids
Research output
:
Book/Report
›
Ph.D. thesis
Overview
Fingerprint
Projects
(1)
Fingerprint
Dive into the research topics of 'Physics of microparticle acoustophoresis: Bridging theory and experiment'. Together they form a unique fingerprint.
Sort by
Weight
Alphabetically
Engineering
Bridging
100%
Microparticles
100%
Particle Velocity
50%
Acoustic Energy
37%
Actuation
37%
Energy Density
37%
Model System
25%
Numerical Scheme
25%
Microchannel
25%
Experimental Model
25%
Compressibility
25%
Similarities
12%
Good Agreement
12%
Quantitative Measurement
12%
Numerical Prediction
12%
Key Parameter
12%
Experimental Platform
12%
Spatial Position
12%
Microsystem
12%
Size of Particle
12%
Drag Force
12%
Voltage Driving
12%
Particle Separation
12%
Channel Geometry
12%
Induced Force
12%
Transients
12%
Harmonics
12%
Hydrodynamics
12%
Standing Wave
12%
Resonator
12%
Particle Trajectory
12%
Acoustic Resonance
12%
Physics
Physics
100%
Microparticles
100%
Particle Motion
50%
Acoustic Streaming
50%
Sound Wave
37%
Flux Density
37%
Acoustic Property
25%
Compressibility
25%
Resonator
12%
Standing Wave
12%
Transients
12%
Luminous Intensity
12%
Harmonics
12%
Velocity Measurement
12%
Particle Trajectory
12%
Temperature Control
12%
Acoustic Resonance
12%
Material Science
Microparticle
100%
Particle Motion
44%
Energy Density
33%
Density
22%
Acoustic Property
22%
Compressibility
22%
Particle Imaging
11%
Hydrodynamics
11%
Resonator
11%
Keyphrases
Bridging Theory
100%
Future Advancements
11%
Ultrasound Standing Wave
11%
Particle Depletion
11%
Micro-PTV
11%
Hydrodynamic Calculation
11%
Subject Particle
11%
Acoustic Actuation
11%
Particle Imaging Velocimetry
11%