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39. MINISYMPOSIA (By Invitation Only)
40. FOCUS SESSIONS
41. Fluid Dynamics – Education, Outreach and Diversity
42. Fluid Dynamics – Student Poster Competition
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: General
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
12.4.1 Energy: Wind Power: Modeling
12.4.2 Energy: Wind Power: Wakes, Control and Fluctuation
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
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: Turbulence
14.4 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
15.3.1 Flow Control: Drag Reduction: Superhydrophobic and Wetting Treatments
15.3.2 Flow Control: Drag Reduction: Structured Surfaces
15.4 Flow Control: Passive
15.5 Flow Control: Separation
15.6 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: Locomotion and Drag
19.4 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. Low-Order Modeling and Machine Learning in Fluid Dynamics
22.0 Low-Order Modeling and Machine Learning in Fluid Dynamics: General
22.1 Low-Order Modeling and Machine Learning in Fluid Dynamics: Methods
22.2 Low-Order Modeling and Machine Learning in Fluid Dynamics: Turbulence Modeling
22.3 Low-Order Modeling and Machine Learning in Fluid Dynamics: Flow Control
22.4 Low-Order Modeling and Machine Learning in Fluid Dynamics: Design
22.5 Low-Order Modeling and Machine Learning in Fluid Dynamics: Other Applications
23. Magnetohydrodynamics
23.0 Magnetohydrodynamics: General
24. Microscale and Nanoscale Flows
24.0 Microscale and Nanoscale Flows: General
24.1 Microscale and Nanoscale Flows: Devices and Applications
24.2 Microscale and Nanoscale Flows: Electrokinetics
24.3 Microscale and Nanoscale Flows: Interfaces, Wetting, Emulsions
24.4 Microscale and Nanoscale Flows: Mixing and Separation
24.5 Microscale and Nanoscale Flows: Non-Newtonian
24.6 Microscale and Nanoscale Flows: Opto/Electro/Magnetic Manipulation
24.7 Microscale and Nanoscale Flows: Oscillations and Streaming
24.8 Microscale and Nanoscale Flows: Particles, Drops, Bubbles
24.9 Microscale and Nanoscale Flows: Theory
25. Multiphase Flows
25.0 Multiphase Flows: General
25.1 Multiphase Flows: Atomization and Sprays
25.2 Multiphase Flows: Bubbly Flows
25.3 Multiphase Flows: Cavitation and Aerated Flows
25.4 Multiphase Flows: Computational Methods
25.5 Multiphase Flows: Modeling and Theory
25.6 Multiphase Flows: Particle-Laden Flows and Fluidization
25.7 Multiphase Flows: Turbulence
26. Nonlinear Dynamics
26.0 Nonlinear Dynamics: General
26.1 Nonlinear Dynamics: Bifurcations and Chaos
26.2 Nonlinear Dynamics: Coherent Structures
26.3 Nonlinear Dynamics: Model Reduction
26.4 Nonlinear Dynamics: Transition
26.5 Nonlinear Dynamics: Turbulence
27. Non-Newtonian Flows: General
27.0 Non-Newtonian Flows: General
27.1 Non-Newtonian Flows: Applications
27.2 Non-Newtonian Flows: Instability and Turbulence
27.3 Non-Newtonian Flows: Hydrodynamics
27.4 Non-Newtonian Flows: Rheology
27.5 Non-Newtonian Flows: Theory
28. Porous Media Flows
28.0 Porous Media Flows: General
28.1 Porous Media Flows: Applications
28.2 Porous Media Flows: Convection and Heat Transfer
28.3 Porous Media Flows: Immiscible Displacements
28.5 Porous Media Flows: Mixing and Turbulence
28.6 Porous Media Flows: Theory
28.7 Porous Media Flows: Wicking and Drying
29. Particle-Laden Flows
29.0 Particle-Laden Flows: General
29.1 Particle-Laden Flows: Clustering
29.2 Particle-Laden Flows: Deformable Particles
29.3 Particle-Laden Flows: Experimental Techniques
29.4 Particle-Laden Flows: Modeling and Theory
29.5 Particle-Laden Flows: Non-Spherical Particles
29.6 Particle-Laden Flows: Particle-Resolved Simulations
29.7 Particle-Laden Flows: Particle-Turbulence Interactions
30. Rarefied Flows
30.0 Rarefied Flows: General
30.1 Rarefied Flows: DSMC
31. Reacting Flows
31.0 Reacting Flows: General
31.1 Reacting Flows: Computational Methods and Simulations
31.2 Reacting Flows: Chemical Kinetics
31.3. Reacting Flows: Detonations, Explosions and DDT
31.4 Reacting Flows: DNS
31.5 Reacting Flows: Extinction and Ignition
31.6 Reacting Flows: Instabilities
31.7 Reacting Flows: LES
31.8 Reacting Flows: Modeling, Theory, PDF and FDF
31.9 Reacting Flows: Sprays, Emissions and Soot
31.10 Reacting Flows: Turbulent Combustion
32. Separated Flows
32.0 Separated Flows: General
32.1 Separated Flows: Control
32.2 Separated Flows: Modeling and Theory
32.3 Separated Flows: Simulations
32.4 Separated Flows: Wakes
33. Suspensions
33.0 Suspensions: General
33.1 Suspensions: Confined Flows
33.2 Suspensions: Fluid-Particle Interaction
33.3 Suspensions: Instability
33.4 Suspensions: Modeling and Theory
33.5 Suspensions: Particle-Resolved Simulations
33.6 Suspensions: Rheology
33.7 Suspensions: Structure and Phase Transitions
34. Surface Tension Effects
34.0 Surface Tension Effects: General
34.1 Surface Tension Effects: Particle-Particle Interactions
34.2 Surface Tension Effects: Interfacial Phenomena
34.3 Surface Tension Effects: Textured Substrates
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
38. Quantum Computing for Fluids
38.0 Quantum Computing for Fluids: General
39. MINISYMPOSIA (By Invitation Only)
39.0 The Stories of Women in Fluids
39.1 Low Prandtl Number Dynamics in Stellar and Planetary Interiors
39.2 Intra-Ventricular Fluid Mechanics in Heart Failure
39.3 Fluid Dynamics in Clinical Imaging
40. FOCUS SESSIONS
40.0 Culinary Fluid Dynamics
40.1 Fluid Dynamics of Injury
40.2 Chaotic Flows in Polymeric Solutions
41. Fluid Dynamics – Education, Outreach and Diversity
41.0 Fluid Dynamics – Education and Outreach