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1.INTRODUCTIONMuch can be learned about optics by critically observing patterns of light and color in nature.1 A fairly common natural optical phenomenon is sun glitter,2 which is a collection of specular reflections of the sun (or “glints”) on the surface of water, as shown in Fig. 1. Glitter patterns change shape depending on the water surface roughness and the solar elevation angle.3,4 Because the water surface is roughened by small, wind-driven waves,5,6,7 glitter pattern measurements can be used for remote sensing of wind patterns.7,8,9 Under very light-wind conditions the number of sun glints decreases and interesting fun-house-mirror kind of reflections of the surroundings can be seen, as shown in Fig. 2.10 This is further illustrated in Fig. 3, which shows multiple sun reflections on the rough water surface and a single sun reflection on the smooth water within the enclosed pool in the foreground. The photographs in Fig. 4 show a glitter pattern close up so that the individual glints are easily discerned. Because we expected to see white light, i.e. colorless glints (or perhaps orange glints with a reddened setting sun11), we were surprised on several occasions to see blue glints when observing glitter patterns through polarizing sun glasses or through a polarizing filter oriented for minimum glint brightness, as shown in the right-hand photograph in Fig. 4 (the image exposures were 1/800 s at f/14 and ISO400 for the left-hand image and 1/80 s at f/5.6 and ISO400 for the right-hand image). The same effect occurred for viewing through either a polarizing filter on a camera lens or polarized sunglasses in front of the lens. Similarly, the same effect occurred for both linear and circular polarizing filters. This is because circular polarizing filters are made of a linear polarizer on the object side and a quarter-wave plate on the camera side, so they act as a regular linear polarizer for detecting light from the scene. After some investigation, we found that the blue glint color arises because of a small amount of blue light leakage through the polarizing filter.2 In other words, the polarizer efficiency falls off at short wavelengths (it also falls off even more at near-infrared wavelengths, but that is not a significant factor here). Figures 5 and 6 show additional examples of blue glints – this time with a single sun reflection on a very smooth water surface viewed through a horizontal polarizer for the left-hand images and a vertical polarizer for the right-hand images. Fig. 5 is a wide-angle view, while Fig. 6 is a zoomed-in image centered on the sun reflection. 2.GLINT POLARIZATION AND BLUE GLINTSGlints are partially polarized by reflection and become 100% polarized when the reflection angle is very near the Brewster angle (approximately 53°).12-14 This is indicated in the plots of Fig. 7 that show the s- and p-polarized reflectivity on the left and the corresponding degree of polarization15 on the right for red light reflected from water. Even if the surface is rippled by the wind, the glints remain at least 90% polarized for angles of 45°-61° and 80% polarized for angles of 41°-65°; this allows for highly polarized glints even with modestly wind-rippled surfaces.10 The glints in the right-hand images of Figs. 4, 5, and 6 took on a blue appearance because they were observed through a polarizer whose transmission axis was oriented approximately vertical, which would be orthogonal to the axis of polarization for the reflected light in the glints. This occurred because the polarizer efficiency drops off for short-wavelength (blue) light, as shown in the transmission spectrum shown in the left-hand image of Fig. 8. This spectrum was recorded with an initially randomly polarized white light source shining through the polarizer under test followed by a second, high-quality, broadband polarizer with a contrast ratio near 105 for 350-580 nm and at least 103 for 580-2600 nm (Meadowlark Optics OWL polarizer). This crossed-polarizer spectrum exhibits a very large light leak in the near infrared (NIR) beyond about 780 nm, but this radiation is not visible by eye and is largely not recorded in standard visible-light cameras, which are fitted with NIR-blocking filters.16.17 Since the same blue glints were visible simply by looking through a polarizer or polarizing sunglasses with the naked eye, we quickly knew that the NIR leak was not the source of the blue color. The actual source of the blue color was the less-obvious blue light leak at wavelengths below 450 nm. The blue light leak is well known in the community of people who design polarizers and electronic displays that incorporate polarizers,18 but many people are not aware of its existence. An even larger version of the blue light leak is apparent in the crossed-polarizer spectrum shown in the right-hand frame of Fig. 8. This spectrum was measured for a pair of polarized sunglasses (Outlaw by Balzer). Blue glints should be visible with any type of polarized sunglasses, but this model makes it particularly easy to see blue glints. In fact, it is so simple that when wearing these glasses, we now regularly see blue colors in reflections from smooth floors, car windows, and just about any relatively smooth surface. Several examples are shown in Figures 8 – 13, which are photographs taken with smartphone cameras looking through the Balzer sunglasses. 3.CONCLUSIONInteresting lessons about optics can be learned and taught using simple polarizing filters or sunglasses and cameras. We have shown crossed-polarizer transmission spectra measured for polarized sunglasses and for photographic polarizing filters, both of which exhibited blue light leakage (as well as NIR leakage). This blue light leakage results in blue reflections when the reflected light occurs at or near the Brewster angle and is viewed through a polarizer oriented with its axis orthogonal to the reflected light polarization. Such blue reflections can be seen on water, car windshields, smooth marble floors, and other relatively smooth surfaces. 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