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  • Female mosquito head (family Culicidae).  The individual eye lenses detect levels of light and dark in different directions.  Several mosquito species are vectors for human diseases, including malaria and yellow fever.   This is a scanning electron microscope image.  The calibration bar is 200 um and the magnification is 243 x.
    K08semmosquito-C012.jpg
  • Female mosquito head (family Culicidae).  The individual eye lenses detect levels of light and dark in different directions.  Several mosquito species are vectors for human diseases, including malaria and yellow fever.   This is a scanning electron microscope image.  The calibration bar is 100 um and the magnification is 689 x.
    K08semmosquito-c010A.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
  • Female mosquito head (family Culicidae).  The individual eye lenses detect levels of light and dark in different directions.  Several mosquito species are vectors for human diseases, including malaria and yellow fever.   This is a scanning electron microscope image.  The calibration bar is 100 um and the magnification is 689 x.
    K08semmosquito-c010.jpg
  • The anti-reflection structures on the surface of one eye element on the head of a female mosquito.  (family Culicidae).  These bump structures interact with the wave nature of light to increase the transmission of light into the eye by decreasing the reflected light.  Structures such as this are beginning to be incorporated into modern optical devices    This is a scanning electron microscope image.  The calibration bar is 1 um and the magnification is 9220 x.
    K08semmosquito-b10red.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..
    ir07-1891.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..
    ir07-1870.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..
    ir07-1750.jpg
  • The scales found on the back of a mosquito (family Culicidae).  These scales decrease fluid flow across the surface of the mosquito and allow it to fly with less energy.  Several mosquito species are vectors for human diseases, including malaria and yellow fever.   This is a scanning electron microscope image.  The calibration bar is 10 um and the magnification is 360 x..
    K08semmosquito-b11.jpg
  • Female mosquito proboscis (family Culicidae).  This sharp tip is used to suck blood as a food source.  Only female mosquitoes suck blood. Several mosquito species are vectors for human diseases, including malaria and yellow fever. .
    K08semmosquito-b02B.jpg
  • Female mosquito eye (family Culicidae).  The individual eye lenses detect levels of light and dark in different directions.  Several mosquito species are vectors for human diseases, including malaria and yellow fever.   This is a scanning electron microscope image.  The calibration bar is 10 um and the magnification is 826x.
    K08semmosquito-b07red.jpg
  • Female mosquito eye (family Culicidae).  The individual eye lenses detect levels of light and dark in different directions.  Several mosquito species are vectors for human diseases, including malaria and yellow fever.   This is a scanning electron microscope image.  The calibration bar is 10 um and the magnification is 407 x.
    K08semmosquito-b06.jpg
  • Female mosquito head (family Culicidae).  The individual eye lenses detect levels of light and dark in different directions.  Several mosquito species are vectors for human diseases, including malaria and yellow fever.   This is a scanning electron microscope image.  The calibration bar is 100 um and the magnification is 156 x.
    K08semmosquito-b03.jpg
  • SEM of a mutant fruit fly. Scanning Electron Micrograph (SEM) of the head of a mutant fruit fly (Drosophila melanogaster). This mutant has abnormal head parts due to the ?ant mutation?.  Fruit flies are widely used in genetic experiments, particularly in mutation experiments, because they reproduce rapidly and their genetic systems are well understood.
    K07sem-fruitfly4.jpg
  • SEM of a mutant fruit fly. Scanning Electron Micrograph (SEM) of the head of a mutant fruit fly (Drosophila melanogaster). This mutant has abnormal size eyes ? they are smaller than normal and are due to the ?eyeless mutation?.  Fruit flies are widely used in genetic experiments, particularly in mutation experiments, because they reproduce rapidly and their genetic systems are well understood.
    K07sem-fruitFLY2.jpg
  • Blood droplet. In forensic science, the pattern created by projected blood is analyzed to determine information about the origin on the body, the weapon used and the number of blows, the relative position of the victim and assailant, and the sequence of events. This is a single drop that fell 20 cm onto a flat paper surface.
    bloodsplatter-20cm_0208.jpg
  • SEM of a mutant fruit fly. Scanning Electron Micrograph (SEM) of the head of a mutant fruit fly (Drosophila melanogaster). This mutant has abnormal antena due to the ?ant? mutation.  Fruit flies are widely used in genetic experiments, particularly in mutation experiments, because they reproduce rapidly and their genetic systems are well understood.
    K07SEM-fruitfly3.jpg
  • SEM of a mutant fruit fly. Scanning Electron Micrograph (SEM) of the head of a mutant fruit fly (Drosophila melanogaster). This mutant has abnormal bar shaped eyes ? they are smaller than normal and are due to the ?bar mutation?.  Fruit flies are widely used in genetic experiments, particularly in mutation experiments, because they reproduce rapidly and their genetic systems are well understood.
    K07SEM-fruitfly-bareye2.jpg
  • Blood droplet. In forensic science, the pattern created by projected blood is analyzed to determine information about the origin on the body, the weapon used and the number of blows, the relative position of the victim and assailant, and the sequence of events. This is a single drop that fell 20 cm onto a paper surface angled at 45 degrees to the horizontal.
    bloodsplatter-20cm-45deg_0202.jpg
  • These  pointed scales are also known as dermal teeth. They give the shark's skin the feel of sandpaper.  The scales disrupt turbulence over the skin, considerably reducing the drag on the shark as it swims.  The reduction in fluid drag allows the shark to swim with less energy.  This unique design is duplicated in swimsuits and other surfaces that move through the water. The scale bar is 100 um and the magnification is 129x.
    K08sem-sharkskin05lines.jpg
  • Blood droplet. In forensic science, the pattern created by projected blood is analyzed to determine information about the origin on the body, the weapon used and the number of blows, the relative position of the victim and assailant, and the sequence of events. This is a single drop that fell 20 cm onto a flat paper surface.
    bloodsplatter-21cm_0188.jpg
  • Blood droplet. In forensic science, the pattern created by projected blood is analyzed to determine information about the origin on the body, the weapon used and the number of blows, the relative position of the victim and assailant, and the sequence of events. This is a single drop that fell 20 cm onto a flat paper surface.
    bloodsplatter-21cm_0186.jpg
  • Blood droplet. In forensic science, the pattern created by projected blood is analyzed to determine information about the origin on the body, the weapon used and the number of blows, the relative position of the victim and assailant, and the sequence of events. This is a single drop that fell 20 cm onto a paper surface angled at 75 degrees to the horizontal.
    bloodsplatter-20cm-75deg_0199.jpg
  • Blood droplet. In forensic science, the pattern created by projected blood is analyzed to determine information about the origin on the body, the weapon used and the number of blows, the relative position of the victim and assailant, and the sequence of events. This is a single drop that fell 20 cm onto a paper surface angled at 45 degrees to the horizontal.
    bloodsplatter-20cm-45deg_0201.jpg
  • An X-ray of a large spider. The insect is a very large unidentified spider from the jungle in Thailand.
    spider1.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
  • An SEM image of a male mosquito (family Culicidae).  Several mosquito species are vectors for human diseases, including malaria and yellow fever.   This is a scanning electron microscope image.  The calibration bar is 100 um and the magnification is 41 x..
    K08semmosquito-c05.jpg
  • These  pointed scales are also known as dermal teeth. They give the shark's skin the feel of sandpaper.  The scales disrupt turbulence over the skin, considerably reducing the drag on the shark as it swims.  The reduction in fluid drag allows the shark to swim with less energy.  This unique design is duplicated in swimsuits and other surfaces that move through the water. The scale bar is 20 um and the magnification is 321x.  This specimen came from a dogfish shark.
    K08sem-sharkskin01blu.jpg
  • SEM of a mutant fruit fly. Scanning Electron Micrograph (SEM) of the head of a mutant fruit fly (Drosophila melanogaster). This mutant has abnormal bar shaped eyes ? they are smaller than normal and are due to the ?bar mutation?.  Fruit flies are widely used in genetic experiments, particularly in mutation experiments, because they reproduce rapidly and their genetic systems are well understood.
    K07SEM-fruitfly-bareye1.jpg
  • Male mosquito head (family Culicidae).  The large bushy antenna is used to detect females. The individual eye lenses detect levels of light and dark in different directions.  Several mosquito species are vectors for human diseases, including malaria and yellow fever. This is a scanning electron microscope image..The calibration bar is 100 um and the magnification is 41 x.
    K08semmosquito-c01.jpg
  • These  pointed scales are also known as dermal teeth. They give the shark's skin the feel of sandpaper.  The scales disrupt turbulence over the skin, considerably reducing the drag on the shark as it swims.  The reduction in fluid drag allows the shark to swim with less energy.  This unique design is duplicated in swimsuits and other surfaces that move through the water. The scale bar is 20 um and the magnification is 187x. This sample was collected from a dogfish shark.
    K08sem-sharkskin02blu.jpg
  • Blood droplet. In forensic science, the pattern created by projected blood is analyzed to determine information about the origin on the body, the weapon used and the number of blows, the relative position of the victim and assailant, and the sequence of events. This is a single drop that fell 20 cm onto a flat paper surface.
    bloodsplatter-100cm_0196.jpg
  • Blood droplet. In forensic science, the pattern created by projected blood is analyzed to determine information about the origin on the body, the weapon used and the number of blows, the relative position of the victim and assailant, and the sequence of events. This is a single drop that fell differnent heights.  The height of the drops on the bottom row were 5 cm, second row from the bottom is 15 cm, third row from the bottom is 20, the top row is 30 cm.  There drops all fell onto a flat paper surface.
    bloodsplatter-20cm-calibration_0216.jpg
  • Blood droplet. In forensic science, the pattern created by projected blood is analyzed to determine information about the origin on the body, the weapon used and the number of blows, the relative position of the victim and assailant, and the sequence of events. This is a single drop that fell 20 cm onto a paper surface angled at 80 degrees to the horizontal.
    bloodsplatter-20cm-80deg_0204.jpg
  • Blood droplet. In forensic science, the pattern created by projected blood is analyzed to determine information about the origin on the body, the weapon used and the number of blows, the relative position of the victim and assailant, and the sequence of events. This is a single drop that fell 20 cm onto a flat paper surface.
    bloodsplatter-20cm_0193.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
  • SEM of a fruit fly mouth. Scanning Electron Micrograph (SEM) of the head of a  fruit fly (Drosophila melanogaster).  Fruit flies are widely used in genetic experiments, particularly in mutation experiments, because they reproduce rapidly and their genetic systems are well understood.
    K07SEM-fruitfly-mouth3.jpg
  • X-ray of a Vacuum Ionization Gauge Tube.  These Ionization Gauge Tubes are hot cathode gauges of the Bayard-Albert Type intended for pressure measurement from 10-3 Torr down to 3 x 10-10 Torr.  These gauges are common in high vacuum equipment used in research and industry.
    K07Vacuum-guage.jpg
  • An X-ray of a quadcopter, also called a quadrotor helicopter.  The quadcopter propelled by four propellers. Quadcopters are classified as rotorcraft, as opposed to fixed-wing aircraft, because their lift is generated by a set of revolving narrow-chord airfoils.  Quadcopter designs have become popular in unmanned aerial vehicle (UAV) research. These vehicles use an electronic control system and electronic sensors to stabilize the aircraft. With their small size and agile maneuverability, these quadcopters can be flown indoors as well as outdoors.
    K14Xquad-full1.jpg
  • Surface of  a mature cannabis stem. The image is 6mm wide.  The different layers of the stem have been given different colors.  The layer that is several cells below the skin is the section of thick-walled fiber cells.  This highlights one potential uses of cannabis: an excellent source of fibers for paper, rope, and fabric.  The legalizing of cannabis in the United States opens research in this very profitable aspect of the plant. Field of view of this image is 2 mm.
    K13SEM-pot-canna52.jpg
  • A cross section of a mature stem.   The different layers of the stem have been given different colors.  The layer that is several cells below the skin is the section of thick-walled fiber cells.  This highlights one potential uses of cannabis: an excellent source of fibers for paper, rope, and fabric.  The legalizing of cannabis in the United States opens research in this very profitable aspect of the plant. Field of vie of this image is 1 mm.
    K13SEM-pot-canna51.jpg
  • A cross section of a mature stem.   The different layers of the stem have been given different colors.  The layer that is several cells below the skin is the section of thick-walled fiber cells.  This highlights one potential uses of cannabis: an excellent source of fibers for paper, rope, and fabric.  The legalizing of cannabis in the United States opens research in this very profitable aspect of the plant. Field of vie of this image is 5 mm.
    K13SEM-pot-canna48.jpg
  • Thermophilic bacteria . Collected in the summer of 2012 in 60C water in Yellowstone National Park, Wyoming USA.  This scanning electron micrograh (SEM) was shot at 6,580X magnification and the filed of view is 20 um.  This type of bacteria is adapted to thrive at high water temperatures and is currently the focus of biological researchers.   Bacteria that can live in these extreme conditions are called thermophiles or extremophiles.
    K12-thermo36B.jpg
  • Thermophilic bacteria . Collected in the summer of 2012 in 60C water in Yellowstone National Park, Wyoming USA.  This scanning electron micrograh (SEM) was shot at 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 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. Collected in the summer of 2012 in 60C water in Yellowstone National Park, Wyoming USA.  This scanning electron micrograh (SEM) was shot at 19,000X magnification and the filed of view is 3 um.  This type of bacteria is adapted to thrive at high water temperatures and is currently the focus of biological researchers.   Bacteria that can live in these extreme conditions are called thermophiles or extremophiles..
    K12-thermo32B.jpg
  • Thermophilic bacteria . Collected in the summer of 2012 in 60C water in Yellowstone National Park, Wyoming USA.  This scanning electron micrograh (SEM) was shot at 4,580X magnification and the filed of view is 27 um.  This type of bacteria is adapted to thrive at high water temperatures and is currently the focus of biological researchers.   Bacteria that can live in these extreme conditions are called thermophiles or extremophiles.
    K12-thermo29A.jpg
  • Thermophilic bacteria (blue). Collected in the summer of 2012 in 60C water in Yellowstone National Park, Wyoming USA.  This scanning electron micrograh (SEM) was shot at 17,131X magnification and the filed of view is 7 um.  This type of bacteria is adapted to thrive at high water temperatures and is currently the focus of biological researchers.   Bacteria that can live in these extreem condions are called thermophiles or extremophiles..
    K12-thermo27B.jpg
  • Thermophilic bacteria (blue). Collected in the summer of 2012 in 60C water in Yellowstone National Park, Wyoming USA.  This scanning electron micrograh (SEM) was shot at 17,131X magnification and the filed of view is 7 um.  This type of bacteria is adapted to thrive at high water temperatures and is currently the focus of biological researchers.   Bacteria that can live in these extreem condions are called thermophiles or extremophiles..
    K12-thermo27A.jpg
  • Thermophilic bacteria (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 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 . 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
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Ted Kinsman

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