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Course: Exploratorium > Unit 2
Lesson 2: Soap Film on a Can- Introduction: Why do we see colors in oily water and soap bubbles?
- Create your soap film viewer: Materials, tools, and steps
- To do and notice: Horizontal bands of color
- What’s going on: Reflections, interference, and … a water sandwich?
- Soap Film on a Can: Complete activity guide
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Soap Film on a Can: Complete activity guide
Why do we see colors in oily water and soap bubbles? Sometimes we see red, sometimes blue, and sometimes it appears as though we see nothing at all. Experiment with soap film to observe the behavior and colorful appearance of different wavelengths of light.
Tools & Materials
- One film can made of black plastic (or try making your own!)
- Dishwashing liquid—Dawn™ Ultra Original Scent in blue works best
- Water—distilled water works best
- Mixing container
- A shallow dish to hold the soap solution
- White paper—very important
- A pencil or pen
Assembly
- To make the soap solution, mix 1 part dishwashing liquid in 10 parts water.
- Pour the soap solution into the shallow dish, filling it to approximately 1 cm (or half-inch) deep. Soap films work best and last longer if you let them sit overnight, allowing the soap molecules to diffuse through the entire solution.
- Remove the lid from the film can.
- Place the white paper on a tabletop. The white paper is important because light will then scatter up off the paper, bouncing off the soap film and into your eye.
To Do and Notice
Dip the open mouth of the film can straight down into the soap solution. When you pull it out, a soap film should have formed over the opening of the film can.
Rotate the film can so that the soap film is in a vertical plane. Hold it over the white paper in a brightly lit place.
You will see colors form and move around on the soap film. Over time, you might notice horizontal bands of color forming.
After a while, the top of the soap film becomes invisible because the soap film becomes thinner than a wavelength of light—under 300 nm thick. Even though you can’t see it, the soap film is still there! You can test this by poking a pencil point into the invisible region of the soap film—it will break.
What's Going On?
Think of the soap film as a water sandwich: a layer of water held between two layers of soap molecules. When the soap film is vertical, gravity pulls the water down, causing the top of the film to become thin and the bottom to become thick.
The reflections caused by these different thicknesses of soap film then cancel out different colors, producing bands of color that stretch across the film can.
Light reflects from both the front and back of the soap film. The light waves reflected from the front of the soap film are inverted while those from the back are not. The two reflections combine, producing interference of light.
When interference of light occurs, some color wavelengths add up “out of phase”—the highest point of one wave lines up with the lowest point of the other—and are therefore canceled. Others add up “in phase”—where the highest point of one wave lines up with the highest point of the other—and are therefore strengthened.
Understanding the colors of the soap film—from top to bottom:
Soap films that are thin compared to the wavelengths of light moving through them reflect no light at all—making them invisible. You can see this happening at the top of your soap film. Poking the invisible soap film with a pencil point reveals its presence because the entire soap film breaks.
When the soap film is a quarter of a wavelength of blue light thick, blue light is reflected strongly. At this same point, the film is about an eighth of a wavelength of red light thick—the wavelength of red light is just under twice that of blue, so some red light is reflected. The result is that the transparent film thickens into a metallic white sheen that appears bluer as it gets thicker.
Moving down the film, when it is half of a wavelength of blue light thick, the blue waves add up out of phase and cancel. At this point, the soap film is now a quarter of a wavelength of red light thick and the red waves add up in phase, resulting in a reddish color band.
Every integer multiple of a half blue wavelength in thickness, blue light is canceled; every odd multiple of a quarter blue wavelength, blue light is strengthened. Every multiple of a half red wavelength, the red light is strengthened. The result is alternating bands of bluish and reddish light as the film grows thicker—like contour lines on a topographic map.
Going Further
Robert Hooke first reported observing the transparent film in a letter to the Royal Society. His letter indicates that he thought that the film actually did not exist where it was transparent, but that some force held the colored film in place. However, a simple experiment of poking the invisible film and breaking it proves the existence of the invisible film.
To further experiment with soap films, try drilling a small hole in the bottom of the film can (approximately 5 mm in diameter). Create a soap film over the open mouth of the can and then blow through the hole. The soap film will bulge out into a dome.
Here’s another cool trick: Try blowing into the can to create a dome and then plug the hole with your finger. If you orientate the film can with the opening facing up, colored rings will appear in the soap film.
What do you think happens when the soap film is a half wavelength of green light thick? Or a quarter wavelength of green light?
Resources
- For more information, read Soap Bubbles: Their Colors and Forces Which Mold Them by C.V. Boys (Dover Publications, 2012).
- For other ways to experiment with interference colors try the Permanent Oil Slick Snack.
Want to join the conversation?
Does the soap ever pop or not work because light is going fast so does the bubble pop when the light hits it?(2 votes)
If light can go through it and create the colors with breaking it, light isn't causing the break at all. It's because it was too thin at the top to hold together anymore, causing the break.(1 vote)
is the paper like the lightbulb wich makes it colorful(1 vote)
No, it's just there so it reflects any light that you have coming from above, for example, the lightbulb above your head, on the ceiling. The light bounces off of the paper and hits the soapy water film, and causes the light to refract, and along with it, making the colors of the rainbow.(1 vote)