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  • 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.
    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
  • 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.
    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.
    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
  • Fragment of an Abalone shell; color enhanced scanning electron micrograph (SEM) of a section through an abalone (Haliotis sp.) shell. The shell is composed of layers of overlapping platelets of calcium carbonate crystals, or aragonite,  Between the layers are thin sheets of protein (not seen). This structure makes the shell much stronger than the materials would be in any other arrangement.  Abalones are edible mollusks found in warm seas. The thin layers of shell reflect light using the wave nature of light.  Each thin layer reflects a particular wavelength – together the layers reflect wavelengths of light that constructively interfere to create bright greens and blues. Magnification: x8000 when printed at 10 cm wide.
    K14SEM140611abalone_0054B.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
  • Fragment of an Abalone shell; color enhanced scanning electron micrograph (SEM) of a section through an abalone (Haliotis sp.) shell. The shell is composed of layers of overlapping platelets of calcium carbonate crystals, or aragonite,  Between the layers are thin sheets of protein (not seen). This structure makes the shell much stronger than the materials would be in any other arrangement.  Abalones are edible mollusks found in warm seas. The thin layers of shell reflect light using the wave nature of light.  Each thin layer reflects a particular wavelength – together the layers reflect wavelengths of light that constructively interfere to create bright greens and blues. Magnification: x1000 when printed at 10 cm wide.
    K14SEMabalone0039.jpg
  • Fragment of an Abalone shell; color enhanced scanning electron micrograph (SEM) of a section through an abalone (Haliotis sp.) shell. The shell is composed of layers of overlapping platelets of calcium carbonate crystals, or aragonite,  Between the layers are thin sheets of protein (not seen). This structure makes the shell much stronger than the materials would be in any other arrangement.  Abalones are edible mollusks found in warm seas. The thin layers of shell reflect light using the wave nature of light.  Each thin layer reflects a particular wavelength – together the layers reflect wavelengths of light that constructively interfere to create bright greens and blues. Magnification: x8000 when printed at 10 cm wide.
    K14SEM140611abalone_0054.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
  • A close up of the seed leaf or cotyledon of a cannabis plant. Imaged with a scanning electron microscope (SEM). The surface of the cotyledon. The cotyledon is the scientific name for the fist two leaves the plant makes. In reality, these two leaves are actually folded up inside the seed, so this structure is often called the seed leaves. It is important that the seeding gets these leaves unfolded and oriented correctly quickly to start photosynthesis and start False color has been applied. The marijuana plant produces tetrahydrocannabinol (THC), the active component of cannabis when used as a drug. The filed of view in this image is 1.2 mm wide.
    K170428-4dayPD024.jpg
  • Fragment of an Abalone shell; color enhanced scanning electron micrograph (SEM) of a section through an abalone (Haliotis sp.) shell. The shell is composed of layers of overlapping platelets of calcium carbonate crystals, or aragonite,  Between the layers are thin sheets of protein (not seen). This structure makes the shell much stronger than the materials would be in any other arrangement.  Abalones are edible mollusks found in warm seas. The thin layers of shell reflect light using the wave nature of light.  Each thin layer reflects a particular wavelength – together the layers reflect wavelengths of x4000 when printed at 10 cm wide.
    K14SEM140611abalone_0061.jpg
  • an X-ray of a Glass sponge (Euplectella) skeleton, formed by silica spicules that unite into complex geometric structures.
    glass-spongeneg.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
  • SEM of Reindeer Lichen (Cladonia rangiferina); color enhanced scanning electron micrograph (SEM). A lichen is a symbiosis between a fungus and an alga. The fungus provides the structural support for the lichen partnership, while the alga provides food by photosynthesis.  Cladonia lichen are classified as fruticose due to their tall erect structures.  Like all lichens, the ones in this photograph grow very slowly: only a few millimeters in a year.  The calibration bar is 100 um and the magnification was .52 x
    K08SEMliken-A020.jpg
  • SEM of Reindeer Lichen (Cladonia rangiferina); color enhanced scanning electron micrograph (SEM). A lichen is a symbiosis between a fungus and an alga. The fungus provides the structural support for the lichen partnership, while the alga provides food by photosynthesis.  Cladonia lichen are classified as fruticose due to their tall erect structures.  Like all lichens, the ones in this photograph grow very slowly: only a few millimeters in a year.  The calibration bar is 100 um and the magnification was .52 x
    K08SEMliken-A019.jpg
  • SEM of Reindeer Lichen (Cladonia rangiferina); color enhanced scanning electron micrograph (SEM). A lichen is a symbiosis between a fungus and an alga. The fungus provides the structural support for the lichen partnership, while the alga provides food by photosynthesis.  Cladonia lichen are classified as fruticose due to their tall erect structures.  Like all lichens, the ones in this photograph grow very slowly: only a few millimeters in a year.  The calibration bar is 100 um and the magnification was .52 x
    K08SEMliken-A020.jpg
  • SEM of Reindeer Lichen (Cladonia rangiferina); color enhanced scanning electron micrograph (SEM). A lichen is a symbiosis between a fungus and an alga. The fungus provides the structural support for the lichen partnership, while the alga provides food by photosynthesis.  Cladonia lichen are classified as fruticose due to their tall erect structures.  Like all lichens, the ones in this photograph grow very slowly: only a few millimeters in a year.  The calibration bar is 100 um and the magnification was .52 x
    K08SEMliken-A019.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-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-humanbone039B.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 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 x50 when printed 10 cm wide.
    K14SEM-humanbone046-2.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 x40 when printed 10 cm wide.
    K14SEM-humanbone034B.jpg
  • Dried Human bone photographed at 5x magnification.  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.
    K13-bonestack001.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 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-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 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
  • Light Micrograph of pollen grains from a flower; magnification 100x at 35mm.
    K12-pollen8563.jpg
  • Scanning Electron Micrograph (SEM) of the root cap of a corn plant. The root tip has only grown for a few days. Magnification: 270x.
    K14-SEM-cornroot-tip001.jpg
  • A scanning electron microscope image of the stem of a young 5-day-old cannabis (Cannabis sativa) plant stem. This image is a transverse section of the stem showing the different cell types. Cannabis is also known as help, and is a source of strong fibers for clothing, paper, and rope. This fast growing plant shows promise for being a cheep source of fibers in the future. This image shows a horizontal field of view of .3mm.
    K170510stemApan1.jpg
  • SEM image of a transverse section through a cannabis (Cannabis sativa) plant root. The root at this location is .5 mm in diameter.
    K170614rootN072pan1.jpg
  • A scanning electron microscope image of the stem of a young 5-day-old cannabis (Cannabis sativa) plant stem. This image is a transverse section of the stem showing the different cell types. Cannabis is also known as help, and is a source of strong fibers for clothing, paper, and rope. This fast growing plant shows promise for being a cheep source of fibers in the future. This image shows a horizontal field of view of .2mm.
    K170512stemC027A.jpg
  • SEM image of a transverse section through a cannabis (Cannabis sativa) plant root. The root at this location is 4 mm in diameter.
    K170614rootp089pan1.jpg
  • SEM image of a transverse section through a cannabis (Cannabis sativa) plant root. The image shows a field of view 3 mm wide at this location.
    K1700515seed012root-tip.jpg
  • SEM image of a transverse section through a cannabis (Cannabis sativa) plant root. The root at this location is 4 mm in diameter.
    K170610LM01A.jpg
  • A scanning electron microscope image of the stem of a young 5-day-old cannabis (Cannabis sativa) plant stem. This image is a transverse section of the stem showing the different cell types. Cannabis is also known as help, and is a source of strong fibers for clothing, paper, and rope. This fast growing plant shows promise for being a cheep source of fibers in the future. This image shows a horizontal field of view of .2mm.
    K170512stemC027B.jpg
  • A scanning electron microscope image of the stem of a young 5-day-old cannabis (Cannabis sativa) plant stem. This image is a transverse section of the stem showing the different cell types. Cannabis is also known as help, and is a source of strong fibers for clothing, paper, and rope. This fast growing plant shows promise for being a cheep source of fibers in the future. This image shows a horizontal field of view of .3mm.
    K170510stemApan1C.jpg
  • A scanning electron microscope image of the stem of a young 5-day-old cannabis (Cannabis sativa) plant stem. This image is a transverse section of the stem showing the different cell types. Cannabis is also known as help, and is a source of strong fibers for clothing, paper, and rope. This fast growing plant shows promise for being a cheep source of fibers in the future. This image shows a horizontal field of view of .3mm.
    K170510stemApan1B.jpg
  • Light Microscope image of a transverse section through a cannabis (Cannabis sativa) plant stem. The root at this location is 6 mm in diameter.
    K17stem-near-root.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
  • SEM image of a transverse section through a cannabis (Cannabis sativa) plant root. This image shows a field of view of .2 mm.
    K170614rootpan2.jpg
  • Scanning Electron Micrograph (SEM) of a grain of pollen from Cannabis sativa plant. The pollen is 20 um in diameter and is scattered by air currents.  The pollen of the cannabis plant is almost identical to the hops plant, a close relative.
    K170524CPDpollen010A.jpg
  • The underside of a new cannabis leaf imaged with a scanning electron microscope (SEM). Width of the image is 8 mm.
    K170509M081full-PAN2.jpg
  • A cannabis seedling showing the first set of true leaves. Imaged with a scanning electron microscope (SEM). False color has been applied. The marijuana plant produces tetrahydrocannabinol (THC), the active component of cannabis when used as a drug. The filed of view in this image is 4 mm wide.
    K170428-4dayPA003A.jpg
  • The top side of a new cannabis leaf imaged with a scanning electron microscope (SEM). Width of the image is 4 mm.
    K17SEM_leaf10C.jpg
  • The top side of a new cannabis leaf imaged with a scanning electron microscope (SEM). Width of the image is 4 mm.
    K17SEM_leaf10A.jpg
  • An x-ray of a human lumbar vertebra. T5
    K15X-humanvert-Comp01A.jpg
  • An x-ray of a human lumbar vertebra. T5
    K15X-human-vertebra06B.jpg
  • An x-ray of a human lumbar vertebra. T5
    K15X-human-vertebra02B.jpg
  • X-ray of bleeding heart flowers (Dicentra formosa). False color x-ray.
    K14X-bleedingheartcolorW.jpg
  • SEM of Eastern bluebird (Sialia sialis) feathers.  This image is 3 mm wide..These feathers have micro-structures that reflect blue light.  These microscopic features allow the bird to display bright blue iridescent colors.
    K08SEMbbfeath06-5.jpg
  • SEM of Eastern bluebird (Sialia sialis) feathers.  This image is 500 um wide..These feathers have micro-structures that reflect blue light.  These microscopic features allow the bird to display bright blue iridescent colors.
    K08SEMbbfeath10blu2.jpg
  • Scanning electron microscope image of a staghorn fern leaf (Platycerium holtummii)  magnified 76x.  Staghorn ferns are epiphytic perennials or "air" plants. Staghorns are native to jungles in Africa and Asia .
    K08-semFERN1.jpg
  • An SEM image of a bract leaf that extends from the center of a cannabis bud. This type of leaf has high concentrations of the glandular trichomes that produce THC. Width of the leaf is 4 mm.
    170614leafE029pan3.jpg
  • An x-ray of a human lumbar vertebra. T5
    K15Xhumanvert-Comp03C.jpg
  • A false color X-ray of a fern.
    K15Xfern01C.jpg
  • An x-ray of a human lumbar vertebra. T5
    K15X-human-vertebra02A.jpg
  • A golf ball that has been sliced in half sits next to a whole ball, demonstrating how golf balls are designed in layers.
    golfball-callaway3_0232.jpg
  • A  view of a human vertebra
    K13-huvert-blue073.JPG
  • Scanning electron microscope image of a Blue mussel (Mytilus edulis) shell.  Colored scanning electron micrograph (SEM). The shell of a mollusc is a tough exoskeleton formed from calcium carbonate (aragonite or calcite). It evolved as a protective barrier to predators. Magnification: 3,740x and the image is 30 um wide.
    K12sem-bluemusselA.jpg
  • SEM of Eastern bluebird (Sialia sialis) feathers.  This image is 3 mm wide..These feathers have micro-structures that reflect blue light.  These microscopic features allow the bird to display bright blue iridescent colors.
    K08SEMbbfeath06-5B.jpg
  • SEM of Eastern bluebird (Sialia sialis) feathers.  This image is 2 mm wide..These feathers have micro-structures that reflect blue light.  These microscopic features allow the bird to display bright blue iridescent colors.
    K08SEMBluebirdfeathres2-3B.jpg
  • False color scanning electron microscope image of an uncut natural diamond.  Diamond is one of the crystal forms of pure carbon and is element 6 on the periodic table. Diamond is the hardest material known to science.  The magnification is 200x and the calibration bar is 200 um in length.
    K07SEM-diamondB2B.jpg
  • A cannabis seedling showing the first set of true leaves. Imaged with a scanning electron microscope (SEM). False color has been applied. The marijuana plant produces tetrahydrocannabinol (THC), the active component of cannabis when used as a drug. The filed of view in this image is 3 mm wide.
    K170429cryo-3-015BW.jpg
  • A cannabis seedling showing the first set of true leaves. Imaged with a scanning electron microscope (SEM). False color has been applied. The marijuana plant produces tetrahydrocannabinol (THC), the active component of cannabis when used as a drug. The filed of view in this image is 4 mm wide.
    K170428-4dayPA003B.jpg
  • A SEM image of the edge of a leaf shows a calcium oxalate crystal. These crystals are found throughout the plant and are responsible for throat irritation when medical marijuana is smoked. Plants that have too many oxalate crystals are good candidates for modern THC extraction techniques. Calcium oxalate crystals in plants are called raphides. Humans have similar calcium crystals that can appear as kidney stones. These crystals help remove calcium build up in the tissues and make it undesirable for grazing animals to eat the plant. Magnification is x120 on the printed page.
    K170406z056.jpg
  • The top side of a new cannabis leaf imaged with a scanning electron microscope (SEM). Width of the image is 4 mm.
    K17SEM_leaf10B.jpg
  • The top side of a new cannabis leaf imaged with a scanning electron microscope (SEM). Width of the image is 2 mm.
    K17SEM_leaf11A.jpg
  • The top side of a new cannabis leaf imaged with a scanning electron microscope (SEM). Width of the image is 4 mm.
    K17SEM_leaf9B.jpg
  • An SEM image of a bract leaf that extends from the center of a cannabis bud. This type of leaf has high concentrations of the glandular trichomes that produce THC. Width of the leaf is 4 mm.
    170614leafE029pan2.jpg
  • An SEM image of a bract leaf that extends from the center of a cannabis bud. This type of leaf has high concentrations of the glandular trichomes that produce THC. Width of the leaf is 4 mm.
    170614leafE029pan1.jpg
  • The underside of a new cannabis leaf imaged with a scanning electron microscope (SEM). Width of the image is 3 mm.
    170515cryoZ-028bottom-pan2.jpg
  • The underside of a new cannabis leaf imaged with a scanning electron microscope (SEM). Width of the image is 3 mm.
    170515cryoZ-028bottom-pan1.jpg
  • An x-ray of a human lumbar vertebra. T5
    K15Xhumanvert-Comp03B.jpg
  • An x-ray of a human lumbar vertebra. T5
    K15Xhumanvert-Comp03.jpg
  • A false color X-ray of a fern.
    K15Xfern01D.jpg
  • A false color X-ray of a fern.
    K15Xfern01A.jpg
  • X-ray of a Grapevine leaf (Vitis vinifera).
    K14X-grapvine1B.jpg
  • X-ray of a Grapevine leaf (Vitis vinifera).
    K14X-grapvine1.jpg
  • This is a turbine blade that is responsible for making a jet engine work.  This particular blade is from a fighter jet and routinely travels though the compression stage of the jet engine traveling faster than the speed of sound as it rotates.  Due to the hot environment inside the engine, the turbine blades have to be specially engineered out of state of the art materials.  Titanium, and titanium alloys are routinely used for turbine blades.
    titanium-jet-blade_0060.jpg
  • A golf ball that has been sliced in half sits next to a whole ball, demonstrating how golf balls are designed in layers.
    golfball-topflight-xl1_0224.jpg
  • A golf ball that has been sliced in half sits next to a whole ball, demonstrating how golf balls are designed in layers.
    golfball-caliaway1_0223.jpg
  • X-ray of bleeding heart flowers (Dicentra formosa). False color x-ray.
    K14X-bleedingheartcolorA.jpg
  • Scanning electron micrograph (SEM) of mature female Cannabis bud (Cannabis sativa) showing globular trichomes – the location of the highest concentration THC.  magnification x120 when printed 10 cm wide.
    K14-SEM-pot22A.jpg
  • A  view of a human vertebra
    K13-huvert-blue066.JPG
  • A  view of a human vertebra
    K13-Humanvert-004.JPG
  • A  view of a human vertebra
    K13-Humanvert-002.JPG
  • Cocoa pod (Theobroma cacao). This is the fruit of the cocoa, or cacao, tree from which cocoa beans are extracted. The leathery yellow pod contains up to 100 beans embedded in a soft pulp. These are dried, roasted and ground to produce cocoa powder, which is then used to make chocolate.
    K12-cocapod1146.jpg
  • Cocoa pod (Theobroma cacao). This is the fruit of the cocoa, or cacao, tree from which cocoa beans are extracted. The leathery yellow pod contains up to 100 beans embedded in a soft pulp. These are dried, roasted and ground to produce cocoa powder, which is then used to make chocolate.
    K12-cocapod1130.jpg
  • X-Ray of the  Chinese lantern plant, (Physalis alkekengi) also called the winter cherry or bladder cherry is a member of the potato family.  The chinese lantern plant is used mostly for decorative purposes, but is also harvested for its fruit. The fruit has twice the Vitamin C of lemons and resembles a blonde-red cherry tomato.
    K11Xlatern2C.jpg
  • X-Ray of the  Chinese lantern plant, (Physalis alkekengi) also called the winter cherry or bladder cherry is a member of the potato family.  The chinese lantern plant is used mostly for decorative purposes, but is also harvested for its fruit. The fruit has twice the Vitamin C of lemons and resembles a blonde-red cherry tomato.
    K11Xlatern2B.jpg
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