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  • A Schlieren image of a balloon popping. To increase the schlieren effect, the balloon is filed with pure carbon dioxide gas. The carbon dioxide gas has a different index of refraction than air, so the mixing can be clearly seen when the balloon is popped. The schlieren image identifies areas of different temperature by using the change in the index of refraction of a fluid due to a change in temperature. This image was captured using a high speed flash with a duration of 1/1,000,000th of a second. By photographer Ted Kinsman
    K07Sch1190.jpg
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  • A plate breaking as it hits the floor. Photographed with high-speed flash of a duration of 1/1,000,000th of a second. . By photographer Ted Kinsman
    K080126Smas...jpg
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  • A cup and plate breaking as it hits the floor. Photographed with high-speed flash of a duration of 1/1,000,000th of a second. . By photographer Ted Kinsman
    K080126Smas...jpg
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  • A drip of water splashes as it hits a shallow dish of water. The action is frozen in time with a high-speed flash with a duration of 1/20,000th of a second. The impact of the water droplet creates a unique crown shaped splash. By photographer Ted Kinsman
    070227drip0...jpg
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  • A drip of water splashes as it hits a shallow dish of water. The action is frozen in time with a high-speed flash with a duration of 1/20,000th of a second. The impact of the water droplet creates a unique crown shaped splash. By photographer Ted Kinsman
    070227drip0...jpg
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  • A drip of water splashes as it hits a shallow dish of water. The action is frozen in time with a high-speed flash with a duration of 1/20,000th of a second. The impact of the water droplet creates a unique crown shaped splash. By photographer Ted Kinsman
    070227drip0...jpg
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  • A drip of water splashes as it hits a shallow dish of water. The action is frozen in time with a high-speed flash with a duration of 1/20,000th of a second. The impact of the water droplet creates a unique crown shaped splash. By photographer Ted Kinsman
    070227drip0...jpg
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  • April Laragy, the lead singer of The Atomic Swindlers shows off her guitar moves. A special stroboscopic camera records the motion. The record of the motion can be analyzed to show both the timing and range of the motion. This type of image is very important in the science of biomechanics. By photographer Ted Kinsman
    April8337.jpg
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  • Little Brown Bat (Myotis lucifugus) captured in flight. These bats begin to fly just about sunset each night. During the winter moths the little brown bat will fly to a cave to hibernate for the winter. These bats also consume a huge amount of insects every night. Theses bats fly with their mouths open as they make the ultrasonic sounds used for feeding with their mouths. By photographer Ted Kinsman
    Bat_5970.jpg
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  • Little Brown Bat (Myotis lucifugus) captured in flight. These bats begin to fly just about sunset each night. During the winter moths the little brown bat will fly to a cave to hibernate for the winter. These bats also consume a huge amount of insects every night. Theses bats fly with their mouths open as they make the ultrasonic sounds used for feeding with their mouths. By photographer Ted Kinsman
    bat_5976.jpg
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  • Little Brown Bat (Myotis lucifugus) captured in flight. These bats begin to fly just about sunset each night. During the winter moths the little brown bat will fly to a cave to hibernate for the winter. These bats also consume a huge amount of insects every night. Theses bats fly with their mouths open as they make the ultrasonic sounds used for feeding with their mouths. By photographer Ted Kinsman
    bat_6040.jpg
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  • Little Brown Bat (Myotis lucifugus) captured in flight. These bats begin to fly just about sunset each night. During the winter moths the little brown bat will fly to a cave to hibernate for the winter. These bats also consume a huge amount of insects every night. Theses bats fly with their mouths open as they make the ultrasonic sounds used for feeding with their mouths. By photographer Ted Kinsman
    bat_6089.jpg
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  • A light bulb breaking as it hits the floor. Photographed with high-speed flash of a duration of 1/1,000,000th of a second. . By photographer Ted Kinsman
    K080127Smas...jpg
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  • Little Brown Bat (Myotis lucifugus) captured in flight. These bats begin to fly just about sunset each night. During the winter moths the little brown bat will fly to a cave to hibernate for the winter. These bats also consume a huge amount of insects every night. Theses bats fly with their mouths open as they make the ultrasonic sounds used for feeding with their mouths. By photographer Ted Kinsman
    bat_6101.jpg
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  • Little Brown Bat (Myotis lucifugus) captured in flight. These bats begin to fly just about sunset each night. During the winter moths the little brown bat will fly to a cave to hibernate for the winter. These bats also consume a huge amount of insects every night. Theses bats fly with their mouths open as they make the ultrasonic sounds used for feeding with their mouths. By photographer Ted Kinsman
    bat_7155.jpg
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  • Two dancers performing modern dance. A special stroboscopic camera records the motion. The record of the motion can be analyzed to show both the timing and range of the motion. This type of image is very important in the science of biomechanics. By photographer Ted Kinsman
    Dance8589.jpg
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  • A dancers performing modern dance. A special stroboscopic camera records the motion. The record of the motion can be analyzed to show both the timing and range of the motion. This type of image is very important in the science of biomechanics. By photographer Ted Kinsman
    dance8599.jpg
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  • A dancer performing modern dance. A special stroboscopic camera records the motion. The record of the motion can be analyzed to show both the timing and range of the motion. This type of image is very important in the science of biomechanics. By photographer Ted Kinsman
    dance8612.jpg
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  • A drummer shows off his drum moves. A special stroboscopic camera records the motion. The record of the motion can be analyzed to show both the timing and range of the motion. This type of image is very important in the science of biomechanics. By photographer Ted Kinsman
    drummer8431.jpg
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  • A light bulb breaking as it hits the floor. Photographed with high-speed flash of a duration of 1/1,000,000th of a second. . By photographer Ted Kinsman
    K080127Smas...jpg
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  • A boy juggles three balls. The motion is recorded by a special stroboscopic camera. The record of the motion can be analyzed to show both the timing and range of the motion. This type of image is very important in the science of biomechanics. By photographer Ted Kinsman
    juggle8288.jpg
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  • A boy juggles three balls. The motion is recorded by a special stroboscopic camera. The record of the motion can be analyzed to show both the timing and range of the motion. This type of image is very important in the science of biomechanics. By photographer Ted Kinsman
    juggle_8268.jpg
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  • A golf club moving at 97 miles per hour (43.36 m/s) hits a stationary golf ball. The action is recorded by a fast strobe with a duration of 1/1,000,000th of a second. In all collisions momentum is conserved. . By photographer Ted Kinsman
    K07-golf001...jpg
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  • A golf club moving at 97 miles per hour (43.36 m/s) hits a stationary golf ball. The action is recorded by a fast strobe with a duration of 1/1,000,000th of a second. In all collisions momentum is conserved. . By photographer Ted Kinsman
    K07-golf002...jpg
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  • A golf club moving at 97 miles per hour (43.36 m/s) hits a stationary golf ball. The action is recorded by a fast strobe with a duration of 1/1,000,000th of a second. In all collisions momentum is conserved. . By photographer Ted Kinsman
    K07-golf985...jpg
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