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  • “Yooperlite” is the common name for syenite rich in fluorescent sodalite. These specimens of fluorescent sodalite were recently discovered Michigan.<br />
The specimen was illuminated with shortwave ultraviolet light (UV) that cannot be detected with the camera used for this image. The tissues in the plant absorbed the UV light and fluoresced in the visible spectrum. This technique is called ultraviolet light induced visible light fluorescence (UVIVLF) and is often used in biology to detect unique compounds in samples. This image is part of a series.
    K20-UVIVF_5667.jpg
  • “Yooperlite” is the common name for syenite rich in fluorescent sodalite. These specimens of fluorescent sodalite were recently discovered Michigan. The specimen was illuminated with white light to compare it with the shortwave ultraviolet light (UV) image in this series. This image is part of a series
    K20-UVIVF_5669.jpg
  • This mineral produces a strong yellow color when exposed to long wave ultraviolet (UV) light. Wernerite is a variation of scapolite.  Collected in Grenville Québec, Canada.  Wernerite is considered one of the strongest fluorescent minerals in the long wave.  This mineral was named in the early 1800's by Abraham Gottlob Werner (1749-1817) who was a well known professor of mineralogy in German mineralogy professor.
    K12-Wernerite4005.jpg
  • .This Fluorescent mineral illimaussaq Complex. This specimen contains Polylithionite and Tugtupite that fluoresces red.  Collected on Taseq Slopes Greenland. This is part of a series.
    K12-Tugtupite3991.jpg
  • .This Fluorescent mineral illimaussaq Complex. This specimen contains Polylithionite (green) and Tugtupite that fluoresces red.  Collected on Taseq Slopes Greenland. This is part of a series.
    K12-Tugtupite3988.jpg
  • This mineral produces a strong yellow color when exposed to long wave ultraviolet (UV) light. Wernerite is a variation of scapolite.  Collected in Grenville Québec, Canada.  Wernerite is considered one of the strongest fluorescent minerals in the long wave.  This mineral was named in the early 1800's by Abraham Gottlob Werner (1749-1817) who was a well known professor of mineralogy in German mineralogy professor.
    K12-Wernerite4001.jpg
  • Ripe bananas in Ultra Violet (UV) light.  This is part of a pair of image to compare bananas in normal light and UV light.  The stressed cells around the brown spots glow under the UV light.
    K11-UVbanana002.JPG
  • willemite photographed in short wave uv light.  Calcite (red), willemite (green) and franklinite (black) from New Jersey, photographed under short-wave ultraviolet light.  Part of a series of the specimen in different lights.
    K12-willemite3998.jpg
  • A specimen of Diopside (blue-green in UV), Humite (yellow in UV) and Calcite (red in UV) collected from the Long Lake Zinc Mine in Frontenac County, Ontario, Canada.  Photographed under short-wave ultraviolet light.  Part of a series of the specimen in different lights.
    K12-UVDiopside8715.jpg
  • willemite photographed in short wave uv light on the laft and white light on teh right - the two images are digitaly combined.  Calcite (red), willemite (green) and franklinite (black) from New Jersey, photographed under short-wave ultraviolet light.  Part of a series of the specimen in different lights.
    K12-willemite3998combo.jpg
  • Calcite (red), willemite (green) and franklinite (black) from New Jersey, photographed under short-wave ultraviolet light.  Part of a series of the specimen in different lights.
    K12-UVroc3983.JPG
  • A specimen of Diopside (blue-green in UV), Humite (yellow in UV) and Calcite (red in UV) collected from the Long Lake Zinc Mine in Frontenac County, Ontario, Canada.  Photographed under short-wave ultraviolet light.  Part of a series of the specimen in different lights.
    K12-UVDiopside8709.jpg
  • Hackmanite is an important variety of sodalite exhibiting Florescence.  This specimen hackmanite is from Ontario Canada.  Photographed under white light.  Part of a series of the specimen in different lights.
    K12-UVHackmanite8703.jpg
  • Two different lights combind into one image.  The left part is UV light, while the right part is white light.  A specimen of Diopside (blue-green in UV), Humite (yellow in UV) and Calcite (red in UV) collected from the Long Lake Zinc Mine in Frontenac County, Ontario, Canada.  Photographed under short-wave ultraviolet light.  Part of a series of the specimen in different lights.
    K12-UVDiopside87combo.jpg
  • Calcite , willemite  and franklinite  from New Jersey, photographed in visible light.  Part of a series of the specimen in different lights.
    K12-UVroc3981.JPG
  • A specimen of Diopside (blue-green in UV), Humite (yellow in UV) and Calcite (red in UV) collected from the Long Lake Zinc Mine in Frontenac County, Ontario, Canada.  Photographed under short-wave ultraviolet light.  Part of a series of the specimen in different lights.
    K12-UVDiopside8716.jpg
  • A specimen of Diopside (blue-green in UV), Humite (yellow in UV) and Calcite (red in UV) collected from the Long Lake Zinc Mine in Frontenac County, Ontario, Canada.  Photographed under short-wave ultraviolet light.  Part of a series of the specimen in different lights.
    K12-UVDiopside8712.jpg
  • Calcite (red), willemite (green) and franklinite (black) from New Jersey, photographed under short-wave ultraviolet light.  Part of a series of the specimen in different lights.
    K12-UVroc8696.jpg
  • willemite photographed in long wave uv light.  Calcite (red), willemite (green) and franklinite (black) from New Jersey, photographed under long-wave ultraviolet light.  Part of a series of the specimen in different lights.
    K12-willemite3996.jpg
  • Willemite photographed in lwhite light.  Calcite, willemite and franklinite (black) from New Jersey.  Part of a series of the specimen in different lights.
    K12-willemite3993.jpg
  • Calcite , willemite  and franklinite (black) from New Jersey, photographed under white light.  Part of a series of the specimen in different lights.
    K12-UVroc8694.jpg
  • Hackmanite is an important variety of sodalite exhibiting Florescence.  This specimen hackmanite is from Ontario Canada.  Photographed under short-wave ultraviolet light.  Part of a series of the specimen in different lights.
    K12-UVHackmanite8707.jpg
  • Fluorescent Coral in Long Wave UV light. A close up image of Favia sp. Coral. This species of coral glows brightly when illuminated in long wave ultra-violet (UV) light.  Favia is a genus of reef building stony corals in the family Faviidae.  This image is part of a series showing the identical specimen in white light and UV light.
    K12UVcorals042.JPG
  • An image of Cycloseris erosa coral in Short wave UV Light showing green Fluorescence.  This species of coral will glow brightly when illuminated in ultra-violet(UV) light.  Corals in the genus Cycloseris are mostly solitary and free living, some attaining 10 centimetres in diameter. The discs are either round or oval and the central mouth, which is surrounded by tentacles, may be a slit. The polyp sits in a calcareous cup, the corallite, and only extends its tentacles to feed at night. It is thought the glow may attract symbiotic algae, or protect the coral from the intense ultraviolet light of the Sun in shallow water. This image is part of a series showing the identical specimen in white light and UV light.
    K12UVcorals033.JPG
  • An image of Pectinia species coral in Long wave UV Light showing green Fluorescence.  This species of coral will glow brightly when illuminated in ultra-violet(UV) light.  Each head of coral is formed by a colony of genetically identical polyps which secrete a hard skeleton of calcium carbonate; this makes them important coral reef builders. It is thought the glow may attract symbiotic algae, or protect the coral from the intense ultraviolet light of the Sun in shallow water. This image is part of a series showing the identical specimen in white light and UV light.
    K12UVcorals012.JPG
  • An image of Acanthastrea lordhowensis coral in Long wave UV Light showing orange Fluorescence.  This species of coral will glow brightly when illuminated in ultra-violet(UV) light.  Each head of coral is formed by a colony of genetically identical polyps which secrete a hard skeleton of calcium carbonate; this makes them important coral reef builders. It is thought the glow may attract symbiotic algae, or protect the coral from the intense ultraviolet light of the Sun in shallow water. This image is part of a series showing the identical specimen in white light and UV light..
    K12UVcorals007.JPG
  • Fluorescent Coral in Short Wave UV light. A close up image of Favia sp. Coral. This species of coral glows brightly when illuminated in short wave ultra-violet (UV) light.  Favia is a genus of reef building stony corals in the family Faviidae.  This image is part of a series showing the identical specimen in white light and UV light.
    K12UVcorals043.JPG
  • An image of Cycloseris erosa coral in Long wave UV Light showing green Fluorescence.  This species of coral will glow brightly when illuminated in ultra-violet(UV) light.  Corals in the genus Cycloseris are mostly solitary and free living, some attaining 10 centimetres in diameter. The discs are either round or oval and the central mouth, which is surrounded by tentacles, may be a slit. The polyp sits in a calcareous cup, the corallite, and only extends its tentacles to feed at night. It is thought the glow may attract symbiotic algae, or protect the coral from the intense ultraviolet light of the Sun in shallow water. This image is part of a series showing the identical specimen in white light and UV light.
    K12UVcorals036.JPG
  • An image of Favites pentagona coral in Long wave UV Light showing green and orange Fluorescence.  This species of coral will glow brightly when illuminated in ultra-violet(UV) light.  Each head of coral is formed by a colony of genetically identical polyps which secrete a hard skeleton of calcium carbonate; this makes them important coral reef builders. It is thought the glow may attract symbiotic algae, or protect the coral from the intense ultraviolet light of the Sun in shallow water. This image is part of a series showing the identical specimen in white light and UV light.
    K12UVcorals006.JPG
  • Fluorescent Coral in White Light. An image of Pectinia species coral in white light. This species of coral will grow brightly when illuminated in ultra-violet(UV) light.  Each head of coral is formed by a colony of genetically identical polyps which secrete a hard skeleton of calcium carbonate; this makes them important coral reef builders. This image is part of a series showing the identical specimen in white light and UV light..
    K12UVcorals001.jpg
  • An image of Cycloseris erosa coral in white Light showing green Fluorescence.  This species of coral will glow brightly when illuminated in ultra-violet(UV) light.  Corals in the genus Cycloseris are mostly solitary and free living, some attaining 10 centimetres in diameter. The discs are either round or oval and the central mouth, which is surrounded by tentacles, may be a slit. The polyp sits in a calcareous cup, the corallite, and only extends its tentacles to feed at night. It is thought the glow may attract symbiotic algae, or protect the coral from the intense ultraviolet light of the Sun in shallow water. This image is part of a series showing the identical specimen in white light and UV light.
    K12UVcorals037.JPG
  • Fluorescent Coral in White and UV Light. An image of Pectinia species coral in white light. This species of coral will grow brightly when illuminated in ultra-violet(UV) light.  Each head of coral is formed by a colony of genetically identical polyps which secrete a hard skeleton of calcium carbonate; this makes them important coral reef builders. This image is part of a series showing the identical specimen in white light and UV light..
    K12UVcorals011.JPG
  • Fluorescent Coral in White Light. An image of Pectinia species coral in white light. This species of coral will grow brightly when illuminated in ultra-violet(UV) light.  Each head of coral is formed by a colony of genetically identical polyps which secrete a hard skeleton of calcium carbonate; this makes them important coral reef builders. This image is part of a series showing the identical specimen in white light and UV light..
    K12UVcorals010.JPG
  • Fluorescent Coral in White Light. An image of Pectinia species coral in white light. This species of coral will grow brightly when illuminated in ultra-violet(UV) light.  Each head of coral is formed by a colony of genetically identical polyps which secrete a hard skeleton of calcium carbonate; this makes them important coral reef builders. This image is part of a series showing the identical specimen in white light and UV light..
    K12UVcorals003.JPG
  • An X-Ray of a fluorescent light.  This compact design is used in emergency exit signs.
    x07fluorescentlightblue.jpg
  • An image of Cycloseris erosa coral in Long wave UV Light showing green Fluorescence.  This species of coral will glow brightly when illuminated in ultra-violet(UV) light.  Corals in the genus Cycloseris are mostly solitary and free living, some attaining 10 centimetres in diameter. The discs are either round or oval and the central mouth, which is surrounded by tentacles, may be a slit. The polyp sits in a calcareous cup, the corallite, and only extends its tentacles to feed at night. It is thought the glow may attract symbiotic algae, or protect the coral from the intense ultraviolet light of the Sun in shallow water. This image is part of a series showing the identical specimen in white light and UV light.
    K12UVcorals034.JPG
  • An image of Cycloseris erosa coral in white Light showing green Fluorescence.  This species of coral will glow brightly when illuminated in ultra-violet(UV) light.  Corals in the genus Cycloseris are mostly solitary and free living, some attaining 10 centimetres in diameter. The discs are either round or oval and the central mouth, which is surrounded by tentacles, may be a slit. The polyp sits in a calcareous cup, the corallite, and only extends its tentacles to feed at night. It is thought the glow may attract symbiotic algae, or protect the coral from the intense ultraviolet light of the Sun in shallow water. This image is part of a series showing the identical specimen in white light and UV light.
    K12UVcorals032.JPG
  • Fluorescent Coral in white light. A close up image of Favia sp. Coral. This species of coral glows brightly when illuminated in ultra-violet (UV) light.  Favia is a genus of reef building stony corals in the family Faviidae.  This image is part of a series showing the identical specimen in white light and UV light.
    K12UVcorals041.JPG
  • An image of Pectinia species coral in Long wave UV Light showing green Fluorescence.  This species of coral will glow brightly when illuminated in ultra-violet(UV) light.  Each head of coral is formed by a colony of genetically identical polyps which secrete a hard skeleton of calcium carbonate; this makes them important coral reef builders. This image is part of a series showing the identical specimen in white light and UV light.
    K12UVcorals002.jpg
  • Fluorescent light is used to image the bud of a cannabis plant. The trichomes on the bud of a cannabis (Cannabis sativa) plant are full of Tetrahydrocannabinol (THC)and glow green. The chlorophyll filled cells of the leaf glow red. The width of the green trichome heads is 90 um, or about the width of a human hair. This is an example of a plant that is past harvest time as the THC laden trichome heads have started to shrivel.
    K18glow-cannabisbud17-10ZSA.jpg
  • Apheloria virginiensis is a large North American millipede. It is known to secrete cyanide compounds as a defense. It is recommended that one wash hands after handling this organism as the toxic compounds it secretes are poisonous and can cause extreme irritation if rubbed in the eyes. This image is part of a set showing the millipede in white light an din ultraviolet (UV) light. Why this animal is fluorescent under UV light is unknown.
    K19-millipede014.jpg
  • Apheloria virginiensis is a large North American millipede. It is known to secrete cyanide compounds as a defense. It is recommended that one wash hands after handling this organism as the toxic compounds it secretes are poisonous and can cause extreme irritation if rubbed in the eyes. This image is part of a set showing the millipede in white light an din ultraviolet (UV) light. Why this animal is fluorescent under UV light is unknown.
    K19-millipede012.jpg
  • Fluorescent light is used to image the bud of a cannabis plant. The trichomes on the bud of a cannabis (Cannabis sativa) plant are full of Tetrahydrocannabinol (THC)and glow green. The chlorophyll filled cells of the leaf glow red. The width of the green trichome heads is 90 um
    K18glow-cannabisbud1710110903A.jpg
  • Apheloria virginiensis is a large North American millipede. It is known to secrete cyanide compounds as a defense. It is recommended that one wash hands after handling this organism as the toxic compounds it secretes are poisonous and can cause extreme irritation if rubbed in the eyes. This image is part of a set showing the millipede in white light an din ultraviolet (UV) light. Why this animal is fluorescent under UV light is unknown.
    K19-millipede016.jpg
  • Apheloria virginiensis is a large North American millipede. It is known to secrete cyanide compounds as a defense. It is recommended that one wash hands after handling this organism as the toxic compounds it secretes are poisonous and can cause extreme irritation if rubbed in the eyes. This image is part of a set showing the millipede in white light an din ultraviolet (UV) light. Why this animal is fluorescent under UV light is unknown.
    K19-millipede025.jpg
  • Fluorescent light is used to image the bud of a cannabis plant. The trichomes on the bud of a cannabis (Cannabis sativa) plant are full of Tetrahydrocannabinol (THC)and glow green. The chlorophyll filled cells of the leaf glow red. The width of the green trichome heads is 90 um, or about the width of a human hair. This is an example of a plant that is past harvest time as the THC laden trichome heads have started to shrivel.
    K18glow-cannabisCS-442A.jpg
  • Apheloria virginiensis is a large North American millipede. It is known to secrete cyanide compounds as a defense. It is recommended that one wash hands after handling this organism as the toxic compounds it secretes are poisonous and can cause extreme irritation if rubbed in the eyes. This image is part of a set showing the millipede in white light an din ultraviolet (UV) light. Why this animal is fluorescent under UV light is unknown.
    K19-millipede025B.jpg
  • Kiwi fruit, (Actinidia deliciosa). The specimen was illuminated with shortwave ultraviolet light (UV) that cannot be detected with the camera used for this image. The tissues in the plant absorbed the UV light and fluoresced in the visible spectrum. This technique is called ultraviolet light induced visible light fluorescence (UVIVLF) and is often used in biology to detect unique compounds in samples. This image is part of a series
    K20-UVIVF_4473.jpg
  • Kiwi fruit, (Actinidia deliciosa). The specimen was illuminated with shortwave ultraviolet light (UV) that cannot be detected with the camera used for this image. The tissues in the plant absorbed the UV light and fluoresced in the visible spectrum. This technique is called ultraviolet light induced visible light fluorescence (UVIVLF) and is often used in biology to detect unique compounds in samples. This image is part of a series
    K20-UVIVF_4468.jpg
  • A Black walnut fruit (Juglans nigra). The specimen was illuminated with shortwave ultraviolet light (UV) that cannot be detected with the camera used for this image. The tissues in the plant absorbed the UV light and fluoresced in the visible spectrum. This technique is called ultraviolet light induced visible light fluorescence (UVIVLF) and is often used in biology to detect unique compounds in samples. This image is part of a series
    K20-UVIVF_4392.jpg
  • Daffodil flower as seen in UV light. The specimen was illuminated with shortwave ultraviolet light (UV) that cannot be detected with the camera used for this image. The tissues in the plant absorbed the UV light and fluoresced in the visible spectrum. This technique is called ultraviolet light induced visible light fluorescence (UVIVLF) and is often used in biology to detect unique compounds in samples. This image is part of a series.
    K20-C_3541UVVF.jpg
  • Daffodil flower as seen in UV light. The specimen was illuminated with shortwave ultraviolet light (UV) that cannot be detected with the camera used for this image. The tissues in the plant absorbed the UV light and fluoresced in the visible spectrum. This technique is called ultraviolet light induced visible light fluorescence (UVIVLF) and is often used in biology to detect unique compounds in samples. This image is part of a series.
    K20-D_3539UVVF.jpg
  • Flint corn (Zea mays indurata) commonly known as Indian corn is the same species but a variant of maize.  The specimen was illuminated with shortwave ultraviolet light (UV) that cannot be detected with the camera used for this image. The tissues in the plant absorbed the UV light and fluoresced in the visible spectrum. This technique is called ultraviolet light induced visible light fluorescence (UVIVLF) and is often used in biology to detect unique compounds in samples. This image is part of a series
    K20-UVIVF_4530.jpg
  • Flint corn (Zea mays indurata) commonly known as Indian corn is the same species but a variant of maize.  The specimen was illuminated with shortwave ultraviolet light (UV) that cannot be detected with the camera used for this image. The tissues in the plant absorbed the UV light and fluoresced in the visible spectrum. This technique is called ultraviolet light induced visible light fluorescence (UVIVLF) and is often used in biology to detect unique compounds in samples. This image is part of a series
    K20-UVIVF_4524.jpg
  • Kiwano fruits (Cucumis metuliferus). The specimen was illuminated with shortwave ultraviolet light (UV) that cannot be detected with the camera used for this image. The tissues in the plant absorbed the UV light and fluoresced in the visible spectrum. This technique is called ultraviolet light induced visible light fluorescence (UVIVLF) and is often used in biology to detect unique compounds in samples. This image is part of a series
    K20-UVIVF_4520.jpg
  • Kiwano fruits (Cucumis metuliferus). The specimen was illuminated with shortwave ultraviolet light (UV) that cannot be detected with the camera used for this image. The tissues in the plant absorbed the UV light and fluoresced in the visible spectrum. This technique is called ultraviolet light induced visible light fluorescence (UVIVLF) and is often used in biology to detect unique compounds in samples. This image is part of a series
    K20-UVIVF_4516.jpg
  • Kiwano fruits (Cucumis metuliferus). The specimen was illuminated with shortwave ultraviolet light (UV) that cannot be detected with the camera used for this image. The tissues in the plant absorbed the UV light and fluoresced in the visible spectrum. This technique is called ultraviolet light induced visible light fluorescence (UVIVLF) and is often used in biology to detect unique compounds in samples. This image is part of a series
    K20-UVIVF_4504.jpg
  • Kiwi fruit, (Actinidia deliciosa). The specimen was illuminated with shortwave ultraviolet light (UV) that cannot be detected with the camera used for this image. The tissues in the plant absorbed the UV light and fluoresced in the visible spectrum. This technique is called ultraviolet light induced visible light fluorescence (UVIVLF) and is often used in biology to detect unique compounds in samples. This image is part of a series
    K20-UVIVF_4467.jpg
  • A browning banana. The specimen was illuminated with shortwave ultraviolet light (UV) that cannot be detected with the camera used for this image. There was a small amout of white light added to the exposure to show the yellow of the banana. The tissues in the plant absorbed the UV light and fluoresced in the visible spectrum. This technique is called ultraviolet light induced visible light fluorescence (UVIVLF) and is often used in biology to detect unique compounds in samples. This image is part of a series
    K20-UVIVF_4448.jpg
  • A seed pod of the thorn apple (Datura stramonium). The specimen was illuminated with shortwave ultraviolet light (UV) that cannot be detected with the camera used for this image. The tissues in the plant absorbed the UV light and fluoresced in the visible spectrum. This technique is called ultraviolet visible light fluorescence and is often used in biology to detect unique compounds in samples. This image is part of a series
    K20-UVIVF_4402.jpg
  • Daffodil flower as seen in UV light. The specimen was illuminated with shortwave ultraviolet light (UV) that cannot be detected with the camera used for this image. The tissues in the plant absorbed the UV light and fluoresced in the visible spectrum. This technique is called ultraviolet light induced visible light fluorescence (UVIVLF) and is often used in biology to detect unique compounds in samples. This image is part of a series.
    K20-B_3551UVVF.jpg
  • Daffodil flower as seen in UV light. The specimen was illuminated with shortwave ultraviolet light (UV) that cannot be detected with the camera used for this image. The tissues in the plant absorbed the UV light and fluoresced in the visible spectrum. This technique is called ultraviolet light induced visible light fluorescence (UVIVLF) and is often used in biology to detect unique compounds in samples. This image is part of a series.
    K20-A_3552UVVF.jpg
  • A browning banana. The specimen was illuminated with shortwave ultraviolet light (UV) that cannot be detected with the camera used for this image. The tissues in the plant absorbed the UV light and fluoresced in the visible spectrum. This technique is called ultraviolet light induced visible light fluorescence (UVIVLF) and is often used in biology to detect unique compounds in samples. This image is part of a series
    K20-UVIVF_4440.jpg
  • An image of Acanthastrea lordhowensis coral in white light.  This species of coral will glow brightly when illuminated in ultra-violet(UV) light.  Each head of coral is formed by a colony of genetically identical polyps which secrete a hard skeleton of calcium carbonate; this makes them important coral reef builders. It is thought the glow may attract symbiotic algae, or protect the coral from the intense ultraviolet light of the Sun in shallow water. This image is part of a series showing the identical specimen in white light and UV light.
    K12UVcorals009.JPG
  • An image of Acanthastrea lordhowensis coral in white light.  This species of coral will glow brightly when illuminated in ultra-violet(UV) light.  Each head of coral is formed by a colony of genetically identical polyps which secrete a hard skeleton of calcium carbonate; this makes them important coral reef builders. It is thought the glow may attract symbiotic algae, or protect the coral from the intense ultraviolet light of the Sun in shallow water. This image is part of a series showing the identical specimen in white light and UV light.
    K12UVcorals008.JPG
  • An image of Favites pentagona coral in white Light.  This species of coral will glow brightly when illuminated in ultra-violet(UV) light.  Each head of coral is formed by a colony of genetically identical polyps which secrete a hard skeleton of calcium carbonate; this makes them important coral reef builders. It is thought the glow may attract symbiotic algae, or protect the coral from the intense ultraviolet light of the Sun in shallow water. This image is part of a series showing the identical specimen in white light and UV light.
    K12UVcorals005.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
  • An image of Caulastrea Curata coral in white light.  This species of coral will glow brightly when illuminated in ultra-violet(UV) light.  It is thought the glow may attract symbiotic algae, or protect the coral from the intense ultraviolet light of the Sun in shallow water. This image is part of a series showing the identical specimen in white light and UV light.
    K12UVcorals040.JPG
  • An image of Stichodactyla taptum anemone in short wave UV Light showing Fluorescence.  This species of anemone will glow brightly when illuminated in ultra-violet(UV) light.  It is thought the glow may protect the anemone from the intense ultraviolet light of the Sun in shallow water. This image is part of a series showing the identical specimen in white light and UV light.
    K12UVcorals030.JPG
  • An image of Stichodactyla taptum anemone in long wave UV Light showing Fluorescence.  This species of anemone will glow brightly when illuminated in ultra-violet(UV) light.  It is thought the glow may protect the anemone from the intense ultraviolet light of the Sun in shallow water. This image is part of a series showing the identical specimen in white light and UV light.
    K12UVcorals029.JPG
  • An image of Scolymia australis coral white Light.  This species of coral will glow brightly when illuminated in ultra-violet(UV) light.  Each head of coral is formed by a colony of genetically identical polyps which secrete a hard skeleton of calcium carbonate; this makes them important coral reef builders. It is thought the glow may attract symbiotic algae, or protect the coral from the intense ultraviolet light of the Sun in shallow water. This image is part of a series showing the identical specimen in white light and UV light.
    K12UVcorals004.JPG
  • Crookes tube. Invented by William Crookes (1832 - 1919) in the late 19th century.  This apparatus was used to investigate the path taken by electrons or cathode rays as they were called then.   In this experiment the electrons are emitted from a central disc towards the glass.  As the electrons collide with the glass they fluoresce.   The metal star pattern blocks the electrons causing a shadow on the glass.  Crookes showed from the resulting shadow that electrons travel in straight lines.  The overall glow of the apparatus is caused by the excitation of the remaining gas molecules in the tube.
    K08crookes0372.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..
    ir07-1652.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..
    ir07-1641.jpg
  • An image of Caulastrea Curata coral in long wave UV light.  This species of coral will glow brightly when illuminated in ultra-violet(UV) light.  It is thought the glow may attract symbiotic algae, or protect the coral from the intense ultraviolet light of the Sun in shallow water. This image is part of a series showing the identical specimen in white light and UV light.
    K12UVcorals039.JPG
  • An image of Stichodactyla taptum anemone in unfiltered UV Light showing Fluorescence.  In this image there is a large amout of blue light that is so bright is it difficult to see the florescent tissues.  This iis what a diver would see with out the blue blocking filter.  This species of anemone will glow brightly when illuminated in ultra-violet(UV) light.  It is thought the glow may protect the anemone from the intense ultraviolet light of the Sun in shallow water. This image is part of a series showing the identical specimen in white light and UV light.
    K12UVcorals027.JPG
  • An image of Stichodactyla taptum anemone in short wave UV Light showing Fluorescence.  This species of anemone will glow brightly when illuminated in ultra-violet(UV) light.  It is thought the glow may protect the anemone from the intense ultraviolet light of the Sun in shallow water. This image is part of a series showing the identical specimen in white light and UV light.
    K12UVcorals024.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..
    ir07-1654.jpg
  • An image of Stichodactyla taptum anemone in white Light showing Fluorescence.  This species of anemone will glow brightly when illuminated in ultra-violet(UV) light.  It is thought the glow may protect the anemone from the intense ultraviolet light of the Sun in shallow water. This image is part of a series showing the identical specimen in white light and UV light.
    K12UVcorals031.JPG
  • This image is part of a series showing the new security features of the United States 100 dollar bill.  These anti-counterfeit features include micro-print, watermarks, lenticular images, special inks, fluorescent fibers and strips, colored fibers, and the use of full colored inks.  In particular this image shows the lenticular lens array that shows a pattern of different colors as the viewing angle of the money is changed. This is a Scanning electron microscope image that is 4 mm wide.  When printed 10 cm wide the magnification is 250 x
    K13SEM-new100lenticular-A.jpg
  • This is a scanning electron microscope image of the This image is part of a series showing the new security features of the United States 100 dollar bill.  These anti-counterfeit features include micro-print, watermarks, lenticular images, special inks, fluorescent fibers and strips, colored fibers, and the use of full colored inks.  In particular this image shows the micro-lens, or lenticular array that shows a differnt color when the viewing angle is changed. Magnification is 125x when printed 10 cm wide.
    K13-SEM100bill-003.jpg
  • This is a scanning electron microscope image of the This image is part of a series showing the new security features of the United States 100 dollar bill.  These anti-counterfeit features include micro-print, watermarks, lenticular images, special inks, fluorescent fibers and strips, colored fibers, and the use of full colored inks.  In particular this image shows the micro-lens, or lenticular array that shows a differnt color when the viewing angle is changed.
    K13-SEM100bill-002.jpg
  • This is a scanning electron microscope image of the new 100 dollar bill. This image is part of a series showing the new security features of the United States 100 dollar bill.  These anti-counterfeit features include micro-print, watermarks, lenticular images, special inks, fluorescent fibers and strips, colored fibers, and the use of full colored inks.  In particular this image shows the micro-lens, or lenticular array that shows a differnt color when the viewing angle is changed. Magnification is 250x when printed 10 cm wide.
    K13-SEM100bill-paper002.jpg
  • X-ray of an energy efficient light bulb.
    K11-xbulbsc2.jpg
  • X-ray of an energy efficient light bulb.
    K11-xbulbsc1.jpg
  • Kiwano fruits (Cucumis metuliferus).  The specimen was illuminated with white light to compare it with the shortwave ultraviolet light (UV) image in this series. This image is part of a series
    K20-UVIVF_4519.jpg
  • Kiwano fruits (Cucumis metuliferus).  The specimen was illuminated with white light to compare it with the shortwave ultraviolet light (UV) image in this series. This image is part of a series
    K20-UVIVF_4505.jpg
  • Kiwi fruit, (Actinidia deliciosa). The specimen was illuminated with white light to compare it with the shortwave ultraviolet light (UV) image in this series. This image is part of a series
    K20-UVIVF_4472.jpg
  • X-ray of an energy efficient light bulb. This buld uses Light emmitting diode (LED) technology. THis is a false color x-ray.
    K14X-LED-bulb01C.jpg
  • Kiwi fruit, (Actinidia deliciosa). The specimen was illuminated with white light to compare it with the shortwave ultraviolet light (UV) image in this series. This image is part of a series
    K20-UVIVF_4469.jpg
  • X-ray of an energy efficient light bulb. This bulb uses Light emmitting diode (LED) technology.
    K15X-newLED002D.jpg
  • X-ray of an energy efficient light bulb. This buld uses Light emmitting diode (LED) technology. THis is a false color x-ray.
    K14X-LED-bulb01.jpg
  • X-ray of an energy efficient light bulb.
    K12X-light3comboB.jpg
  • X-ray of an energy efficient light bulb.
    K12X-light3A.jpg
  • An energy efficient light bulb.
    K12X-light3-optical.jpg
  • Flint corn (Zea mays indurata) commonly known as Indian corn is the same species but a variant of maize.  The specimen was illuminated with white light to compare it with the shortwave ultraviolet light (UV) image in this series. This image is part of a series
    K20-UVIVF_4529.jpg
  • Kiwano fruits (Cucumis metuliferus).  The specimen was illuminated with white light to compare it with the shortwave ultraviolet light (UV) image in this series. This image is part of a series
    K20-UVIVF_4517.jpg
  • A seed pod of the thorn apple (Datura stramonium). The specimen was illuminated with white light to compare it with the shortwave ultraviolet light (UV) image in this series. This image is part of a series
    K20-UVIVF_4400.jpg
  • A Black walnut fruit (Juglans nigra). The specimen was illuminated with white light to compare it with the shortwave ultraviolet light (UV) image in this series. This image is part of a series
    K20-UVIVF_4393.jpg
  • Daffodil flower as seen in white light. The specimen was illuminated with white light to compare it with the shortwave ultraviolet light (UV) image in this series. This image is part of a series
    K20-C_3543white.jpg
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Ted Kinsman

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