No immedate assembly needed.
Shine the maglite into one end of a glue stick and hold the other end of the glue stick approximately one centimeter from the white background. Notice that the end of the glue stick closer to the Mini-MagLite is a different color than the end nearer the white background. Notice the color of the circle on the white background.
Place two glue sticks end to end, and attach them together with the clear tape. Repeat the investigation with the Mini-MagLite, and notice any difference in the colors along the glue sticks and in the colored circle on the white background. Continue to attach more glue sticks with the clear tape and to notice the changes in color and intensity along the glue sticks and in the colored circle.
The Mini-MagLite emits white light. The glue stick scatters the blue light out of the Mini-MagLite beam more than the yellow or the red light. Because the first color to be scattered is blue, the end of the glue stick nearest the Mini-MagLite appears blue and the other end is yellow to yellow-orange. As glue sticks are joined to increase the length, more yellow light is scattered and the colored circle changes to an orange color.
The glue stick scattering model offers a demonstration of why the sky is blue and sunsets are red. The sky is blue because blue light is most readily scattered from sunlight in the atmosphere, just as blue light was most readily scattered from white light in the glue sticks. If blue light was not scattered in the atmosphere, the sun would look a little less yellow and a little more white, and the rest of the sky would be black.
At sunset, the sun is low near the horizon, and light travels through a greater thickness of atmosphere before reaching your eyes than it does when the sun is higher in the sky. Just as the light traveling along the glue sticks got redder as the length of the glue stick path got longer, so the sunset is red when the atmospheric path through which the sunlight travels gets longer. The scattering that produces the red sunset may be enhanced by pollution or other atmospheric conditions.
Scattering can polarize light. Place a polarizing filter between the Mini-MagLite and the first glue stick. Turn the filter while one person views the glue stick from the top and another views it from the side. Notice that when the top person sees a bright beam, the side person will see a dim beam, and vice-versa.
You can also hold the polarizing filter between your eye and the glue sticks and rotate the filter to make the beam look bright or dim. The filter polarizes the light and so does the scattering. When the two polarizations are aligned, the beam will be bright; when they are at right angles, the beam will be dim.
Scattering polarizes light because light is a transverse wave. The direction of the transverse oscillation of the electric field is called the direction of polarization of light.
The beam of light from the Mini-MagLite contains photons of light that are polarized in all directions: horizontally, vertically, and all angles in between. Consider only the vertically polarized light passing through the glue sticks. This light can scatter to the side and remain vertically polarized, but it cannot scatter upwards! To retain the characteristic of a transverse wave after scattering, only the vertically polarized light can be scattered sideways, and only the horizontally polarized light can be scattered upward. This is shown in the drawing below.
Paul Doherty and Don Rathjen