Call for Papers
1. Acoustics
1.0 Acoustics: General
1.1 Acoustics: Aeroacoustics
1.2 Acoustics: Hydroacoustics
1.3 Acoustics: Thermoacoustics
2. Aerodynamics
2.0 Aerodynamics: General
2.1 Aerodynamics: Control
2.2 Aerodynamics: Fixed, Flapping and Rotating Wings
2.3 Aerodynamics: Fluid-Structure Interactions, Membranes, Flutter
2.4 Aerodynamics: Theory
2.5 Aerodynamics: Vehicles
2.6 Aerodynamics: Wind Energy
3. Astrophysical Fluid Dynamics
3.0 Astrophysical Fluid Dynamics
4. Biological Fluid Dynamics
4.0 Biological Fluid Dynamics: General
4.1 Biological Fluid Dynamics: Biofilms
4.2 Biological Fluid Dynamics: Collective Behavior and Active Matter
4.3 Biological Fluid Dynamics: Flying
4.3.1 Biological Fluid Dynamics: Flying Birds
4.3.2 Biological Fluid Dynamics: Flying Insects
4.4 Biological Fluid Dynamics: Single Cells and Bacteria
4.5 Biological Fluid Dynamics: Locomotion
4.5.1 Biological Fluid Dynamics: Locomotion, High Reynolds Number Swimming
4.5.2 Biological Fluid Dynamics: Locomotion, Low Reynolds Number Swimming
4.5.3 Biological Fluid Dynamics: Locomotion, Cilia and Flagella
4.5.4 Biological Fluid Dynamics: Locomotion, Non-Newtonian Fluids
4.5.5 Biological Fluid Dynamics: Locomotion, Cells
4.6 Biological Fluid Dynamics: Medical Devices
4.7 Biological Fluid Dynamics: Plant Biomechanics
4.8 Biological Fluid Dynamics: Physiological
4.8.1 Biological Fluid Dynamics: Physiological, Cardiac Flows
4.8.2 Biological Fluid Dynamics: Physiological, Small Vessels and Microcirculation
4.8.3 Biological Fluid Dynamics: Physiological, Large Vessels and Arteries
4.8.4 Biological Fluid Dynamics: Physiological, Lymphatic and CSF Flows
4.8.5 Biological Fluid Dynamics: Physiological, Phonation and Speech
4.8.6 Biological Fluid Dynamics: Physiological, Respiratory Flows
4.9 Biological Fluid Dynamics: Vesicles and Micelles
5. Boundary Layers
5.0 Boundary Layers: General
5.1 Boundary Layers: Laminar
5.2 Boundary Layers: Thermal
5.3 Boundary Layers: Surface Effects, Features, Roughness
5.4 Boundary Layers: Turbulent
5.4.1 Boundary Layers: Turbulent, High Re Effects
5.4.2 Boundary Layers: Turbulent, Wall Modeling
5.4.3 Boundary Layers: Turbulent, Curvature and Pressure Gradient Effects
6. Bubbles
6.0 Bubbles: General
6.1 Bubbles: Biomedical, Cavitation and Acoustics
6.2 Bubbles: Cavitation, Nucleation, Collapse, Coalescence
6.3 Bubbles: Dynamics and Rupture
6.4 Bubbles: Growth, Heat Transfer and Boiling
6.5 Bubbles: Microbubbles and Nanobubbles
6.6 Bubbles: Surfactants and Foams
7. Compressible Flows
7.0 Compressible Flows: General
7.1 Compressible Flow: Instability and Turbulence
7.2 Compressible Flow: Shock Waves and Explosions
7.3 Compressible Flow: Shock-Boundary Layer Interactions
7.4 Compressible Flow: Supersonic and Hypersonic
8. Computational Fluid Dynamics
8.0 Computational Fluid Dynamics: General
8.1 Computational Fluid Dynamics: Algorithms
8.2 Computational Fluid Dynamics: Applications
8.3 Computational Fluid Dynamics: High Performance Computing
8.4 Computational Fluid Dynamics: Immersed Boundary Methods
8.5 Computational Fluid Dynamics: LES, DNS, Hybrid RANS/LES
8.6 Computational Fluid Dynamics: LBM, SPH, Mesh Free
8.7 Computational Fluid Dynamics: RANS Modeling
8.8 Computational Fluid Dynamics: Shock Capturing, DG, Higher Order Schemes
8.9 Computational Fluid Dynamics: Uncertainty Quantification
9. Convection and Buoyancy-Driven Flows
9.0 Convection and Buoyancy-Driven Flows: General
9.1 Convection and Buoyancy-Driven Flows: Binary Systems
9.2 Convection and Buoyancy-Driven Flows: Environmental
9.3 Convection and Buoyancy-Driven Flows: Free Convection and Rayleigh-Benard
9.4 Convection and Buoyancy-Driven Flows: Heat Transfer and Forced Convection
9.5 Convection and Buoyancy-Driven Flows: Particle Laden
9.6 Convection and Buoyancy-Driven Flows: Stratified Flow
9.7 Convection and Buoyancy-Driven Flows: Thermal Instability
9.8 Convection and Buoyancy-Driven Flows: Turbulent Convection
10. Drops
10.0 Drops: General
10.1 Drops: Coalescence
10.2 Drops: Complex Fluids
10.3 Drops: Dynamic Surface Interactions
10.4 Drops: Electric Field Effects
10.5 Drops: Heat Transfer, Evaporation and Buoyancy Effects
10.6 Drops: Impact, Bouncing, Wetting and Spreading
10.7 Drops: Interaction with Elastic Surfaces, Particles and Fibers
10.8 Drops: Instability and Break-up
10.9 Drops: Multiple Drop Interactions
10.10 Drops: Levitation
10.11 Drops: Particle Laden
10.12 Drops: Sessile and Static Surface Interactions
10.13 Drops: Superhydrophobic Surfaces
11. Electrokinetic Flows
11.0 Electrokinetic Flows: General
11.1 Electrokinetic Flows: Electric Double Layers
11.2 Electrokinetic Flows: Ion-Selective Interfaces
11.3 Electrokinetic Flows: Induced-Charge Flows and Nonlinear Dynamics
11.4 Electrokinetic Flows: Nanochannels and Surface Conduction
11.5 Electrokinetic Flows: Preconcentration, Separations and Reactions
12. Energy
12.0 Energy: General
12.1 Energy: Combustion
12.2 Energy: Storage
12.3 Energy: Water Power
12.4 Energy: Wind Power
13. Experimental Techniques
13.0 Experimental Techniques: General
13.1 Experimental Techniques: Aerodynamics/Wind Tunnel
13.2 Experimental Techniques: Data Analysis, Bias and Uncertainty
13.3 Experimental Techniques: Quantitative Flow Visualization. PIV, PTV, PLIF
13.4 Experimental Techniques: High-Speed Flow
13.5 Experimental Techniques: Microscale Flow
13.6 Experimental Techniques: Multiphase Flow
13.7 Experimental Techniques: Laser-Based Diagnostics
13.8 Experimental Techniques: Pressure/Temperature Scalar Surface visualization
13.9 Experimental Techniques: Reacting Flow and Spectroscopy
14. Free-Surface Flows
14.0 Free-Surface Flows: General
14.1 Free-Surface Flows: Instability
14.2 Free-Surface Flows: Interaction with Structures
14.3 Free-Surface Flows: Mixing
14.4 Free-Surface Flows: Turbulence
14.5 Free-Surface Flows: Waves
15. Flow Control
15.0 Flow Control: General
15.1 Flow Control: Actuator Design and Analysis
15.2 Flow Control: Coherent Structures, Vortices and Turbulence
15.3 Flow Control: Drag Reduction
15.4 Flow Control: Passive
15.5 Flow Control: Plasma Actuators
15.6 Flow Control: Separation
15.7 Flow Control: Theory
16. Flow Instability
16.0 Flow Instability: General
16.1 Flow Instability: Boundary Layers and Transition
16.2 Flow Instability: Control
16.3 Flow Instability: Complex Fluids
16.4 Flow Instability: Geophysical
16.5 Flow Instability: Global Modes
16.6 Flow Instability: Interfacial and Thin Film
16.7 Flow Instability: Kelvin-Helmholtz
16.8 Flow Instability: Multiphase Flow
16.9 Flow Instability: Nonlinear Dynamics
16.10 Flow Instability: Pulsating Flows
16.11 Flow Instability: Rayleigh-Taylor
16.12 Flow Instability: Richtmyer-Meshkov
16.13 Flow Instability: Theory
16.14 Flow Instability: Transition to Turbulence
16.15 Flow Instability: Vortex-Dominated Flows
16.16 Flow Instability: Wakes
17. General Fluid Dynamics
17.0 General Fluid Dynamics: General
17.1 General Fluid Dynamics: Drag Reduction
17.2 General Fluid Dynamics: Multi-Physics Phenomena
17.3 General Fluid Dynamics: Obstacles, Flow Constrictions
17.4 General Fluid Dynamics: Rotating Flows
17.5 General Fluid Dynamics: Theory and Mathematical Methods
17.6 General Fluid Dynamics: Viscous Flows
18. Geophysical Fluid Dynamics
18.0 Geophysical Fluid Dynamics: General
18.1 Geophysical Fluid Dynamics: Atmospheric
18.2 Geophysical Fluid Dynamics: Air-Sea Interaction
18.3 Geophysical Fluid Dynamics: Climate
18.4 Geophysical Fluid Dynamics: Cryosphere
18.5 Geophysical Fluid Dynamics: Mesoscale Dynamics, Transport and Mixing
18.6 Geophysical Fluid Dynamics: Oceanographic
18.7 Geophysical Fluid Dynamics: Rotating Flows
18.8 Geophysical Fluid Dynamics: Sediment Transport
18.9 Geophysical Fluid Dynamics: Stratified Flows
19. Granular Flows
19.0 Granular Flows: General
19.1 Granular Flows: Applications
19.2 Granular Flows: Fluctuations and Instabilities
19.3 Granular Flows: Impact and Force Transmission
19.4 Granular Flows: Locomotion and Drag
19.5 Granular Flows: Mixing and Blending, Segregation and Separation
20. Industrial Applications
20.0 Industrial Applications: General
21. Jets
21.0 Jets: General
21.1 Jets: Control
21.2 Jets: Impinging
21.3 Jets: Swirling
22. Magnetohydrodynamics
22.0 Magnetohydrodynamics: General
23. Microscale and Nanoscale Flows
23.0 Microscale and Nanoscale Flows: General
23.1 Microscale and Nanoscale Flows: Devices and Applications
23.2 Microscale and Nanoscale Flows: Electrokinetics
23.3 Microscale and Nanoscale Flows: Interfaces, Wetting, Emulsions
23.4 Microscale and Nanoscale Flows: Mixing and Separation
23.4.1 Microscale and Nanoscale Flows: Mixing and Separation, Chemical/Biochemical Analysis, µTAS
23.4.2 Microscale and Nanoscale Flows: Mixing and Separation, Instability
23.4.3 Microscale and Nanoscale Flows: Mixing and Separation, Membranes
23.4.4 Microscale and Nanoscale Flows: Mixing and Separation, Reactions
23.5 Microscale and Nanoscale Flows: Non-Newtonian
23.6 Microscale and Nanoscale Flows: Opto/Electro/Magnetic Manipulation
23.7 Microscale and Nanoscale Flows: Oscillations and Streaming
23.8 Microscale and Nanoscale Flows: Particles, Drops, Bubbles
23.9 Microscale and Nanoscale Flows: Theory
24. Multiphase Flows
24.0 Multiphase Flows: General
24.1 Multiphase Flows: Atomization and Sprays
24.2 Multiphase Flows: Bubbly Flows
24.3 Multiphase Flows: Cavitation and Aerated Flows
24.4 Multiphase Flows: Computational Methods
24.5 Multiphase Flows: Modeling and Theory
24.6 Multiphase Flows: Particle-Laden Flows and Fluidization
24.7 Multiphase Flows: Turbulence
25. Nonlinear Dynamics
25.0 Nonlinear Dynamics: General
25.1 Nonlinear Dynamics: Bifurcations and Chaos
25.2 Nonlinear Dynamics: Coherent Structures
25.3 Nonlinear Dynamics: Model Reduction
25.4 Nonlinear Dynamics: Transition
25.5 Nonlinear Dynamics: Turbulence
26. Non-Newtonian Flows: General
26.0 Non-Newtonian Flows: General
26.1 Non-Newtonian Flows: Applications
26.2 Non-Newtonian Flows: Instability and Turbulence
26.3 Non-Newtonian Flows: Hydrodynamics
26.4 Non-Newtonian Flows: Rheology
26.5 Non-Newtonian Flows: Theory
27. Porous Media Flows
27.0 Porous Media Flows: General
27.1 Porous Media Flows: Applications
27.2 Porous Media Flows: Convection and Heat Transfer
27.3 Porous Media Flows: Immiscible Displacements
27.4 Porous Media Flows: Imbibition and Injection
27.5 Porous Media Flows: Mixing and Turbulence
27.6 Porous Media Flows: Theory
27.7 Porous Media Flows: Wicking and Drying
28. Particle-Laden Flows
28.0 Particle-Laden Flows: General
28.1 Particle-Laden Flows: Clustering
28.2 Particle-Laden Flows: Deformable Particles
28.3 Particle-Laden Flows: Experimental Techniques
28.4 Particle-Laden Flows: Modeling and Theory
28.5 Particle-Laden Flows: Non-Spherical Particles
28.6 Particle-Laden Flows: Particle-Resolved Simulations
28.7 Particle-Laden Flows: Particle-Turbulence Interactions
29. Rarefied Flows
29.0 Rarefied Flows: General
29.1 Rarefied Flows: DSMC
30. Reacting Flows
30.0 Reacting Flows: General
30.1 Reacting Flows: Computational Methods and Simulations
30.2 Reacting Flows: Chemical Kinetics
30.3. Reacting Flows: Detonations, Explosions and DDT
30.4 Reacting Flows: DNS
30.5 Reacting Flows: Extinction and Ignition
30.6 Reacting Flows: Instabilities
30.7 Reacting Flows: LES
30.8 Reacting Flows: Modeling, Theory, PDF and FDF
30.9 Reacting Flows: Sprays, Emissions and Soot
30.10 Reacting Flows: Turbulent Combustion
31. Separated Flows
31.0 Separated Flows: General
31.1 Separated Flows: Control
31.2 Separated Flows: Modeling and Theory
31.3 Separated Flows: Simulations
31.4 Separated Flows: Wakes
32. Suspensions
32.0 Suspensions: General
32.1 Suspensions: Confined Flows
32.2 Suspensions: Fluid-Particle Interaction
32.3 Suspensions: Instability
32.4 Suspensions: Modeling and Theory
32.5 Suspensions: Particle-Resolved Simulations
32.6 Suspensions: Rheology
32.7 Suspensions: Structure and Phase Transitions
33. Surface Tension Effects
33.0 Surface Tension Effects: General
33.1 Surface Tension Effects: Particle-Particle Interactions
33.2 Surface Tension Effects: Interfacial Phenomena
33.3 Surface Tension Effects: Textured Substrates
34. Superfluids
34.0 Superfluids: General
34.1 Superfluids: Vortex Dynamics
35. Turbulence
35.0 Turbulence: General
35.1 Turbulence: Boundary Layers
35.2 Turbulence: Buoyancy-Driven
35.3 Turbulence: Compressible
35.4 Turbulence: DNS
35.5 Turbulence: Environmental
35.6 Turbulence: Jets
35.7 Turbulence: LES
35.8 Turbulence: Measurements
35.9 Turbulence: Modeling
35.10 Turbulence: Mixing
35.11 Turbulence: Multiphase
35.12 Turbulence: Particle-Laden
35.13 Turbulence: Planetary Boundary Layer
35.14 Turbulence: Stratification, Rotation and Magnetic Fields
35.15 Turbulence: Theory
35.16 Turbulence: Shear Layers
35.17 Turbulence: Wakes
35.18 Turbulence: Wall-Bounded
36. Vortex Dynamics and Vortex Flows
36.0 Vortex Dynamics and Vortex Flows: General
36.1 Vortex Dynamics and Vortex Flows: Astrophysical/Geophysical
36.2 Vortex Dynamics and Vortex Flows: Instability
36.3 Vortex Dynamics and Vortex Flows: Propulsion
36.4 Vortex Dynamics and Vortex Flows: Simulations
36.5 Vortex Dynamics and Vortex Flows: Theory
36.6 Vortex Dynamics and Vortex Flows: Turbulence
36.7 Vortex Dynamics and Vortex Flows: Wakes
37. Waves
37.0 Waves: General
37.1 Waves: Surface Waves
37.2 Waves: Internal and Interfacial Waves
37.3 Waves: Nonlinear Dynamics and Turbulence
