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  • Two water drips collide. One drip hits a surface of water and rebounds at the exact time a second drip calls. The resulting collision makes a spray of water. This effect is photographed with a high speed flash and is effectively frozen in time with a 20 microsecond flash.
    K21-Double-Water-Drips-02768.jpg
  • Two water drips collide. One drip hits a surface of water and rebounds at the exact time a second drip calls. The resulting collision makes a spray of water. This effect is photographed with a high speed flash and is effectively frozen in time with a 20 microsecond flash.
    K21-Double-Water-Drips-03236.jpg
  • Two water drips collide. One drip hits a surface of water and rebounds at the exact time a second drip calls. The resulting collision makes a spray of water. This effect is photographed with a high speed flash and is effectively frozen in time with a 20 microsecond flash.
    K21-Double-Water-Drips-03067.jpg
  • Two water drips collide. One drip hits a surface of water and rebounds at the exact time a second drip calls. The resulting collision makes a spray of water. This effect is photographed with a high speed flash and is effectively frozen in time with a 20 microsecond flash.
    K21-Double-Water-Drips-02816.jpg
  • Two water drips collide. One drip hits a surface of water and rebounds at the exact time a second drip calls. The resulting collision makes a spray of water. This effect is photographed with a high speed flash and is effectively frozen in time with a 20 microsecond flash.
    K21-Double-Water-Drips-02792.jpg
  • Two water drips collide. One drip hits a surface of water and rebounds at the exact time a second drip calls. The resulting collision makes a spray of water. This effect is photographed with a high speed flash and is effectively frozen in time with a 20 microsecond flash.
    K21-Double-Water-Drips-02802.jpg
  • Two water drips collide. One drip hits a surface of water and rebounds at the exact time a second drip calls. The resulting collision makes a spray of water. This effect is photographed with a high speed flash and is effectively frozen in time with a 20 microsecond flash.
    K21-Double-Water-Drips-02780.jpg
  • Two water drips collide. One drip hits a surface of water and rebounds at the exact time a second drip calls. The resulting collision makes a spray of water. This effect is photographed with a high speed flash and is effectively frozen in time with a 20 microsecond flash.
    K21-Double-Water-Drips-03198.jpg
  • Two water drips collide. One drip hits a surface of water and rebounds at the exact time a second drip calls. The resulting collision makes a spray of water. This effect is photographed with a high speed flash and is effectively frozen in time with a 20 microsecond flash.
    K21-Double-Water-Drips-03098.jpg
  • Two water drips collide. One drip hits a surface of water and rebounds at the exact time a second drip calls. The resulting collision makes a spray of water. This effect is photographed with a high speed flash and is effectively frozen in time with a 20 microsecond flash.
    K21-Double-Water-Drips-03076.jpg
  • Two water drips collide. One drip hits a surface of water and rebounds at the exact time a second drip calls. The resulting collision makes a spray of water. This effect is photographed with a high speed flash and is effectively frozen in time with a 20 microsecond flash.
    K21-Double-Water-Drips-02832.jpg
  • Two water drips collide. One drip hits a surface of water and rebounds at the exact time a second drip calls. The resulting collision makes a spray of water. This effect is photographed with a high speed flash and is effectively frozen in time with a 20 microsecond flash.
    K21-Double-Water-Drips-02776.jpg
  • Two water drips collide. One drip hits a surface of water and rebounds at the exact time a second drip calls. The resulting collision makes a spray of water. This effect is photographed with a high speed flash and is effectively frozen in time with a 20 microsecond flash.
    K21-Double-Water-Drips-03088.jpg
  • Two water drips collide. One drip hits a surface of water and rebounds at the exact time a second drip calls. The resulting collision makes a spray of water. This effect is photographed with a high speed flash and is effectively frozen in time with a 20 microsecond flash.
    K21-Double-Water-Drips-02770.jpg
  • Two water drips collide. One drip hits a surface of water and rebounds at the exact time a second drip calls. The resulting collision makes a spray of water. This effect is photographed with a high speed flash and is effectively frozen in time with a 20 microsecond flash.
    K21-Double-Water-Drips-02868.jpg
  • Two water drips collide. One drip hits a surface of water and rebounds at the exact time a second drip calls. The resulting collision makes a spray of water. This effect is photographed with a high speed flash and is effectively frozen in time with a 20 microsecond flash.
    K21-Double-Water-Drips-02795.jpg
  • Two water drips collide. One drip hits a surface of water and rebounds at the exact time a second drip calls. The resulting collision makes a spray of water. This effect is photographed with a high speed flash and is effectively frozen in time with a 20 microsecond flash.
    K21-Double-Water-Drips-03268.jpg
  • Two water drips collide. One drip hits a surface of water and rebounds at the exact time a second drip calls. The resulting collision makes a spray of water. This effect is photographed with a high speed flash and is effectively frozen in time with a 20 microsecond flash.
    K21-Double-Water-Drips-02808.jpg
  • Leaf of a Giant Amazon water lilies (Victoria amazonica).
    K15-giantwaterlily01.jpg
  • A false color x-ray of the leaf of a Giant Amazon water lilies (Victoria amazonica)
    K14X-amazon-lily01B.jpg
  • A false color x-ray of the leaf of a Giant Amazon water lilies (Victoria amazonica)
    K14X-amazon-lily01BW.jpg
  • The water flea (Daphnia magna) is commonly found in fresh water. Water fleas are filter feeders that ingest algae, protozoan, or organic matter. The dark spots inside the animal are eggs. This image was created using the Rheinberg illumination technique.
    daphnia-B00039_8x10.jpg
  • A false color x-ray of the leaf of a Giant Amazon water lilies (Victoria amazonica)
    K14X-amazon-lily01.jpg
  • 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.
    070227drip0449.jpg
  • 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.
    070227drip0427.jpg
  • A false color x-ray of the leaf of a Giant Amazon water lilies (Victoria amazonica)
    K14X-amazon-lily01BW2.jpg
  • Two water drips collide.  One drip hits a surface of water and rebounds at the exact time a second drip calls.  The resulting collision makes a spray of water.  This effect is photographed with a high speed flash and is effectively frozen in time with a 1/60,000 second flash.
    K08-drips008.jpg
  • Two water drips collide.  One drip hits a surface of water and rebounds at the exact time a second drip calls.  The resulting collision makes a spray of water.  This effect is photographed with a high speed flash and is effectively frozen in time with a 1/60,000 second flash.
    K08-drips001.jpg
  • The vacuum chamber setup to boil ice water in a vacuum.  Ice water is placed in a beaker and the air is removed in a vacuum chamber.  Then the air pressure is lower that the waters vapor pressure the liquid will boil.
    K12vac-boil-icewater001.JPG
  • Two water drips collide.  One drip hits a surface of water and rebounds at the exact time a second drip calls.  The resulting collision makes a spray of water.  This effect is photographed with a high speed flash and is effectively frozen in time with a 1/60,000 second flash.
    K08-drips003.jpg
  • X-ray of a Deep Water Crab
    K12X-deep-crab001A2.jpg
  • A stone is dropped in water, creating a splash.
    K09watersplash5377.jpg
  • 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.
    070227drip0319.jpg
  • Two water drips collide.  One drip hits a surface of water and rebounds at the exact time a second drip calls.  The resulting collision makes a spray of water.  This effect is photographed with a high speed flash and is effectively frozen in time with a 1/60,000 second flash.
    K08-drips016.jpg
  • Two water drips collide.  One drip hits a surface of water and rebounds at the exact time a second drip calls.  The resulting collision makes a spray of water.  This effect is photographed with a high speed flash and is effectively frozen in time with a 1/60,000 second flash.
    K08-drips017.jpg
  • Two water drips collide.  One drip hits a surface of water and rebounds at the exact time a second drip calls.  The resulting collision makes a spray of water.  This effect is photographed with a high speed flash and is effectively frozen in time with a 1/60,000 second flash.
    K08-drips014.jpg
  • Two water drips collide.  One drip hits a surface of water and rebounds at the exact time a second drip calls.  The resulting collision makes a spray of water.  This effect is photographed with a high speed flash and is effectively frozen in time with a 1/60,000 second flash.
    K08-drips011.jpg
  • Two water drips collide.  One drip hits a surface of water and rebounds at the exact time a second drip calls.  The resulting collision makes a spray of water.  This effect is photographed with a high speed flash and is effectively frozen in time with a 1/60,000 second flash.
    K08-drips007.jpg
  • Two water drips collide.  One drip hits a surface of water and rebounds at the exact time a second drip calls.  The resulting collision makes a spray of water.  This effect is photographed with a high speed flash and is effectively frozen in time with a 1/60,000 second flash.
    K08-drips005.jpg
  • Two water drips collide.  One drip hits a surface of water and rebounds at the exact time a second drip calls.  The resulting collision makes a spray of water.  This effect is photographed with a high speed flash and is effectively frozen in time with a 1/60,000 second flash.
    K08-drips018.jpg
  • Two water drips collide.  One drip hits a surface of water and rebounds at the exact time a second drip calls.  The resulting collision makes a spray of water.  This effect is photographed with a high speed flash and is effectively frozen in time with a 1/60,000 second flash.
    K08-drips002.jpg
  • Ice water is placed in a beaker and the air is removed in a vacuum chamber.  Then the air pressure is lower that the waters vapor pressure the liquid will boil.
    K12vac-boil-icewater004.JPG
  • A green apple is dropped in water, creating a splash.
    K09watersplash5496.jpg
  • A tomato is dropped in water, creating a splash.
    K09watersplash5436.jpg
  • A two liter soda bottle is filled with 400ml of water and pressurized to 8 atmospheric pressures..When the bottom clamp is released, the soda bottle becomes a rocket that can reach a height in excess of 150 meters.  This activity is used with students to study rockets.  This rocket is photographed with a high speed flash.
    K07waterrockets003.jpg
  • Two water drips collide.  One drip hits a surface of water and rebounds at the exact time a second drip calls.  The resulting collision makes a spray of water.  This effect is photographed with a high speed flash and is effectively frozen in time with a 1/60,000 second flash.
    K08-drips013.jpg
  • Two water drips collide.  One drip hits a surface of water and rebounds at the exact time a second drip calls.  The resulting collision makes a spray of water.  This effect is photographed with a high speed flash and is effectively frozen in time with a 1/60,000 second flash.
    K08-drips012.jpg
  • Two water drips collide.  One drip hits a surface of water and rebounds at the exact time a second drip calls.  The resulting collision makes a spray of water.  This effect is photographed with a high speed flash and is effectively frozen in time with a 1/60,000 second flash.
    K08-drips010.jpg
  • Two water drips collide.  One drip hits a surface of water and rebounds at the exact time a second drip calls.  The resulting collision makes a spray of water.  This effect is photographed with a high speed flash and is effectively frozen in time with a 1/60,000 second flash.
    K08-drips009.jpg
  • Two water drips collide.  One drip hits a surface of water and rebounds at the exact time a second drip calls.  The resulting collision makes a spray of water.  This effect is photographed with a high speed flash and is effectively frozen in time with a 1/60,000 second flash.
    K08-drips004.jpg
  • X-ray and optical image of a Deep Water Crab.  The left side of the image is an X-ray, while the right side is a visible light photograph.
    K12X-deep-crab-half-half005A.jpg
  • X-ray of a Deep Water Crab
    K12X-deep-crab005C.jpg
  • X-ray of a Deep Water Crab
    K12X-deep-crab004A.jpg
  • A lemon is dropped in water, creating a splash.
    K09watersplash5511.jpg
  • Two water drips collide.  One drip hits a surface of water and rebounds at the exact time a second drip calls.  The resulting collision makes a spray of water.  This effect is photographed with a high speed flash and is effectively frozen in time with a 1/60,000 second flash.
    K08-drips015.jpg
  • Two water drips collide.  One drip hits a surface of water and rebounds at the exact time a second drip calls.  The resulting collision makes a spray of water.  This effect is photographed with a high speed flash and is effectively frozen in time with a 1/60,000 second flash.
    K08-drips006.jpg
  • X-ray of a Deep Water Crab
    K12X-deep-crab005B.jpg
  • X-ray of a Deep Water Crab
    K12X-deep-crab005A.jpg
  • X-ray of a Deep Water Crab
    K12X-deep-crab004B.jpg
  • X-ray of a Deep Water Crab
    K12X-deep-crab001A3.jpg
  • X-ray of a Deep Water Crab
    K12X-deep-crab001A.jpg
  • Ice water is placed in a beaker and the air is removed in a vacuum chamber.  Then the air pressure is lower that the waters vapor pressure the liquid will boil.
    K12vac-boil-icewater002.JPG
  • A lemon is dropped in water, creating a splash.
    K09watersplash5512.jpg
  • An apple is dropped in water, creating a splash.
    K09watersplash5508.jpg
  • An ice cube is dropped in water, creating a splash.
    K09watersplash5407.jpg
  • False color scanning electron microscope image of a water penny beetle larva (Psephenus herricki).  this specimen was collected in freshwater in New York State.  The magnification is 15x.
    K08semWaterpenny-combo-Large3.jpg
  • An ice cube is dropped in water, creating a splash.
    K09watersplash5414.jpg
  • A stone is dropped in water, creating a splash.
    K09watersplash5343.jpg
  • A boy holds a glass of hot water.  This image is part of a series showing the identical scene in far infrared light.  The comparison of image in the series show the power of far infrared light to detect changes in temperature.
    ir07-198visible.jpg
  • Thermogram of a boy drinking cold water.  This image is part of a series.  The different colors represent different temperatures on the object. The lightest colors are the hottest temperatures, while the darker colors represent a cooler temperature.  Thermography uses special cameras that can detect light in the far-infrared range of the electromagnetic spectrum (900?14,000 nanometers or 0.9?14 µm) and creates an  image of the objects temperature..
    ir07-1314.jpg
  • Water is stirred until the rotation causes a vortex to form on the surface.  Here the fine structure of the vortex is studied with the help of high speed photography..
    kin070217vortex0002.jpg
  • Thermogram of a boy drinking cold water.  This image is part of a series.  The different colors represent different temperatures on the object. The lightest colors are the hottest temperatures, while the darker colors represent a cooler temperature.  Thermography uses special cameras that can detect light in the far-infrared range of the electromagnetic spectrum (900?14,000 nanometers or 0.9?14 µm) and creates an  image of the objects temperature..
    ir07-1319.jpg
  • Water is stirred until the rotation causes a vortex to form on the surface.  Here the fine structure of the vortex is studied with the help of high speed photography..
    kin070217vortex0001.jpg
  • Scanning Electron Micrograph (SEM) of a sample if ice water hash or hashish. Shown in the image is a pile of glandular trichomes that have been concentrated in a unique process. Leaves with very high concentrations of stalked glandular trichomes are cooled in ice water then agitated. The agitation breaks off the trichomes, which in turn sink, to the bottom of the water.  Once separated from the water and dried, the ice water hash has some of the highest concentrations of THC of any physical separation process.  Since the stalked glandular trichomes are the location of the highest concentration of THC this technique in recent years has become very popular. The marijuana (Cannabis sativa) plant contains tetrahydrocannabinol (THC), the active component of cannabis when used as a drug. The spherical cells in this sample are 60 um in diameter.
    K170403hashish01.jpg
  • Scanning electron microscope image of a water flea (Daphnia magna).  Daphnia is commonly found in fresh water. Water fleas are filter feeders that ingest algae, protozoan, or organic matter. This image represents a field of view of 2 mm and was collected at a magnification of 329x...
    K09-semdaphnia117.jpg
  • Scanning electron microscope image of a water flea (Daphnia magna).  Daphnia is commonly found in fresh water. Water fleas are filter feeders that ingest algae, protozoan, or organic matter. This image was collected at a magnification of 2,180x...
    K09-semdaphnia119.jpg
  • The inside of a magnetron removed from a microwave oven.  The magnetron is a device that creates microwave radiation. A magnetron consists of an electron tube surrounded by a magnet. As electrons are released from the heated cathode they are forced to take a spiral path to the anode by the magnetic field, creating microwaves. This magnetron creates a microwave radiation that is the same frequency as a water molecule vibrates.  When water is exposed to just the right frequency, the water molecules will gain kinetic energy and become hotter.
    K11-magnetron7111.jpg
  • Unidentified freshwater bacteria collected from pond water. The red structure is a freshwater diatom. The horizontal field of view is 15 um.
    K15SEM-pondbacteria024.jpg
  • Snowflake with a platelet crystal form, made in a cloud when water freezes at negative fifteen degrees Celsius. When crystallization occurs slowly, in calm air and in temperatures near the freezing point, snowflakes will exhibit hexagonal symmetry.
    K11Snowflake6525.jpg
  • Snowflake with a platelet crystal form, made in a cloud when water freezes at negative fifteen degrees Celsius. When crystallization occurs slowly, in calm air and in temperatures near the freezing point, snowflakes will exhibit hexagonal symmetry.
    K11Snowflake6511.jpg
  • The inside of a magnetron removed from a microwave oven.  The magnetron is a device that creates microwave radiation. A magnetron consists of an electron tube surrounded by a magnet. As electrons are released from the heated cathode they are forced to take a spiral path to the anode by the magnetic field, creating microwaves. This magnetron creates a microwave radiation that is the same frequency as a water molecule vibrates.  When water is exposed to just the right frequency, the water molecules will gain kinetic energy and become hotter.
    K11-magnetron7101.jpg
  • Unidentified freshwater bacteria collected from pond water. The red structure is a freshwater diatom. The horizontal field of view is 12 um.
    K15SEM-pondbacteria026B.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
  • Snowflake with a stellar (or dendritic) crystal form, made in a cloud when water freezes at negative fifteen degrees Celsius. When crystallization occurs slowly, in calm air and in temperatures near the freezing point, snowflakes will exhibit hexagonal symmetry.
    K11Snowflake6817.jpg
  • Snowflake with a stellar (or dendritic) crystal form, made in a cloud when water freezes at negative fifteen degrees Celsius. When crystallization occurs slowly, in calm air and in temperatures near the freezing point, snowflakes will exhibit hexagonal symmetry.
    K11Snowflake6794.jpg
  • Snowflake with a platelet crystal form, made in a cloud when water freezes at negative fifteen degrees Celsius. When crystallization occurs slowly, in calm air and in temperatures near the freezing point, snowflakes will exhibit hexagonal symmetry.
    K11Snowflake6528.jpg
  • Snowflake with a stellar (or dendritic) crystal form, made in a cloud when water freezes at negative fifteen degrees Celsius. When crystallization occurs slowly, in calm air and in temperatures near the freezing point, snowflakes will exhibit hexagonal symmetry.
    K11-snow6840.jpg
  • Snowflake with a stellar (or dendritic) crystal form, made in a cloud when water freezes at negative fifteen degrees Celsius. When crystallization occurs slowly, in calm air and in temperatures near the freezing point, snowflakes will exhibit hexagonal symmetry.
    IMG_5855.jpg
  • Snowflake with a stellar (or dendritic) crystal form, made in a cloud when water freezes at negative fifteen degrees Celsius. When crystallization occurs slowly, in calm air and in temperatures near the freezing point, snowflakes will exhibit hexagonal symmetry.
    IMG_5795.jpg
  • Snowflake with a stellar (or dendritic) crystal form, made in a cloud when water freezes at negative fifteen degrees Celsius. When crystallization occurs slowly, in calm air and in temperatures near the freezing point, snowflakes will exhibit hexagonal symmetry.
    IMG_5649.jpg
  • Snowflake with a stellar (or dendritic) crystal form, made in a cloud when water freezes at negative fifteen degrees Celsius. When crystallization occurs slowly, in calm air and in temperatures near the freezing point, snowflakes will exhibit hexagonal symmetry.
    IMG_5450.jpg
  • Snowflake with a stellar (or dendritic) crystal form, made in a cloud when water freezes at negative fifteen degrees Celsius. When crystallization occurs slowly, in calm air and in temperatures near the freezing point, snowflakes will exhibit hexagonal symmetry.
    IMG_5287.jpg
  • Snowflake with a stellar (or dendritic) crystal form, made in a cloud when water freezes at negative fifteen degrees Celsius. When crystallization occurs slowly, in calm air and in temperatures near the freezing point, snowflakes will exhibit hexagonal symmetry.
    IMG_4829.jpg
  • Snowflake with a stellar (or dendritic) crystal form, made in a cloud when water freezes at negative fifteen degrees Celsius. When crystallization occurs slowly, in calm air and in temperatures near the freezing point, snowflakes will exhibit hexagonal symmetry.
    IMG_4648.jpg
  • Snowflake with a stellar (or dendritic) crystal form, made in a cloud when water freezes at negative fifteen degrees Celsius. When crystallization occurs slowly, in calm air and in temperatures near the freezing point, snowflakes will exhibit hexagonal symmetry.
    070214frost0006.jpg
  • Snowflake with a stellar (or dendritic) crystal form, made in a cloud when water freezes at negative fifteen degrees Celsius. When crystallization occurs slowly, in calm air and in temperatures near the freezing point, snowflakes will exhibit hexagonal symmetry.
    Snowflake05-1936.jpg
  • A Northern Leopard Frog (Rana pipiens) jumps into water. This species escapes predators by seeking the safety of water.
    IMG_1584-crop.jpg
  • Snowflake with a stellar (or dendritic) crystal form, made in a cloud when water freezes at negative fifteen degrees Celsius. When crystallization occurs slowly, in calm air and in temperatures near the freezing point, snowflakes will exhibit hexagonal symmetry.
    K14-snowflake9024A.jpg
  • Snowflake with a stellar (or dendritic) crystal form, made in a cloud when water freezes at negative fifteen degrees Celsius. When crystallization occurs slowly, in calm air and in temperatures near the freezing point, snowflakes will exhibit hexagonal symmetry.
    K13Snow011A.jpg
  • Snowflake with a stellar (or dendritic) crystal form, made in a cloud when water freezes at negative fifteen degrees Celsius. When crystallization occurs slowly, in calm air and in temperatures near the freezing point, snowflakes will exhibit hexagonal symmetry.
    K13snow006A.jpg
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