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  • A .22 caliber bullet hitting a hot pepper. The bullet is travelling at 660 feet per second (201 meters per second). This image shows the collision of the bullet and hot pepper photographed at 1/1,000,000th of a second lash/strobe speed.
    hot-pepperbullet.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
  • A Thermogram of a hot rifle.  This gun has just fired a dozen bullets and the barrel is quite hot.  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..
    gun-1.jpg
  • X-Ray of a three different types of hot peppers.  On the top is Anaheim pepper or New Mexican pepper , the bottom left is the  habanero pepper, and on the lower right is the jalapeno pepper.
    x07hotpepperscolor.jpg
  • Thermogram of a hot toast.  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..
    ir07-675.jpg
  • A Thermogram of a boy witha hot glass of 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..
    ir07-198.jpg
  • Thermogram of hot toast and butter.  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..
    ir07-678.jpg
  • Schlieren image of a hot light bulb.  The schlieren images identifies areas of different temperature by using the change in the index of refraction of a fluid due to a change in temperature.
    K07Sch1346.jpg
  • Thermogram of a hot dish of food.  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..
    ir07-1524.jpg
  • Schlieren image of a hot light bulb.  The schlieren images identifies areas of different temperature by using the change in the index of refraction of a fluid due to a change in temperature.
    K07Sch1327.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-012B.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 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 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 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
  • Thermogram of steam pipes for a hot water heating system.  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..
    Ir07-1079.jpg
  • Thermogram of steam pipes for a hot water heating system.  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..
    Ir07-1077.jpg
  • This image is a combination of two images, one taken in visible light and one taken in infrared light. In the IR thermogram the temperature range goes from hot (white) to cold (blue). Thermography is a technique for visualizing the temperature of surfaces by recording the emission of long-wavelength infrared radiation. This heat radiation is detected electronically and displayed with different colors representing different temperatures.  In this image the whiter colors are the hottest.  The windows in homes are a major source of heat loss.
    K07houseD-ir-combo1.tif
  • This image is a combination of two images, one taken in visible light and one taken in infrared light. In the IR thermogram the temperature range goes from hot (white) to cold (blue). Thermography is a technique for visualizing the temperature of surfaces by recording the emission of long-wavelength infrared radiation. This heat radiation is detected electronically and displayed with different colors representing different temperatures.  In this image the whiter colors are the hottest.  The windows in homes are a major source of heat loss.
    K07houseC-ir-combo.tif
  • A thermogram of a home in winter. The temperature range goes from hot (white) to cold (blue). Thermography is a technique for visualizing the temperature of surfaces by recording the emission of long-wavelength infrared radiation. This heat radiation is detected electronically and displayed with different colors representing different temperatures.  In this image the whiter colors are the hottest.  The windows in homes are a major source of heat loss.
    K07houseC-ir02.tif
  • This image is a combination of two images, one taken in visible light and one taken in infrared light. In the IR thermogram the temperature range goes from hot (white) to cold (blue). Thermography is a technique for visualizing the temperature of surfaces by recording the emission of long-wavelength infrared radiation. This heat radiation is detected electronically and displayed with different colors representing different temperatures.  In this image the whiter colors are the hottest.  The windows in homes are a major source of heat loss.
    K07houseA-ir-combo.tif
  • Thermogram of a hot dishwasher and coffee machine.  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..
    dish-washer.jpg
  • A thermogram of a home in winter. The temperature range goes from hot (white) to cold (blue). Thermography is a technique for visualizing the temperature of surfaces by recording the emission of long-wavelength infrared radiation. This heat radiation is detected electronically and displayed with different colors representing different temperatures.  In this image the whiter colors are the hottest.  The windows in homes are a major source of heat loss.
    K07HouseB-IRNW.tif
  • A Thermogram of a young girl curling her hair with a hot iron.  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..
    ir07-174.jpg
  • A thermogram of a home in winter. The temperature range goes from hot (white) to cold (blue). Thermography is a technique for visualizing the temperature of surfaces by recording the emission of long-wavelength infrared radiation. This heat radiation is detected electronically and displayed with different colors representing different temperatures.  In this image the whiter colors are the hottest.  The windows in homes are a major source of heat loss.
    K07HouseD-IR01.tif
  • This image is a combination of two images, one taken in visible light and one taken in infrared light. In the IR thermogram the temperature range goes from hot (white) to cold (blue). Thermography is a technique for visualizing the temperature of surfaces by recording the emission of long-wavelength infrared radiation. This heat radiation is detected electronically and displayed with different colors representing different temperatures.  In this image the whiter colors are the hottest.  The windows in homes are a major source of heat loss.
    K07houseB-ir-combo.tif
  • 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
  • A thermogram of a home in winter. The temperature range goes from hot (white) to cold (blue). Thermography is a technique for visualizing the temperature of surfaces by recording the emission of long-wavelength infrared radiation. This heat radiation is detected electronically and displayed with different colors representing different temperatures.  In this image the whiter colors are the hottest.  The windows in homes are a major source of heat loss.
    K07houseA-IR-NW.tif
  • 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
  • Thermogram of a mouse.  The hot spot to the left is fresh mouse feces.  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..
    ir07-1268.jpg
  • X-ray of a thermos or vacuum flask. The internal chamber (red), and the liquid that it contains, is kept hot or cold by an insulating vacuum.  The vacuum is contained in an aluminum coated glass container.  The internal walls of the flask are coated with aluminum to reflect heat that is radiated away. Most of the heat will be gained or lost through the neck of the flask. .
    K11X-thermos1.jpg
  • A Thermogram of a boy playing with a model rocket while he drinks hot coco.  A Thermogram of a boy with glasses.  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..
    Ir07-1067.jpg
  • This image is a combination of two images, one taken in visible light and one taken in infrared light. In the IR thermogram the temperature range goes from hot (white) to cold (blue). Thermography is a technique for visualizing the temperature of surfaces by recording the emission of long-wavelength infrared radiation. This heat radiation is detected electronically and displayed with different colors representing different temperatures.  In this image the whiter colors are the hottest.  The windows in homes are a major source of heat loss.
    K07houseD-ir-combo2.tif
  • 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
  • X-Ray of a three Habanero Peppers (Capsicum chinense) .  The habanero chile is one of the hottest peppers consumed by people and rates between 100,000 and 300,000 Scoville units.   This pepper originated in South America, but when the Latin name was applied it was belied to have originated in china ? thus the Latin name of china that is now associated with this pepper.
    x07habaneroblue.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 (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. 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 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 (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
  • 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. 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
  • X-Ray of a two jalapeno (Capsicum annuum).  The  jalapeño rates between 2,500 and 10,000 Scoville units in heat.  This pepper originated in South America.
    x07jalapenoBG.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-thermo35C.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
  • X-Ray of a three Habanero Peppers (Capsicum chinense) .  The habanero chile is one of the hottest peppers consumed by people and rates between 100,000 and 300,000 Scoville units.   This pepper originated in South America, but when the Latin name was applied it was belied to have originated in china ? thus the Latin name of china that is now associated with this pepper.
    x07habaneroneg.jpg
  • Thermogram of a girl eating pizza.  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..
    ir07-1149.jpg
  • Thermogram of toast and butter.  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..
    ir07-677.jpg
  • A Thermogram of washing hands.  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..
    ir07-141.jpg
  • X-ray Habanero Chili Pepper.The habanero chili is one of the more intensely piquant species of chili peppers of the Capsicum genus. Unripe habaneros are green, and they color as they mature.
    K15X-Habanero01C.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
  • Marble ws heated in a lime kiln to convert teh mineral to lime.  This is the material used in a limelight lamp.  Limelight also known as calcium light is a type of stage lighting once used in theaters.  A bright light is created when a sample of quicklime (calcium oxide). The light is produced by  incandescence.  The historic use of the light still services as someone in the public eye is still said to be ?in the limelight.? .Lime is produced by heating calcium carbonate until the extra carbon and oxygen atoms are driven off leaving just the calcium oxide.  This process is very easy and takes place in a lime kiln. Lime can be made from sea shells, chalk, and many types of rock - including marble.
    K12lime-marble026.JPG
  • A Thermogram of a coffee machine as it warms up.  This is one image from 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..
    ir07-444.jpg
  • A Thermogram of a boy.  This image is part of a series and has a corresponding visible light image.   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..
    ir07-419.jpg
  • A Thermogram of fireplace.  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..
    ir07-163.jpg
  • Thermogram of two Cinnamon Teal Ducks. (Anas cvanoptera)  Note the warm leg on the duck on the right - the ducks tuck one leg under their feathers to keep warm.  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..
    ir07-1309.jpg
  • Thermogram of a mouse.  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..
    ir07-1181.jpg
  • Thermogram of milk jug and hand.  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..
    ir07-1147.jpg
  • A home in winter.  This image was taken to have a visual photograph to compare with a matching infrared image.  This image is one of a set used to compare a house in visible light to infrared light (heat).
    K07houseD001.TIF
  • Marble ws heated in a lime kiln to convert teh mineral to lime.  This is the material used in a limelight lamp.  Limelight also known as calcium light is a type of stage lighting once used in theaters.  A bright light is created when a sample of quicklime (calcium oxide). The light is produced by  incandescence.  The historic use of the light still services as someone in the public eye is still said to be ?in the limelight.? .Lime is produced by heating calcium carbonate until the extra carbon and oxygen atoms are driven off leaving just the calcium oxide.  This process is very easy and takes place in a lime kiln. Lime can be made from sea shells, chalk, and many types of rock - including marble.
    K12lime-marble051.JPG
  • Limelight also known as calcium light is a type of stage lighting once used in theaters.  A bright light is created when a sample of quicklime (calcium oxide). The light is produced by  incandescence.  The historic use of the light still services as someone in the public eye is still said to be ?in the limelight.? .Lime is produced by heating calcium carbonate until the extra carbon and oxygen atoms are driven off leaving just the calcium oxide.  This process is very easy and takes place in a lime kiln. Lime can be made from sea shells, chalk, and many types of rock - including marble.
    K12lime-chalk013.JPG
  • Limelight also known as calcium light is a type of stage lighting once used in theaters.  A bright light is created when a sample of quicklime (calcium oxide). The light is produced by  incandescence.  The historic use of the light still services as someone in the public eye is still said to be ?in the limelight.? .Lime is produced by heating calcium carbonate until the extra carbon and oxygen atoms are driven off leaving just the calcium oxide.  This process is very easy and takes place in a lime kiln. Lime can be made from sea shells, chalk, and many types of rock - including marble.
    K12lime023.JPG
  • An x ray of a neon light bulb.  THis type of bulb is often used for spectrum experiments.
    x07-bulb12.jpg
  • A Thermogram of a coffee machine as it warms up.  This is one image from 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..
    ir07-445.jpg
  • Thermogram of two ice skaters.  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..
    ir07-273.jpg
  • A boy holds a gun in a bag.  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 see through materials like the plastic bag teh boy is holding.
    ir07-192visible.jpg
  • A Thermogram of a young girl sleeping.  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..
    ir07-1912.jpg
  • Thermogram of an energy efficient fluorescent light.  These lights use less energy than incandescent lights and operate at a cooler temperature.  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..
    ir07-1643.jpg
  • A Thermogram of a young child lost in the woods.  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..
    ir07-1603.jpg
  • Thermogram of penguins.  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..
    ir07-1400.jpg
  • Thermogram of penguins.  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..
    ir07-1398.jpg
  • Thermogram of two White Rhinos (Ceratotherium simum).  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..
    ir07-1362.jpg
  • Thermogram of a woman. This image is part of a series including a matching image in visible light.   The different colors represent different temperatures on the object. The lightest colors are the coldest temperatures, while the darker colors represent a hotter 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..
    ir07-1343.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
  • Thermogram of a Scarlet Ibis. (Eudocimus ruber) 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..
    ir07-1304.jpg
  • Thermogram of a mouse and a snake.  The cold blooded snake is much darker  (cooler) than the mouse.  The warm spot to the right is where the mouse was sitting for a while.   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..
    ir07-1245.jpg
  • Thermogram of a mouse.  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..
    ir07-1224.jpg
  • A Thermogram of an injured hand.  Note the colder temperature of the index finger.  The top part of the finger was lost in an accident.  The lack of blood flow in the finger results in a lower temperature.  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..
    Ir07-105.jpg
  • A Thermogram of a young girl and a cat.  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..
    Ir07-1034.jpg
  • A boy holding up a sheet of black plastic. This image has a corresponding visible light image.  This plastic is opaque to visible light, but is transparent to far-infrared light.  This image was taken inthe far-infrared.  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..
    combo-ir07-350.jpg
  • X-ray image of Chili pepper.  Chili pepper is the fruit of plants from the genus Capsicum, members of the nightshade family, Solanaceae.
    K15X-Chilipeppers02B.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
  • Imperial  Geyser, Yellowstone National Park.  One of the lesser geysers in the park is a wonderful two mile hike from the park highway.  This is also one of the more active geysers in Yellowstone, erupting every few minutes.
    K12-yellowstone032.JPG
  • Imperial  Geyser, Yellowstone National Park.  One of the lesser geysers in the park is a wonderful two mile hike from the park highway.  This is also one of the more active geysers in Yellowstone, erupting every few minutes.
    K12-yellowstone031.JPG
  • Limelight also known as calcium light is a type of stage lighting once used in theaters.  A bright light is created when a sample of quicklime (calcium oxide). The light is produced by  incandescence.  The historic use of the light still services as someone in the public eye is still said to be ?in the limelight.? .Lime is produced by heating calcium carbonate until the extra carbon and oxygen atoms are driven off leaving just the calcium oxide.  This process is very easy and takes place in a lime kiln. Lime can be made from sea shells, chalk, and many types of rock - including marble.
    K12lime020.JPG
  • A seashell was heated in a lime kiln to convert the shell material into lime.  Limelight also known as calcium light is a type of stage lighting once used in theaters.  A bright light is created when a sample of quicklime (calcium oxide). The light is produced by  incandescence.  The historic use of the light still services as someone in the public eye is still said to be ?in the limelight.? .Lime is produced by heating calcium carbonate until the extra carbon and oxygen atoms are driven off leaving just the calcium oxide.  This process is very easy and takes place in a lime kiln. Lime can be made from sea shells, chalk, and many types of rock - including marble.
    K12lime003.JPG
  • A seashell was heated in a lime kiln to convert the shell material into lime.  Limelight also known as calcium light is a type of stage lighting once used in theaters.  A bright light is created when a sample of quicklime (calcium oxide). The light is produced by  incandescence.  The historic use of the light still services as someone in the public eye is still said to be ?in the limelight.? .Lime is produced by heating calcium carbonate until the extra carbon and oxygen atoms are driven off leaving just the calcium oxide.  This process is very easy and takes place in a lime kiln. Lime can be made from sea shells, chalk, and many types of rock - including marble.
    K12lime007.JPG
  • An x ray of a projection light bulb.
    x07-reflector-bulb.jpg
  • Thermogram of children and a computer.  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..
    ir07kids-comp1.jpg
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Ted Kinsman

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