The image I took was of green dyed water being poured over a candle topper. The phenomena I was trying to target was a pressure differential that occurs as the water is sucked into the tiny hole. This can be explained by Bernoulli’s Principle in which various elements including pressured differential are formed into an equation.
Team First: Pressure Differential – Cooper Lay
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Flow Vis Guidebook
- Introduction to the Guidebook
- Overview 1: Phenomena. Why Does It Look Like That?
- Overview 2: Visualization Techniques
- Overview 3: Lighting
- Overview 4 - Photography A: Composition and Studio Workflow
- Overview 4 - Photography B: Cameras
- Overview 4 - Photography C: Lenses - Focal Length
- Overview 4 - Photography C: Lenses - Aperture and DOF
- Overview 4: Photography D: Exposure
- Overview 4 - Photography E - Resolution
- Overview 5 - Post-Processing
- Clouds 1: Names
- Clouds 2: Why Are There Clouds? Lift Mechanism 1: Instability
- Clouds 3: Skew - T and Instability
- Clouds 4: Clouds in Unstable Atmosphere
- Clouds 5: Lift Mechanism 2 - Orographics
- Clouds 6: Lift Mechanism 3 - Weather Systems
- Boundary Techniques - Introduction
- Dye Techniques 1 - Do Not Disturb
- Dye Techniques 2 - High Visibility
- Dye Techniques 3 - Light Emitting Fluids
- Refractive Index Techniques 1: Liquid Surfaces
- Refractive Index Techniques 2: Shadowgraphy and Schlieren
- Particle Physics: Flow and Light
- Particles 2: Aerosols
- Art and Science
- TOC and Zotpress test
- Photons, Wavelength and Color
2 Comments. Leave new
I like how you captured the surface tension in the green droplets. Its cool to see how you poured a set amount of liquid and this is the shapes they happened to form into!
I like your picture! Blur was well incorporated and the coloring works well. Though without the background description as context it’s hard to tell what phenomenon you were trying to capture. I may suggest cropping to focus on the area of pressure differential by the hole?