Visualizing turbulence

The motion is linear and simple.

The motion is too slow to observe.

The motion is too predictable.

The motion is chaotic and complex.

A stable doughnut-shaped region of fluid.

A flat circular motion of particles.

A linear flow of water.

A chaotic swirl of air.

Turbulence is confined to distinct layers.

Turbulence is smooth and predictable.

Turbulence is a type of laminar flow.

Turbulence involves chaotic and swirling eddies.

Describing the motion of solid objects.

Calculating the speed of light.

Predicting the behavior of gases only.

Describing fluid dynamics.

It is unrelated to fluid dynamics.

It is easy to solve.

It is predictable and linear.

It involves chaotic and complex patterns.

Energy is not present in turbulent flow.

Energy cascades from large to small scales.

Energy is evenly distributed across all scales.

Energy is only present at large scales.

A range of length scales where energy distribution is predictable.

A range where energy is absent.

A range where only large eddies exist.

A range where turbulence is not observed.

It describes the size of eddies.

It represents the speed of light.

It is a fundamental constant of turbulence.

It is unrelated to fluid dynamics.

A process where vortices shrink in size.

A process where vortices expand in two dimensions.

A process where rotating fluid stretches perpendicular to its rotation plane.

A process where fluid stops moving.

In 3D, energy is static.

In 2D, energy moves from small to large scales.

In 3D, energy moves from small to large scales.

In 2D, energy moves from large to small scales.