Studies of Scattering and Absorption in Light-Absorbing Materials Sage Farrar, Fishers Island School, Fishers Island, NY; Harold Metcalf and John Noe, Laser Teaching Center, Department of Physics and Astronomy, Stony Brook University. This summer I studied two different topics dealing with the scattering and absorption of light in different materials. Both topics were suggested by recent news stories, and both are related to familiar situations or problems. During the initial weeks of the Simons program I researched the scattering of light in human tissue. My interest in this began when I read about an FDA-approved acne treatment which involves exposure to strong blue light from an array of LEDs (light emitting diodes). Porphyrin compounds within the propionibacterium acnes (P. acnes) bacteria that cause acne are photo-sensitive, and when exposed to the blue LED light produce singlet oxygen which kills the anaerobic bacteria. This treatment is remarkable in that only light is used, without any other chemicals or drugs. In England, the same method of treatment is used, but they use yellow light, claiming that it penetrates the skin deeper. I wanted to test different colors of light on human tissue to see which wavelength is absorbed the most, and scattered least, as this might relate to the effectiveness of the different treatments. While this topic is very interesting, designing a suitable experiment that would give new and useful information is not easy. For this reason this study was set aside when a more straight-forward topic came up. My second topic was suggested by a news story (New York Times, 22 July) about a Yale study that tested the efficiency of anti-glare decals versus the dark greasepaint that football and baseball players have traditionally used on their faces. The conclusion was that the traditional greasepaint was more effective in reducing glare than the newer decals. It seemed that direct measurements of the actual scattering and absorption properties of the different materials could complement the Yale study, which was based on questionnaires. My experimental setup was the same as that being used by an undergraduate, Thomas Cummings, for a study related to laser drilling. The setup allows a sensitive photodetector to be moved in a semi-circle in front of the sample, at a constant distance. In my initial measurements the light source was a near-infrared laser beam (lambda=1.06 microns) incident perpendicular to the test surface. Measurements were taken every five degrees from 0 to 180. Measured light levels were compared to readings from a "bright white" diffuse test material (Spectralon). These initial measurements showed that even the black portion of the decals reflected about twice as much light as the greasepaint sample did (20% versus less than 10%). The measurements are now being extended to other wavelengths and angles of incidence. In the future I would like to continue my earlier research on light scattering from human tissue with medical applications. This study was supported by the Simons Foundation. I would also like to thank Richard Migliaccio for providing the photodetector and other assistance.