A stream of water droplets falling from a tap appears frozen or to move in slow motion when illuminated by a strobe light. Adjusting the strobe frequency reveals the apparent stillness, upward motion, or slow fall of the drops.

1. Darken the room and set up a dripping faucet so water drops fall steadily.
2. Position a strobe light to shine directly on the drops.
3. Adjust the strobe frequency until the drops appear stationary in midair.
4. Change the strobe frequency slightly higher or lower:
   1. Drops may appear to fall slowly.
   2. Drops may appear to rise upward against gravity.
5. Observe and discuss how the effect is created by synchronization between the drop frequency and strobe flashes.

The Stroboscopic Effect with Water Drops | Science Project - Science Buddies:

• Try dripping water into a glass or bowl to create ripples visible under the strobe.
• Compare fast vs slow dripping rates by adjusting the faucet.
• Use food coloring in the water for clearer visibility.
• Record the effect with a camera for comparison with real slow-motion video.

• Avoid staring directly into the strobe light—short demonstrations only.
• Be aware that strobe lights can trigger seizures in people with photosensitive epilepsy.
• Clean up spilled water to prevent slipping.

• Why do the water drops appear frozen in place? (Because the strobe flashes at the same frequency as the drip rate, making each drop appear in the same position.)
• Why can drops seem to rise upward? (If the strobe frequency is slightly slower than the drip frequency, each flash captures the drop a bit lower, creating the illusion of upward motion.)
• How is this effect similar to what happens with wagon wheels in movies appearing to spin backwards? (Both are stroboscopic effects caused by sampling motion at discrete time intervals.)
• What real-world applications use stroboscopic effects? (Measuring vibrations, observing machinery, and studying fast periodic motion.)