Place the laser so that it shines down the length of the tube filled with Karo Syrup. Place one polarizing sheet between the laser and the tube. Darken the room and a series of maximums and minimums will be observed the length of the tube. If you view a maximum from the side and then move so that you are viewing the same spot from the top you will find that the maximum has turned into a minimum due to the optical rotation of the Karo Syrup. Replace the laser with a slide projector and you will see a rainbow spiral down the length of the tube.

NOTE:  Only secondary colors are seen here.  Also by rotating the polarizing plate you may make the colors or the maximums and minimums of the laser beam travel down the length of the tube.

NOTE: Do not bring the 1000 watt bulb slide projector too close to the polarizing plate as the heat generated will melt the plate. A regular slide projector will work in this situation, the colors will be just less intense.  

An interesting effect can be observed by placing filters in the light beam or in the slide projector itself.  Instead of a barber pole type rainbow, you will see dark bands in the rainbow corresponding to the colors that are absorbed by the filter.

If you happen to have two tube available for this experiment you could try filling one with a solution of D-Fructose (Levulose) and one with D-Glucose (Dextrose) with concentrations of 1 to 5 g / 100 ml of solution.  The D-Fructose should have polarization angles between -92 and -133.5 degrees.  The D-Glucose solution should have polarization angles between +52.7 to +122.  Both of these sugars have chemical formulas of C₆H₁₂O₆.