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  • Visitors observe the colorful red bacterial mat around perimeter of Grand Prismatic Spring, Midway Geyser Basin, Yellowstone National Park, Wyoming. Noted as the largest hot spring in the U.S. and third largest in the world.
    K12-yellowstone-pan002.jpg
  • Visitors observe the colorful red bacterial mat around perimeter of Grand Prismatic Spring, Midway Geyser Basin, Yellowstone National Park, Wyoming. Noted as the largest hot spring in the U.S. and third largest in the world.
    K12-yellowstone033.JPG
  • Visitors observe the colorful red bacterial mat around perimeter of Grand Prismatic Spring, Midway Geyser Basin, Yellowstone National Park, Wyoming. Noted as the largest hot spring in the U.S. and third largest in the world.
    K12-yellowstone-pan-prismatic001.jpg
  • A ball bounces on a spring.  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.
    spring8081.jpg
  • A light is mounted to the end of a spring.  The pendulum and bouncing action of the spring trace out Lissajous patterns in space.
    K09spring003.jpg
  • Scanning electron microscope (SEM) image of a hot spring extremophile community. The field of view is 45 um. This community thrives in 75C water in the hills of New Mexico. The community is made up of purple Sulfur bacteria, algae, and unidentified protozoa. The image was false colored with Photoshop since SEM images are inherently black and white.
    K18SEM-hotsprings-012B.jpg
  • A light is mounted to the end of a spring.  The pendulum and bouncing action of the spring trace out Lissajous patterns in space.
    K09spring002.jpg
  • Scanning electron microscope (SEM) image of a hot spring extremophile community. The field of view is 45 um. This community thrives in 75C water in the hills of New Mexico. The community is made up of purple Sulfur bacteria, algae, and unidentified protozoa. The image was false colored with Photoshop since SEM images are inherently black and white.
    K18SEM-hotsprings-012A.jpg
  • Scanning electron microscope (SEM) image of a hot spring extremophile community. The field of view is 45 um. This community thrives in 75C water in the hills of New Mexico. The community is made up of purple Sulfur bacteria, algae, and unidentified protozoa. The image was false colored with Photoshop since SEM images are inherently black and white.
    K18SEM-hotsprings-070A.jpg
  • Scanning electron microscope (SEM) image of a hot spring extremophile community. The field of view is 118 um which is just larger than a human hair. This community thrives in 75C water in the hills of New Mexico. The community is made up of purple Sulfur bacteria, algae, and unidentified protozoa. The image was false colored with Photoshop since SEM images are inherently black and white.
    K18SEM-hotsprings-002AA.jpg
  • Scanning electron microscope (SEM) image of a hot spring extremophile community. The field of view is 80 um. This community thrives in 75C water in the hills of New Mexico. The community is made up of purple Sulfur bacteria, algae, and unidentified protozoa. The image was false colored with Photoshop since SEM images are inherently black and white.
    K18SEM-hotsprings-008.jpg
  • Scanning electron microscope (SEM) image of a hot spring extremophile community. The field of view is 80 um. This community thrives in 75C water in the hills of New Mexico. The community is made up of purple Sulfur bacteria, algae, and unidentified protozoa. The image was false colored with Photoshop since SEM images are inherently black and white.
    K18SEM-hotsprings-008B.jpg
  • Scanning electron microscope (SEM) image of a hot spring extremophile community. The field of view is 146 um which is just larger than a human hair. This community thrives in 75C water in the hills of New Mexico. The community is made up of purple Sulfur bacteria, algae, and unidentified protozoa. The image was false colored with Photoshop since SEM images are inherently black and white.
    K18SEM-hotsprings-013B.jpg
  • Scanning electron microscope (SEM) image of a hot spring extremophile community. The field of view is 45 um. This community thrives in 75C water in the hills of New Mexico. The community is made up of purple Sulfur bacteria, algae, and unidentified protozoa. The image was false colored with Photoshop since SEM images are inherently black and white.
    K18SEM-hotsprings-066A.jpg
  • Scanning electron microscope (SEM) image of a hot spring extremophile community. The field of view is 45 um. This community thrives in 75C water in the hills of New Mexico. The community is made up of purple Sulfur bacteria, algae, and unidentified protozoa. The image was false colored with Photoshop since SEM images are inherently black and white.
    K18SEM-hotsprings-066B.jpg
  • False color x-ray of a Texas bluebonnet, Lupinus texensis. Bluebonnets are the state flower of Texas. This species is a Texas endemic, being limited to Central Texas where it puts on a world famous spring floral display along roadsides and in fields and pastures.
    K15X-bluebonnet01B.jpg
  • False color x-ray of a Texas bluebonnet, Lupinus texensis. Bluebonnets are the state flower of Texas. This species is a Texas endemic, being limited to Central Texas where it puts on a world famous spring floral display along roadsides and in fields and pastures.
    K15X-bluebonnet01A.jpg
  • Thermophilic bacteria (blue). Collected in the summer of 2012 in 90C water in Yellowstone National Park, Wyoming USA.  This scanning electron micrograh (SEM) was shot at 19,000X magnification and the filed of view is 1.5 um.  This type of bacteria is adapted to thrive at high water temperatures and is currently the focus of biological researchers.   Bacteria that can live in these extreme conditions are called thermophiles or extremophiles. This sample came from the hottest part of the springs.  The hotter the temperature the small smaller the bacteria typically.
    K12-thermo23A.jpg
  • Thermophilic bacteria (blue). Collected in the summer of 2012 in 90C water in Yellowstone National Park, Wyoming USA.  This scanning electron micrograh (SEM) was shot at 19,000X magnification and the filed of view is 1.5 um.  This type of bacteria is adapted to thrive at high water temperatures and is currently the focus of biological researchers.   Bacteria that can live in these extreme conditions are called thermophiles or extremophiles. This sample came from the hottest part of the springs.  The hotter the temperature the small smaller the bacteria typically.
    K12-thermo23BW.jpg
  • An X-ray of an artist's figure model.  The interior springs allow the wooden model to be poised in any position for drawing.
    artdollblue.jpg
  • An experiment is preformed to show how much liquid a pitcher of snow creates when it melts..This image is part of a series..
    K10snowmelt-montage1.jpg
  • An experiment is preformed to show how much liquid a pitcher of snow creates when it melts..This image is part of a series..
    K10blue-melt1.jpg
  • Thermophilic bacteria . Collected in the summer of 2012 in 60C water in Yellowstone National Park, Wyoming USA.  This scanning electron micrograh (SEM) was shot at 17,131X magnification and the filed of view is 7 um.  This type of bacteria is adapted to thrive at high water temperatures and is currently the focus of biological researchers.   Bacteria that can live in these extreme conditions are called thermophiles or extremophiles.
    K12-thermo35A.jpg
  • Thermophilic bacteria . Collected in the summer of 2012 in 60C water in Yellowstone National Park, Wyoming USA.  This scanning electron micrograh (SEM) was shot at 6,580X magnification and the filed of view is 20 um.  This type of bacteria is adapted to thrive at high water temperatures and is currently the focus of biological researchers.   Bacteria that can live in these extreme conditions are called thermophiles or extremophiles.
    K12-thermo36B.jpg
  • Thermophilic bacteria. Collected in the summer of 2012 in 60C water in Yellowstone National Park, Wyoming USA.  This scanning electron micrograh (SEM) was shot at 19,000X magnification and the filed of view is 3 um.  This type of bacteria is adapted to thrive at high water temperatures and is currently the focus of biological researchers.   Bacteria that can live in these extreme conditions are called thermophiles or extremophiles..
    K12-thermo32A.jpg
  • Thermophilic bacteria . Collected in the summer of 2012 in 60C water in Yellowstone National Park, Wyoming USA.  This scanning electron micrograh (SEM) was shot at 3,380X magnification and the filed of view is 29 um.  This type of bacteria is adapted to thrive at high water temperatures and is currently the focus of biological researchers.   Bacteria that can live in these extreme conditions are called thermophiles or extremophiles.
    K12-thermo31BW.jpg
  • Thermophilic bacteria . Collected in the summer of 2012 in 60C water in Yellowstone National Park, Wyoming USA.  This scanning electron micrograh (SEM) was shot at 3,380X magnification and the filed of view is 29 um.  This type of bacteria is adapted to thrive at high water temperatures and is currently the focus of biological researchers.   Bacteria that can live in these extreme conditions are called thermophiles or extremophiles.
    K12-thermo31A.jpg
  • Thermophilic bacteria . Collected in the summer of 2012 in 60C water in Yellowstone National Park, Wyoming USA.  This scanning electron micrograh (SEM) was shot at 4,580X magnification and the filed of view is 27 um.  This type of bacteria is adapted to thrive at high water temperatures and is currently the focus of biological researchers.   Bacteria that can live in these extreme conditions are called thermophiles or extremophiles.
    K12-thermo29B.jpg
  • Thermophilic bacteria. Collected in the summer of 2012 in 60C water in Yellowstone National Park, Wyoming USA.  This scanning electron micrograh (SEM) was shot at 19,000X magnification and the filed of view is 3 um.  This type of bacteria is adapted to thrive at high water temperatures and is currently the focus of biological researchers.   Bacteria that can live in these extreme conditions are called thermophiles or extremophiles..
    K12-thermo32C.jpg
  • Thermophilic bacteria. Collected in the summer of 2012 in 60C water in Yellowstone National Park, Wyoming USA.  This scanning electron micrograh (SEM) was shot at 19,000X magnification and the filed of view is 3 um.  This type of bacteria is adapted to thrive at high water temperatures and is currently the focus of biological researchers.   Bacteria that can live in these extreme conditions are called thermophiles or extremophiles..
    K12-thermo32B.jpg
  • Thermophilic bacteria . Collected in the summer of 2012 in 60C water in Yellowstone National Park, Wyoming USA.  This scanning electron micrograh (SEM) was shot at 4,580X magnification and the filed of view is 27 um.  This type of bacteria is adapted to thrive at high water temperatures and is currently the focus of biological researchers.   Bacteria that can live in these extreme conditions are called thermophiles or extremophiles.
    K12-thermo29A.jpg
  • Thermophilic bacteria (blue). Collected in the summer of 2012 in 60C water in Yellowstone National Park, Wyoming USA.  This scanning electron micrograh (SEM) was shot at 17,131X magnification and the filed of view is 7 um.  This type of bacteria is adapted to thrive at high water temperatures and is currently the focus of biological researchers.   Bacteria that can live in these extreem condions are called thermophiles or extremophiles..
    K12-thermo27B.jpg
  • Thermophilic bacteria . Collected in the summer of 2012 in 60C water in Yellowstone National Park, Wyoming USA.  This scanning electron micrograh (SEM) was shot at 6,580X magnification and the filed of view is 20 um.  This type of bacteria is adapted to thrive at high water temperatures and is currently the focus of biological researchers.   Bacteria that can live in these extreme conditions are called thermophiles or extremophiles.
    K12-thermo36A.jpg
  • Thermophilic bacteria . Collected in the summer of 2012 in 60C water in Yellowstone National Park, Wyoming USA.  This scanning electron micrograh (SEM) was shot at 17,131X magnification and the filed of view is 7 um.  This type of bacteria is adapted to thrive at high water temperatures and is currently the focus of biological researchers.   Bacteria that can live in these extreme conditions are called thermophiles or extremophiles.
    K12-thermo35BW.jpg
  • Thermophilic bacteria (blue). Collected in the summer of 2012 in 60C water in Yellowstone National Park, Wyoming USA.  This scanning electron micrograh (SEM) was shot at 17,131X magnification and the filed of view is 7 um.  This type of bacteria is adapted to thrive at high water temperatures and is currently the focus of biological researchers.   Bacteria that can live in these extreem condions are called thermophiles or extremophiles..
    K12-thermo27A.jpg
  • Thermophilic bacteria . Collected in the summer of 2012 in 60C water in Yellowstone National Park, Wyoming USA.  This scanning electron micrograh (SEM) was shot at 17,131X magnification and the filed of view is 7 um.  This type of bacteria is adapted to thrive at high water temperatures and is currently the focus of biological researchers.   Bacteria that can live in these extreme conditions are called thermophiles or extremophiles.
    K12-thermo35C.jpg
  • The geothermal pools at the edge of Yellowstone Lake in Yellowstone National Park.
    K12-yellowstone013.JPG
  • X-Ray of the  Hybrid hyacinth (Hyacinthus sp.) .
    K11X-hyacinth01.jpg
  • X-Ray of the  Hybrid hyacinth (Hyacinthus sp.) .
    K11X-hyacinthCU3.jpg
  • X-Ray of the  Hybrid hyacinth (Hyacinthus sp.) .
    K11X-hyacinthCU2.jpg
  • Taughannock Falls is the highest waterfall in western New York with a 215 foot sheer drop. This waterfall is located near Ithaca, New York.
    K09taughannock0001.jpg
  • X-Ray of Grape Hyacinth (Muscari armeniacum)
    K11X-grapehy1.jpg
  • A male American Toad (Bufo americanus)making vocalizations for mating. The male has an air sack that inflates to make the charasteric call.  The female will respond to an attractive call.  This image was taken the last  week of April in Upstate New York.  The toads live in woodland forest and only return to swamp land to mate and lay their eggs.  The toads only mate for about three days.
    K07toadmate0435.jpg
  • X-Ray of the  Hybrid hyacinth (Hyacinthus sp.) .
    K11X-hyacinthCU1.jpg
  • X-ray Wisteria Fowers. (Wisteria sp.)
    K15X-Wisteria01B.jpg
  • X-ray Wisteria Fowers. (Wisteria sp.)
    K15X-Wisteria01.jpg
  • X-Ray of the  Hybrid hyacinth (Hyacinthus sp.) .
    K11X-hyacinth02.jpg
  • A SEM iamge at 1500 x showing bacteria, algae, and un identified protozoa.
    Hot-spring-NM4000ARS.jpg
  • A new born fawn hides in the leaves in teh spring waiting for it's mother to return to feed it.  This fawn is less than 24  hours old and was photographed on May 22 in New York State.  White-tailed Deer (Odocoilieus virginianus) fawn in camouflage among fall leaves.
    K14-fawn0798.JPG
  • Cross section of a morel mushroom (Morchella esculenta) Photographed in Upstate New York in the Spring.
    K12-morel-2032.jpg
  • A new born fawn hides in the leaves in teh spring waiting for it's mother to return to feed it.  This fawn is less than 24  hours old and was photographed on May 22 in New York State.  White-tailed Deer (Odocoilieus virginianus) fawn in camouflage among fall leaves.
    K14-fawn0802.JPG
  • A new born fawn hides in the leaves in teh spring waiting for it's mother to return to feed it.  This fawn is less than 24  hours old and was photographed on May 22 in New York State.  White-tailed Deer (Odocoilieus virginianus) fawn in camouflage among fall leaves.
    K14-fawn0800.JPG
  • A new born fawn hides in the leaves in teh spring waiting for it's mother to return to feed it.  This fawn is less than 24  hours old and was photographed on May 22 in New York State.  White-tailed Deer (Odocoilieus virginianus) fawn in camouflage among fall leaves.
    K14-fawn0794.JPG
  • A new born fawn hides in the leaves in teh spring waiting for it's mother to return to feed it.  This fawn is less than 24  hours old and was photographed on May 22 in New York State.  White-tailed Deer (Odocoilieus virginianus) fawn in camouflage among fall leaves.
    K14-fawn0791.JPG
  • Cross section of a morel mushroom (Morchella esculenta) Photographed in Upstate New York in the Spring.
    K12-morel-2036.jpg
  • A new born fawn hides in the leaves in teh spring waiting for it's mother to return to feed it.  This fawn is less than 24  hours old and was photographed on May 22 in New York State.  White-tailed Deer (Odocoilieus virginianus) fawn in camouflage among fall leaves.
    K14-fawn0796.JPG
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