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  • A scanning electron microscope (SEM) image of a gecko tongue..The reference bar is 30 um wide and was imaged at 176x magnification.
    K08semgecko-tongue03A.jpg
  • Scanning electron microscopy (SEM) of cellulose fibers in a paper wasp nest..The calibration bar is 100 um and the magnification is 371 x.
    K08SEMwasp-paper21.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 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 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
  • 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
  • SEM of a Porcupine Quill. This is a quill from a porcupine. (Erethizon dorsatum) The quill is designed to stick into the skin of a predator and not be easily removed.  This is an effective defensive mechanism for the porcupine. False color  Scanning Electron Micrograph (SEM).
    KW07SEM-porcupinecolor2.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
  • 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
  • A scanning electron microscope (SEM) image of fastskin swimsuit fabric.  This fabric simulates the water flow found on the skin of sharks.  Using natural materials for insperation has lead to these modern fabrics.  This fabric allows swimmers to decrease fluid resistance and had lead swimmers to record times..The reference bar is 100 um wide and was imaged at 131x magnification.
    K08semfastskin08col.jpg
  • A scanning electron microscope (SEM) image of fastskin swimsuit fabric.  This fabric simulates the water flow found on the skin of sharks.  Using natural materials for insperation has lead to these modern fabrics.  This fabric allows swimmers to decrease fluid resistance and had lead swimmers to record times..This image is  2 mm wide and was imaged at 35x magnification.
    K08fastskin07lines.jpg
  • A scanning electron microscope (SEM) image of fastskin swimsuit fabric.  This fabric simulates the water flow found on the skin of sharks.  Using natural materials for insperation has lead to these modern fabrics.  This fabric allows swimmers to decrease fluid resistance and had lead swimmers to record times..This image is  2 mm wide and was imaged at 35x magnification.
    K08fastskin00A1c.jpg
  • Powdery mildew (Sphaerotheca pannosa) infection on a peony leaf.  Sample was collected in late summer in New York State.  The balls are fruiting bodies of the fungus that will distribute the spores to more plants.
    K09sem-mildew103.jpg
  • Powdery mildew (Sphaerotheca pannosa) infection on a peony leaf.  Sample was collected in late summer in New York State.  The balls are fruiting bodies of the fungus that will distribute the spores to more plants.
    K09sem-mildew100.jpg
  • SEM of Human bone. This image shows the cancellous (spongy) bone of the human shin. Bone tissue is either compact or cancellous. Compact bone usually makes up the exterior of the bone, while cancellous bone is found in the interior. Cancellous bone is characterised by a honeycomb arrangement of trabeculae. These structures help to provide support and strength. The spaces within this tissue normally contain bone marrow, a blood forming substance.  Magnification is x40 when printed 10 cm wide.
    K14SEM-humanbone041B.jpg
  • SEM of Human bone. This image shows the cancellous (spongy) bone of the human shin. Bone tissue is either compact or cancellous. Compact bone usually makes up the exterior of the bone, while cancellous bone is found in the interior. Cancellous bone is characterised by a honeycomb arrangement of trabeculae. These structures help to provide support and strength. The spaces within this tissue normally contain bone marrow, a blood forming substance.  Magnification is x50 when printed 10 cm wide.
    K14SEM-humanbone039.jpg
  • SEM of Human bone. This image shows the cancellous (spongy) bone of the human shin. Bone tissue is either compact or cancellous. Compact bone usually makes up the exterior of the bone, while cancellous bone is found in the interior. Cancellous bone is characterised by a honeycomb arrangement of trabeculae. These structures help to provide support and strength. The spaces within this tissue normally contain bone marrow, a blood forming substance.  Magnification is x40 when printed 10 cm wide.
    K14SEM-humanbone034.jpg
  • SEM of a conodont tooth.  Acid etched from 500 million year old rock. Scientists are still unsure how these teeth were placed in most of the species.  Conodonts are extinct chordates resembling small eels maybe the size of the modern earthworm.  Classified in the class Conodonta. For many years, they were known only from tooth-like microfossils now called conodont elements, found in isolation. Knowledge about soft tissues remains relatively sparse. The animals are also called Conodontophora (conodont bearers) to avoid ambiguity.  This specimen was .5 mm wide and was collected in Ohio.
    K14-SEM-set2conodont039full.jpg
  • SEM of a conodont tooth.  Acid etched from 500 million year old rock. Scientists are still unsure how these teeth were placed in most of the species.  Conodonts are extinct chordates resembling small eels maybe the size of the modern earthworm.  Classified in the class Conodonta. For many years, they were known only from tooth-like microfossils now called conodont elements, found in isolation. Knowledge about soft tissues remains relatively sparse. The animals are also called Conodontophora (conodont bearers) to avoid ambiguity.  This specimen was .5 mm wide and was collected in Ohio.
    K14-SEM-set2conodont022full2.jpg
  • SEM of a conodont tooth.  Acid etched from 500 million year old rock. Scientists are still unsure how these teeth were placed in most of the species.  Conodonts are extinct chordates resembling small eels maybe the size of the modern earthworm.  Classified in the class Conodonta. For many years, they were known only from tooth-like microfossils now called conodont elements, found in isolation. Knowledge about soft tissues remains relatively sparse. The animals are also called Conodontophora (conodont bearers) to avoid ambiguity.  This specimen was .5 mm wide and was collected in Ohio.
    K14-SEM-set2conodont022full.jpg
  • SEM of Human bone. This image shows the cancellous (spongy) bone of the human shin. Bone tissue is either compact or cancellous. Compact bone usually makes up the exterior of the bone, while cancellous bone is found in the interior. Cancellous bone is characterised by a honeycomb arrangement of trabeculae. These structures help to provide support and strength. The spaces within this tissue normally contain bone marrow, a blood forming substance.  Magnification is x50 when printed 10 cm wide.
    K14SEM-humanbone039B.jpg
  • SEM of a conodont tooth.  Acid etched from 500 million year old rock. Scientists are still unsure how these teeth were placed in most of the species.  Conodonts are extinct chordates resembling small eels maybe the size of the modern earthworm.  Classified in the class Conodonta. For many years, they were known only from tooth-like microfossils now called conodont elements, found in isolation. Knowledge about soft tissues remains relatively sparse. The animals are also called Conodontophora (conodont bearers) to avoid ambiguity.  This specimen was .5 mm wide and was collected in Ohio.
    K14-SEM-set2conodont039full2.jpg
  • SEM of a conodont tooth.  Acid etched from 500 million year old rock. Scientists are still unsure how these teeth were placed in most of the species.  Conodonts are extinct chordates resembling small eels maybe the size of the modern earthworm.  Classified in the class Conodonta. For many years, they were known only from tooth-like microfossils now called conodont elements, found in isolation. Knowledge about soft tissues remains relatively sparse. The animals are also called Conodontophora (conodont bearers) to avoid ambiguity.  This specimen was .5 mm wide and was collected in Ohio.
    K14-SEM-set2conodont017full.jpg
  • SEM of Human bone. This image shows the cancellous (spongy) bone of the human shin. Bone tissue is either compact or cancellous. Compact bone usually makes up the exterior of the bone, while cancellous bone is found in the interior. Cancellous bone is characterised by a honeycomb arrangement of trabeculae. These structures help to provide support and strength. The spaces within this tissue normally contain bone marrow, a blood forming substance.  Magnification is x50 when printed 10 cm wide.
    K14SEM-humanbone046-2B.jpg
  • SEM of Human bone. This image shows the cancellous (spongy) bone of the human shin. Bone tissue is either compact or cancellous. Compact bone usually makes up the exterior of the bone, while cancellous bone is found in the interior. Cancellous bone is characterised by a honeycomb arrangement of trabeculae. These structures help to provide support and strength. The spaces within this tissue normally contain bone marrow, a blood forming substance.  Magnification is x40 when printed 10 cm wide.
    K14SEM-humanbone034B.jpg
  • SEM of a conodont tooth.  Acid etched from 500 million year old rock. Scientists are still unsure how these teeth were placed in most of the species.  Conodonts are extinct chordates resembling small eels maybe the size of the modern earthworm.  Classified in the class Conodonta. For many years, they were known only from tooth-like microfossils now called conodont elements, found in isolation. Knowledge about soft tissues remains relatively sparse. The animals are also called Conodontophora (conodont bearers) to avoid ambiguity.  This specimen was .5 mm wide and was collected in Ohio.
    K14-SEM-set2conodont002full2.jpg
  • SEM of Human bone. This image shows the cancellous (spongy) bone of the human shin. Bone tissue is either compact or cancellous. Compact bone usually makes up the exterior of the bone, while cancellous bone is found in the interior. Cancellous bone is characterised by a honeycomb arrangement of trabeculae. These structures help to provide support and strength. The spaces within this tissue normally contain bone marrow, a blood forming substance.  Magnification is x1000 when printed 10 cm wide.
    K14SEM-humanbone043.jpg
  • SEM of Human bone. This image shows the cancellous (spongy) bone of the human shin. Bone tissue is either compact or cancellous. Compact bone usually makes up the exterior of the bone, while cancellous bone is found in the interior. Cancellous bone is characterised by a honeycomb arrangement of trabeculae. These structures help to provide support and strength. The spaces within this tissue normally contain bone marrow, a blood forming substance.  Magnification is x40 when printed 10 cm wide.
    K14SEM-humanbone041.jpg
  • SEM of Human bone. This image shows the cancellous (spongy) bone of the human shin. Bone tissue is either compact or cancellous. Compact bone usually makes up the exterior of the bone, while cancellous bone is found in the interior. Cancellous bone is characterised by a honeycomb arrangement of trabeculae. These structures help to provide support and strength. The spaces within this tissue normally contain bone marrow, a blood forming substance.  Magnification is x300 when printed 10 cm wide.
    K14SEM-humanbone038B.jpg
  • SEM of Human bone. This image shows the cancellous (spongy) bone of the human shin. Bone tissue is either compact or cancellous. Compact bone usually makes up the exterior of the bone, while cancellous bone is found in the interior. Cancellous bone is characterised by a honeycomb arrangement of trabeculae. These structures help to provide support and strength. The spaces within this tissue normally contain bone marrow, a blood forming substance.  Magnification is x300 when printed 10 cm wide.
    K14SEM-humanbone038.jpg
  • SEM of Human bone. This image shows the cancellous (spongy) bone of the human shin. Bone tissue is either compact or cancellous. Compact bone usually makes up the exterior of the bone, while cancellous bone is found in the interior. Cancellous bone is characterised by a honeycomb arrangement of trabeculae. These structures help to provide support and strength. The spaces within this tissue normally contain bone marrow, a blood forming substance.  Magnification is x40 when printed 10 cm wide.
    K14SEM-humanbone035.jpg
  • SEM of a conodont tooth.  Acid etched from 500 million year old rock. Scientists are still unsure how these teeth were placed in most of the species.  Conodonts are extinct chordates resembling small eels maybe the size of the modern earthworm.  Classified in the class Conodonta. For many years, they were known only from tooth-like microfossils now called conodont elements, found in isolation. Knowledge about soft tissues remains relatively sparse. The animals are also called Conodontophora (conodont bearers) to avoid ambiguity.  This specimen was .5 mm wide and was collected in Ohio.
    K14-SEM-set2conodont009full2.jpg
  • SEM of Human bone. This image shows the cancellous (spongy) bone of the human shin. Bone tissue is either compact or cancellous. Compact bone usually makes up the exterior of the bone, while cancellous bone is found in the interior. Cancellous bone is characterised by a honeycomb arrangement of trabeculae. These structures help to provide support and strength. The spaces within this tissue normally contain bone marrow, a blood forming substance.  Magnification is x50 when printed 10 cm wide.
    K14SEM-humanbone046-2.jpg
  • SEM of a conodont tooth.  Acid etched from 500 million year old rock. Scientists are still unsure how these teeth were placed in most of the species.  Conodonts are extinct chordates resembling small eels maybe the size of the modern earthworm.  Classified in the class Conodonta. For many years, they were known only from tooth-like microfossils now called conodont elements, found in isolation. Knowledge about soft tissues remains relatively sparse. The animals are also called Conodontophora (conodont bearers) to avoid ambiguity.  This specimen was .5 mm wide and was collected in Ohio.
    K14-SEM-set2conodont022full3.jpg
  • SEM of a conodont tooth.  Acid etched from 500 million year old rock. Scientists are still unsure how these teeth were placed in most of the species.  Conodonts are extinct chordates resembling small eels maybe the size of the modern earthworm.  Classified in the class Conodonta. For many years, they were known only from tooth-like microfossils now called conodont elements, found in isolation. Knowledge about soft tissues remains relatively sparse. The animals are also called Conodontophora (conodont bearers) to avoid ambiguity.  This specimen was .5 mm wide and was collected in Ohio.
    K14-SEM-set2conodont017full2.jpg
  • SEM of a conodont tooth.  Acid etched from 500 million year old rock. Scientists are still unsure how these teeth were placed in most of the species.  Conodonts are extinct chordates resembling small eels maybe the size of the modern earthworm.  Classified in the class Conodonta. For many years, they were known only from tooth-like microfossils now called conodont elements, found in isolation. Knowledge about soft tissues remains relatively sparse. The animals are also called Conodontophora (conodont bearers) to avoid ambiguity.  This specimen was .5 mm wide and was collected in Ohio.
    K14-SEM-set2conodont002full.jpg
  • SEM of Human bone. This image shows the cancellous (spongy) bone of the human shin. Bone tissue is either compact or cancellous. Compact bone usually makes up the exterior of the bone, while cancellous bone is found in the interior. Cancellous bone is characterised by a honeycomb arrangement of trabeculae. These structures help to provide support and strength. The spaces within this tissue normally contain bone marrow, a blood forming substance.  Magnification is x1000 when printed 10 cm wide.
    K14SEM-humanbone043B.jpg
  • SEM of Human bone. This image shows the cancellous (spongy) bone of the human shin. Bone tissue is either compact or cancellous. Compact bone usually makes up the exterior of the bone, while cancellous bone is found in the interior. Cancellous bone is characterised by a honeycomb arrangement of trabeculae. These structures help to provide support and strength. The spaces within this tissue normally contain bone marrow, a blood forming substance.  Magnification is x40 when printed 10 cm wide.
    K14SEM-humanbone035B.jpg
  • SEM of a conodont tooth.  Acid etched from 500 million year old rock. Scientists are still unsure how these teeth were placed in most of the species.  Conodonts are extinct chordates resembling small eels maybe the size of the modern earthworm.  Classified in the class Conodonta. For many years, they were known only from tooth-like microfossils now called conodont elements, found in isolation. Knowledge about soft tissues remains relatively sparse. The animals are also called Conodontophora (conodont bearers) to avoid ambiguity.  This specimen was .5 mm wide and was collected in Ohio.
    K14-SEM-set2conodont015full.jpg
  • SEM of a conodont tooth.  Acid etched from 500 million year old rock. Scientists are still unsure how these teeth were placed in most of the species.  Conodonts are extinct chordates resembling small eels maybe the size of the modern earthworm.  Classified in the class Conodonta. For many years, they were known only from tooth-like microfossils now called conodont elements, found in isolation. Knowledge about soft tissues remains relatively sparse. The animals are also called Conodontophora (conodont bearers) to avoid ambiguity.  This specimen was .5 mm wide and was collected in Ohio.
    K14-SEM-set2conodont009full.jpg
  • SEM image with false color of the reflective ink on a new 100 dollar bill.  This image shows the the special highly reflective optical ink used on the large 100 pattern and on the liberty bell. This ink can not be duplicated with a digital printer. 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. This image is x150 magnification when printed 10 cm wide.
    K14SEM140611new100bill_0095.jpg
  • Scanning electron microscope (SEM) of the egg (nit) of a human head louse (Pediculus humanus).   Magnified 500x.
    K07SEM-headliceeggs3.jpg
  • Scanning electron microscope (SEM) of the egg (nit) of a human head louse (Pediculus humanus).   Magnified 145x.
    K07SEM-headliceeggs1.jpg
  • The stigma of Cannabis sativa. The stigma is the structure on the female flower that catches the male pollen. The sexual transfer of genetic materials is critical for creating seeds.  This Scanning Electron Microscope image (SEM) has false color applied. The stigma is 1 mm in diameter in this image.
    K170517-B027pan.jpg
  • The stigma of Cannabis sativa. The stigma is the structure on the female flower that catches the male pollen. The sexual transfer of genetic materials is critical for creating seeds.  This Scanning Electron Microscope image (SEM) has false color applied. The stigma is 1 mm in diameter in this image.
    K170525-B-cpdM080C.jpg
  • Scanning electron microscope image of the dark flower in the center of a Queen Anne's Lace ( Daucus carota) Flower. Queen Anne's Lace , is also known as Wild Carrot or Bird's Nest . An introduced weed that is abundant throughout much of temperate North America east of the Sierras. It is the wild form of the domesticated garden carrot.  The USDA has listed it as a noxious weed. The calibration bar is 200um or .2mm.  This image was collected at 231x..The luna moth has one of the most sensitive antenna of any insect.  The males antenna has the sole purpose of smelling out a female for mating.
    K08SEMqueenannslace017A.jpg
  • Scanning electron microscope image of a male luna moths antennae (Actias luna)..The calibration bar is 100um or .1mm.  This image was collected at 982x..The luna moth has one of the most sensitive antenna of any insect.  The males antenna has the sole purpose of smelling out a female for mating.
    K08SEM-lunamoth002D.jpg
  • Scanning electron microscope image of the dark flower in the center of a Queen Anne's Lace ( Daucus carota) Flower. Queen Anne's Lace , is also known as Wild Carrot or Bird's Nest . An introduced weed that is abundant throughout much of temperate North America east of the Sierras. It is the wild form of the domesticated garden carrot.  The USDA has listed it as a noxious weed. The calibration bar is 200um or .2mm.  This image was collected at 231x..The luna moth has one of the most sensitive antenna of any insect.  The males antenna has the sole purpose of smelling out a female for mating.
    K08SEMqueenannslace017B.jpg
  • Scanning electron microscope image of a male luna moths antennae (Actias luna)..The calibration bar is 100um or .1mm.  This image was collected at 982x..The luna moth has one of the most sensitive antenna of any insect.  The males antenna has the sole purpose of smelling out a female for mating.
    K08SEM-lunamoth002B.jpg
  • The stigma of Cannabis sativa. The stigma is the structure on the female flower that catches the male pollen. The sexual transfer of genetic materials is critical for creating seeds.  This Scanning Electron Microscope image (SEM) has false color applied. The stigma is 1 mm in diameter in this image.
    K170525-B-cpdM080.jpg
  • The stigma of Cannabis sativa. The stigma is the structure on the female flower that catches the male pollen. The sexual transfer of genetic materials is critical for creating seeds.  This Scanning Electron Microscope image (SEM) has false color applied. The stigma is 1 mm in diameter in this image.
    K170524H072B.jpg
  • The stigma of Cannabis sativa. The stigma is the structure on the female flower that catches the male pollen. The sexual transfer of genetic materials is critical for creating seeds.  This Scanning Electron Microscope image (SEM) has false color applied. The stigma is 1 mm in diameter in this image.
    K170524H072A.jpg
  • The stigma of Cannabis sativa. The stigma is the structure on the female flower that catches the male pollen. The sexual transfer of genetic materials is critical for creating seeds.  This Scanning Electron Microscope image (SEM) has false color applied. The stigma is 1 mm in diameter in this image.
    K170517bud-F055panC.jpg
  • The stigma of Cannabis sativa. The stigma is the structure on the female flower that catches the male pollen. The sexual transfer of genetic materials is critical for creating seeds.  This Scanning Electron Microscope image (SEM) has false color applied. The stigma is 1 mm in diameter in this image.
    K170517bud-F055panA.jpg
  • Scanning electron microscope image of the dark flower in the center of a Queen Anne's Lace ( Daucus carota) Flower. Queen Anne's Lace , is also known as Wild Carrot or Bird's Nest . An introduced weed that is abundant throughout much of temperate North America east of the Sierras. It is the wild form of the domesticated garden carrot.  The USDA has listed it as a noxious weed. The calibration bar is 200um or .2mm.  This image was collected at 231x..The luna moth has one of the most sensitive antenna of any insect.  The males antenna has the sole purpose of smelling out a female for mating.
    K08sem2queenannslace009.jpg
  • The stigma of Cannabis sativa. The stigma is the structure on the female flower that catches the male pollen. The sexual transfer of genetic materials is critical for creating seeds.  This Scanning Electron Microscope image (SEM) has false color applied. The stigma is 1 mm in diameter in this image.
    K170525-B-cpdM080B.jpg
  • The stigma of Cannabis sativa. The stigma is the structure on the female flower that catches the male pollen. The sexual transfer of genetic materials is critical for creating seeds.  This Scanning Electron Microscope image (SEM) has false color applied. The stigma is 1 mm in diameter in this image.
    K170524H072B1.jpg
  • The stigma of Cannabis sativa. The stigma is the structure on the female flower that catches the male pollen. The sexual transfer of genetic materials is critical for creating seeds.  This Scanning Electron Microscope image (SEM) has false color applied. The stigma is 1 mm in diameter in this image.
    K170517bud-F055panB.jpg
  • Scanning electron microscope image of a male luna moths antennae (Actias luna)..The calibration bar is 100um or .1mm.  This image was collected at 982x..The luna moth has one of the most sensitive antenna of any insect.  The males antenna has the sole purpose of smelling out a female for mating.
    K08SEM-lunamoth002C.jpg
  • Scanning electron microscopy (SEM) of a black fly eye (species Simulium ).  The yellow is yeast cells onthe eye, their function is unknown.  The magnification is 4,410x and the calibration bar is 1 um in length.
    K08SEM-blackflyeye001C.jpg
  • Scanning electron microscopy (SEM) of a black fly  (species Simulium ).  The magnification is 118x and the calibration bar is 100 um in length.
    K08SEM-blackfly002.jpg
  • Scanning electron microscopy (SEM) of a black fly eye (species Simulium ).  The magnification is 4,410x and the calibration bar is 1 um in length.
    K08SEM-blackflyeye001B.jpg
  • Scanning electron microscopy (SEM) of a black fly eye (species Simulium ).  The magnification is 00x and the calibration bar is 100 um in length.
    K08SEM-blackflyB07.jpg
  • Scanning electron microscope image of the mouth parts of a mosquito larva (family Culicidae).  The collection of hairs (light brown) are feeding structures used to filter water. The hairs beat through the water filtering out algae, bacteria and other micro-organisms that the larva feeds on.The calibration bar is 100 um and was take at a magnification of 1,440 x. ..
    K08semmosquito-larva023.jpg
  • Scanning electron microscope image of a Honey Bee Stinger. (Apis mellifera)  The large sack on the left produces the poison.  Once the barbs are set into the victim, the poison flows between the two blades of the stinger.  This image represents a field of view of 2 mm...
    K08sembeestinger047.jpg
  • Scanning electron microscope image of a water flea (Daphnia magna).  Daphnia is commonly found in fresh water. Water fleas are filter feeders that ingest algae, protozoan, or organic matter. This image represents a field of view of 2 mm and was collected at a magnification of 329x...
    K09-semdaphnia117.jpg
  • Scanning electron microscope image of the eastern subterranean termite (Reticulitermes flavipes) is the most widely distributed Reticulitermes termite and is found in the entire eastern region of North America as far north as Ontario, Canada, and south to Florida.  The calibration bar is 100 um and the magnification was 52 x...
    K08semtermites012.jpg
  • Scanning electron microscope image of a Bald-faced hornet stinger(Vespula maculata)   Once the barbs are set into the victim, the poison flows between the two blades of the stinger.  The claibration bar is 20 um and the magnification is 2,880x..
    K08sembaldfacedhornet008b.jpg
  • Scanning electron microscope image of a water flea (Daphnia magna).  Daphnia is commonly found in fresh water. Water fleas are filter feeders that ingest algae, protozoan, or organic matter. This image was collected at a magnification of 2,180x...
    K09-semdaphnia119.jpg
  • Scanning electron microscope image of a  mosquito larva (family Culicidae). The larva hatches and lives in water until it attains its adult form. It breathes air through its siphon tube (upper right), This image represents a field of view of 2 mm...
    K08SEMMosquito-larva51.jpg
  • DVD disc surface. Colored scanning electron micrograph (SEM) of the surface of a digital video disk. The plastic disc is pressed with a series of fine depressions representing a digitized video signal capable of being read by a laser. To reflect the laser light, the plastic is coated with a fine film of metal .The calibration bar is 1 um...
    K08SEMdvd01B.jpg
  • Scanning electron microscope (SEM) image of the  sporangia (spore sacs)  of the "male fern".  The sporangia are borne on the undersides of the leaf fronds in brown kidney- shaped structures known as sori.   Each sporangium is a biconvex capsule in which the mature spores lie freely.   As the mature sporangium dries, the tension in the walls of the annulus causes the sporangium to rupture, expelling the spores which are then distributed by the wind. The calibration bar is 20 um and the image was collected at a magnification of 2,280x.
    K08semfern049B.jpg
  • Skin from the Great Hammerhead Shark (Sphyrna mokarran). The Great Hammerhead Shark is the largest species of hammerhead shark, family Sphyrnidae, attaining a maximum length of 6.1 m (20 ft). It is found in tropical and warm temperate waters worldwide. This specimen was collected in Florida. This is a scanning electron microscope shot of the skin. Magnification is x142 when printed 10 cm wide.
    K14SEM-hammerhead-skin008B.jpg
  • Skin from the Great Hammerhead Shark (Sphyrna mokarran). The Great Hammerhead Shark is the largest species of hammerhead shark, family Sphyrnidae, attaining a maximum length of 6.1 m (20 ft). It is found in tropical and warm temperate waters worldwide. This specimen was collected in Florida. This is a scanning electron microscope shot of the skin. Magnification is x240 when printed 10 cm wide.
    K14SEM-hammerhead-skin043B.jpg
  • Scanning electron microscope (SEM) image of the  sporangia (spore sacs)  of the "male fern".  The sporangia are borne on the undersides of the leaf fronds in brown kidney- shaped structures known as sori.   Each sporangium is a biconvex capsule in which the mature spores lie freely.   As the mature sporangium dries, the tension in the walls of the annulus causes the sporangium to rupture, expelling the spores which are then distributed by the wind. The calibration bar is 20 um and the image was collected at a magnification of 2,280x.
    K08semfern045b.jpg
  • Skin from the Great Hammerhead Shark (Sphyrna mokarran). The Great Hammerhead Shark is the largest species of hammerhead shark, family Sphyrnidae, attaining a maximum length of 6.1 m (20 ft). It is found in tropical and warm temperate waters worldwide. This specimen was collected in Florida. This is a scanning electron microscope shot of the skin. Magnification is x240 when printed 10 cm wide.
    K14SEM-hammerhead-skin043.jpg
  • Skin from the Great Hammerhead Shark (Sphyrna mokarran). The Great Hammerhead Shark is the largest species of hammerhead shark, family Sphyrnidae, attaining a maximum length of 6.1 m (20 ft). It is found in tropical and warm temperate waters worldwide. This specimen was collected in Florida. This is a scanning electron microscope shot of the skin. Magnification is x73 when printed 10 cm wide.
    K14SEM-hammerhead-skin003B.jpg
  • Skin from the Great Hammerhead Shark (Sphyrna mokarran). The Great Hammerhead Shark is the largest species of hammerhead shark, family Sphyrnidae, attaining a maximum length of 6.1 m (20 ft). It is found in tropical and warm temperate waters worldwide. This specimen was collected in Florida. This is a scanning electron microscope shot of the skin. Magnification is x142 when printed 10 cm wide.
    K14SEM-hammerhead-skin008.jpg
  • Skin from the Great Hammerhead Shark (Sphyrna mokarran). The Great Hammerhead Shark is the largest species of hammerhead shark, family Sphyrnidae, attaining a maximum length of 6.1 m (20 ft). It is found in tropical and warm temperate waters worldwide. This specimen was collected in Florida. This is a scanning electron microscope shot of the skin. Magnification is x73 when printed 10 cm wide.
    K14SEM-hammerhead-skin003.jpg
  • Skin from the Great Hammerhead Shark (Sphyrna mokarran). The Great Hammerhead Shark is the largest species of hammerhead shark, family Sphyrnidae, attaining a maximum length of 6.1 m (20 ft). It is found in tropical and warm temperate waters worldwide. This specimen was collected in Florida. This is a scanning electron microscope shot of the skin. Magnification is x64 when printed 10 cm wide.
    K14SEM-hammerhead-skin02.jpg
  • Skin from the Great Hammerhead Shark (Sphyrna mokarran). The Great Hammerhead Shark is the largest species of hammerhead shark, family Sphyrnidae, attaining a maximum length of 6.1 m (20 ft). It is found in tropical and warm temperate waters worldwide. This specimen was collected in Florida. This is a scanning electron microscope shot of the skin. Magnification is x64 when printed 10 cm wide.
    K14SEM-hammerhead-skin02B.jpg
  • Colored scanning electron micrograph (SEM) of clotting red blood cells from a 18 year old male's wisdom tooth tissue.  The red blood cells are starting to clot in this image.  Magnification: x3380 when printed 10cm wide.
    K14-sem-tissue091.jpg
  • Colored scanning electron micrograph (SEM) of clotting red blood cells from a 18 year old male's wisdom tooth tissue.  The red blood cells are starting to clot in this image.  Magnification: x1830 when printed 10cm wide.
    K14SEM140618tooth043.jpg
  • Colored scanning electron micrograph (SEM) of clotting red blood cells from a 18 year old male's wisdom tooth tissue.  The red blood cells are starting to clot in this image.  Magnification: x2330 when printed 10cm wide.
    K14-sem-tissue069.jpg
  • Colored scanning electron micrograph (SEM) of clotting red blood cells from a 18 year old male's wisdom tooth tissue.  The red blood cells are starting to clot in this image.  Magnification: x2330 when printed 10cm wide.
    K14SEM140618tooth013.jpg
  • Colored scanning electron micrograph (SEM) of clotting red blood cells from a 18 year old male's wisdom tooth tissue.  The red blood cells are starting to clot in this image.  Magnification: x5100 when printed 10cm wide.
    K14-sem-tissue079B.jpg
  • Colored scanning electron micrograph (SEM) of clotting red blood cells from a 18 year old male's wisdom tooth tissue.  The red blood cells are starting to clot in this image.  Magnification: x12,000 when printed 10cm wide.
    K14-sem-tissue084.jpg
  • Colored scanning electron micrograph (SEM) of clotting red blood cells from a 18 year old male's wisdom tooth tissue.  The red blood cells are starting to clot in this image.  Magnification: x2990 when printed 10cm wide.
    K14-sem-tissue081.jpg
  • Colored scanning electron micrograph (SEM) of clotting red blood cells from a 18 year old male's wisdom tooth tissue.  The red blood cells are starting to clot in this image.  Magnification: x5100 when printed 10cm wide.
    K14-sem-tissue079.jpg
  • Colored scanning electron micrograph (SEM) of clotting red blood cells from a 18 year old male's wisdom tooth tissue.  The red blood cells are starting to clot in this image.  Magnification: x2330 when printed 10cm wide.
    K14-sem-tissue077.jpg
  • Colored scanning electron micrograph (SEM) of clotting red blood cells from a 18 year old male's wisdom tooth tissue.  The red blood cells are starting to clot in this image.  Magnification: x2330 when printed 10cm wide.
    K14-sem-tissue069B.jpg
  • Colored scanning electron micrograph (SEM) of clotting red blood cells from a 18 year old male's wisdom tooth tissue.  The red blood cells are starting to clot in this image.  Magnification: x22,570 when printed 10cm wide.
    K14-sem-tissue026C.jpg
  • Colored scanning electron micrograph (SEM) of clotting red blood cells from a 18 year old male's wisdom tooth tissue.  The red blood cells are starting to clot in this image.  Magnification: x2000 when printed 10cm wide.
    K14SEM-lymphocyte-Z030B.jpg
  • Colored scanning electron micrograph (SEM) of clotting red blood cells from a 18 year old male's wisdom tooth tissue.  The red blood cells are starting to clot in this image.  Magnification: x7330 when printed 10cm wide.
    K14-sem-tissue095.jpg
  • Colored scanning electron micrograph (SEM) of clotting red blood cells from a 18 year old male's wisdom tooth tissue.  The red blood cells are starting to clot in this image.  Magnification: x6580 when printed 10cm wide.
    K14-sem-tissue083.jpg
  • Colored scanning electron micrograph (SEM) of clotting red blood cells from a 18 year old male's wisdom tooth tissue.  The red blood cells are starting to clot in this image.  Magnification: x2990 when printed 10cm wide.
    K14-sem-tissue081B.jpg
  • Colored scanning electron micrograph (SEM) of clotting red blood cells from a 18 year old male's wisdom tooth tissue.  The red blood cells are starting to clot in this image.  Magnification: x2330 when printed 10cm wide.
    K14-sem-tissue077B.jpg
  • Colored scanning electron micrograph (SEM) of clotting red blood cells from a 18 year old male's wisdom tooth tissue.  The red blood cells are starting to clot in this image.  Magnification: x22,570 when printed 10cm wide.
    K14-sem-tissue026B.jpg
  • Colored scanning electron micrograph (SEM) of clotting red blood cells from a 18 year old male's wisdom tooth tissue.  The red blood cells are starting to clot in this image.  Magnification: x2000 when printed 10cm wide.
    K14SEM-lymphocyte-Z030.jpg
  • Colored scanning electron micrograph (SEM) of clotting red blood cells from a 18 year old male's wisdom tooth tissue.  The red blood cells are starting to clot in this image.  Magnification: x3380 when printed 10cm wide.
    K14-sem-tissue091B.jpg
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Ted Kinsman

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