#worthingtonjet — Public Fediverse posts

When a drop or object hits water, a narrow high-speed jet can shoot upward: the Worthington jet. This study reveals universal scaling laws that govern how these jets form and evolve across different impact conditions.

🔗 https://journals.aps.org/prfluids/abstract/10.1103/2vdb-tqj6

#FluidDynamics #DropImpact #WorthingtonJet #Physics #InterfacialFlows

When a drop or object hits water, a narrow high-speed jet can shoot upward: the Worthington jet. This study reveals universal scaling laws that govern how these jets form and evolve across different impact conditions.

🔗 https://journals.aps.org/prfluids/abstract/10.1103/2vdb-tqj6

#FluidDynamics #DropImpact #WorthingtonJet #Physics #InterfacialFlows

When a drop or object hits water, a narrow high-speed jet can shoot upward: the Worthington jet. This study reveals universal scaling laws that govern how these jets form and evolve across different impact conditions.

🔗 https://journals.aps.org/prfluids/abstract/10.1103/2vdb-tqj6

#FluidDynamics #DropImpact #WorthingtonJet #Physics #InterfacialFlows

When a drop or object hits water, a narrow high-speed jet can shoot upward: the Worthington jet. This study reveals universal scaling laws that govern how these jets form and evolve across different impact conditions.

🔗 https://journals.aps.org/prfluids/abstract/10.1103/2vdb-tqj6

#FluidDynamics #DropImpact #WorthingtonJet #Physics #InterfacialFlows

When a drop or object hits water, a narrow high-speed jet can shoot upward: the Worthington jet. This study reveals universal scaling laws that govern how these jets form and evolve across different impact conditions.

🔗 https://journals.aps.org/prfluids/abstract/10.1103/2vdb-tqj6

#FluidDynamics #DropImpact #WorthingtonJet #Physics #InterfacialFlows

Oil-Slicked Bubble Bursts

When bubbles at the surface of the ocean pop, they can send up a spray of tiny droplets that carry salt, biomass, microplastics, and other contaminants into the atmosphere. Teratons of such materials enter the atmosphere from the ocean each year. To better understand how contaminants can cross from the ocean to the atmosphere, researchers studied what happens when a oil-coated water bubble pops.

The team looked at bubbles about 2 millimeters across, coated in varying amounts of oil, and observed their demise via high-speed video. When the bubble pops, capillary waves ripple down into its crater-like cavity and meet at the bottom. That collision creates a rebounding Worthington jet, like the one above, which can eject droplets from its tip.

The team found that the oil layer’s thickness affected the capillary waves and changed the width of the resulting jet. They were able to build a mathematical model that predicts how wide a jet will be, though a prediction of the jet’s velocity is still a work-in-progress. (Image credit: Р. Морозов; research credit: Z. Yang et al.; via APS)

#bubbles #capillaryWaves #contamination #fluidDynamics #physics #science #WorthingtonJet

Manu Jumping, a.k.a. How to Make a Big Splash

The Māori people of Aotearoa New Zealand compete in manu jumping to create the biggest splash. Here’s a fun example. In this video, researchers break down the physics of the move and how it creates an enormous splash. There are two main components — the V-shaped tuck and the underwater motion. At impact, jumpers use a relatively tight V-shape; the researchers found that a 45-degree angle works well at high impact speeds. This initiates the jumper’s cavity. Then, as they descend, the jumper unfolds, using their upper body to tear open a larger underwater cavity, which increases the size of the rebounding jet that forms the splash. To really maximize the splash, jumpers can aim to have their cavity pinch-off (or close) as deep underwater as possible. (Video and image credit: P. Rohilla et al.)

#2024gofm #diving #flowVisualization #fluidDynamics #manuJumping #physics #science #splashes #sports #WorthingtonJet

Since Harold Edgerton’s experiments with stroboscopic photographs in the 1930s, we’ve been fascinated by the shape of splashes. These days students and artists can take advantage of programmable external flashes to capture this split-second moment of impact. Here, a pink-dyed drop of ethanol strikes a jet rising from a pool of glycerin, milk, and food coloring. The resulting splash is umbrella-like, with a thickened rim that shows tiny ligaments of fluid — an early sign of the instability that will ultimately detach droplets from the splash. This image was taken by students in a course that connects art and fluid mechanics. (Image credit: L. Sharpe et al.; via Physics Today)

https://fyfluiddynamics.com/2024/07/making-a-splash/

#crownSplash #fluidDynamics #fluidsAsArt #instability #physics #science #splashes #WorthingtonJet

Since Harold Edgerton’s experiments with stroboscopic photographs in the 1930s, we’ve been fascinated by the shape of splashes. These days students and artists can take advantage of programmable external flashes to capture this split-second moment of impact. Here, a pink-dyed drop of ethanol strikes a jet rising from a pool of glycerin, milk, and food coloring. The resulting splash is umbrella-like, with a thickened rim that shows tiny ligaments of fluid — an early sign of the instability that will ultimately detach droplets from the splash. This image was taken by students in a course that connects art and fluid mechanics. (Image credit: L. Sharpe et al.; via Physics Today)

https://fyfluiddynamics.com/2024/07/making-a-splash/

#crownSplash #fluidDynamics #fluidsAsArt #instability #physics #science #splashes #WorthingtonJet