Adaptations
Size-Among the very largest of sharks, the Great White regularly reaches a length of 20 feet and a weight of more than two tons. There is reasonably good evidence that this species can reach lengths of 23 or even 26 feet, but such individuals are notoriously difficult to confirm - let alone weigh.
Color-As with other animals, the Great White's color is highly variable. In general, the species is dark above and white below, a patterns called "countershading". Countershading makes the Great White difficult to see because it reduces the contrast between its belly in the shadow of the shark's bulk and its back illuminated by sunlight. Back and flank color in the Great White ranges from bronzy and greyish brown to various shades of grey. Pacific Coast specimens tend to be very dark - almost black - above. This darkness helps camouflage the Great White against the dark, rocky bottom over which it typically swims.
SkinLike other sharks, the skin of a Great White is very tough and studded with tiny, tooth-like scales called "dermal denticles". Dermal denticles protect the skin from damage and are replaced continually. Each individual denticle has a flat, table-like crown that has a series of raised ridges. These ridges reduce the drag and noise generated by a shark's swimming movements, enabling the Great White to glide efficiently in ghost-like silence.
Jaws-As in other sharks, the upper jaw of a Great White is not fused to the skull. Instead, the jaws are slung loosely beneath the skull, held in place by flexible connective tissue and braced by accessory cartilages. Special muscles pull the jaw complex forward and down, riding on grooves on the undersurface of the skull. This arrangement allows a Great White to protrude its jaws outward from the head, extending the reach of its teeth and creating a partial vacuum that helps suck in prey.
Teeth-The teeth of a Great White have broadly triangular blades with coarsely serrated edges. The upper teeth are broader and flatter than the lower teeth, which reflects their different roles during biting. The lower teeth stab into and hold secure a food item while the saw-like upper teeth gouge out a hunk of flesh. This dental arrangement allows the Great White to feed on prey too large to swallow whole as well as scoop calorie-rich blubber from whale carcasses.
Eyes-The eyes of a Great White are relatively large and well developed. The retina (light-sensitive tissue lining the back of the eyeball) of this species contains both rods and cones in a similar ratio to that of humans (about 4 to 1). This suggests that the Great White is highly visual and has acute color vision. Although different parts of its retina are adapted for bright and dim light conditions, it is believed that the Great White is primarily a daytime hunter.
NostrilsEach nostril of a Great White consists of a flap of skin that controls water movement into a cup-like structure. The cup-like structure contains a roughly spherical scent-detecting organ called an "olfactory bulb". Each olfactory bulb is composed of a series of closely-packed plates of tissue that are extremely sensitive to dissolved chemicals. The Great White has the largest olfactory bulbs of any shark species measured to date, enabling it to locate bleeding prey, decomposing whale carcasses, and seal or sea lion colonies by their distinctive odors.
Electroreceptors-Like other sharks, the Great White has specialized sensory organs that detect extremely minute electrical fields. These organs, called "ampullae of Lorenzini", consist of clusters of miniature testtube-shaped structures with a sensory hair cell at the base and filled with an electrically conductive jelly. Externally, the open ends of these ampullae appear as clusters of tiny pores peppered over the head. These pores are most richly distributed on the undersurface of the snout and recent work has shown that each cluster has a peak directional sensitivity. The Great White uses these electroreceptors to locate hidden prey, such as the tiny electrical signal of its prey's muscles in the otherwise confusing bloody froth of a predatory attack.
Ears-As in other sharks, the ears of a Great White are located close together on top of its head. Each ear consists of a pair of sac-like structures to which are attached three semicircular tubes. Each tube is oriented at right angles to the others is lined with sensory hair cells and contains a non-viscous fluid. This arrangement provides a Great White with continuous information on its acceleration and the orientation of its body in all three spatial dimensions.
Lateral Line-Like other sharks, the Great White has a row of sensitive vibration-detectors, called the "lateral line", running along each of its flanks. Together, the two lateral lines allow a Great White to 'feel' the direction of erratic water disturbances caused by struggling or injured animals that might make easy prey.
Gills-All sharks breathe by means of gills, but those of the Great White are exceptionally large. Each gill filament consists of a feather-like arrangement of thin-skinned plates. Each of these plates contains tiny arteries called "capillaries" that carry blood in a direction opposite to that of water flow over the gills. This "counter-current" arrangement allows the Great White efficient uptake of dissolved oxygen from the water, enabling it to pursue an active predatory lifestyle.
Heat Exchangers-Although its heart and gills operate at environmental temperatures, portions of the Great White's circulatory system have been modified to allow retention of body heat. On its way back to the heart, blood inside the veins is heated by muscle contraction and other metabolic processes. This heat is transferred to the arterial blood as it passes through a tightly-intermeshed network of tiny veins and arteries. These veins and arteries carry blood in opposite directions, allowing efficient transfer of metabolic heat in what is termed a "counter-current heat exchanger". The Great White has such heat exchangers around its brain, stomach, and swimming muscles, enabling it to function effectively in waters too cold for most other sharks.
Fins-like other sharks, the Great White has paired and unpaired fins. The pectoral and pelvic fins are paired, while the first dorsal, second dorsal, anal and caudal (tail) fins are unpaired. The pectoral fins control banking, turning, ascending, descending and breaking as well as acting as important signaling structures. The first dorsal fin is important in preventing unwanted roll, keeping the shark on an even trim. The caudal fin is the main propulsive structure, featuring an efficient crescentic shape and supported on either side by sturdy keels. All these fins allow the Great White to finely control its movement through the water
Size-Among the very largest of sharks, the Great White regularly reaches a length of 20 feet and a weight of more than two tons. There is reasonably good evidence that this species can reach lengths of 23 or even 26 feet, but such individuals are notoriously difficult to confirm - let alone weigh.
Color-As with other animals, the Great White's color is highly variable. In general, the species is dark above and white below, a patterns called "countershading". Countershading makes the Great White difficult to see because it reduces the contrast between its belly in the shadow of the shark's bulk and its back illuminated by sunlight. Back and flank color in the Great White ranges from bronzy and greyish brown to various shades of grey. Pacific Coast specimens tend to be very dark - almost black - above. This darkness helps camouflage the Great White against the dark, rocky bottom over which it typically swims.
SkinLike other sharks, the skin of a Great White is very tough and studded with tiny, tooth-like scales called "dermal denticles". Dermal denticles protect the skin from damage and are replaced continually. Each individual denticle has a flat, table-like crown that has a series of raised ridges. These ridges reduce the drag and noise generated by a shark's swimming movements, enabling the Great White to glide efficiently in ghost-like silence.
Jaws-As in other sharks, the upper jaw of a Great White is not fused to the skull. Instead, the jaws are slung loosely beneath the skull, held in place by flexible connective tissue and braced by accessory cartilages. Special muscles pull the jaw complex forward and down, riding on grooves on the undersurface of the skull. This arrangement allows a Great White to protrude its jaws outward from the head, extending the reach of its teeth and creating a partial vacuum that helps suck in prey.
Teeth-The teeth of a Great White have broadly triangular blades with coarsely serrated edges. The upper teeth are broader and flatter than the lower teeth, which reflects their different roles during biting. The lower teeth stab into and hold secure a food item while the saw-like upper teeth gouge out a hunk of flesh. This dental arrangement allows the Great White to feed on prey too large to swallow whole as well as scoop calorie-rich blubber from whale carcasses.
Eyes-The eyes of a Great White are relatively large and well developed. The retina (light-sensitive tissue lining the back of the eyeball) of this species contains both rods and cones in a similar ratio to that of humans (about 4 to 1). This suggests that the Great White is highly visual and has acute color vision. Although different parts of its retina are adapted for bright and dim light conditions, it is believed that the Great White is primarily a daytime hunter.
NostrilsEach nostril of a Great White consists of a flap of skin that controls water movement into a cup-like structure. The cup-like structure contains a roughly spherical scent-detecting organ called an "olfactory bulb". Each olfactory bulb is composed of a series of closely-packed plates of tissue that are extremely sensitive to dissolved chemicals. The Great White has the largest olfactory bulbs of any shark species measured to date, enabling it to locate bleeding prey, decomposing whale carcasses, and seal or sea lion colonies by their distinctive odors.
Electroreceptors-Like other sharks, the Great White has specialized sensory organs that detect extremely minute electrical fields. These organs, called "ampullae of Lorenzini", consist of clusters of miniature testtube-shaped structures with a sensory hair cell at the base and filled with an electrically conductive jelly. Externally, the open ends of these ampullae appear as clusters of tiny pores peppered over the head. These pores are most richly distributed on the undersurface of the snout and recent work has shown that each cluster has a peak directional sensitivity. The Great White uses these electroreceptors to locate hidden prey, such as the tiny electrical signal of its prey's muscles in the otherwise confusing bloody froth of a predatory attack.
Ears-As in other sharks, the ears of a Great White are located close together on top of its head. Each ear consists of a pair of sac-like structures to which are attached three semicircular tubes. Each tube is oriented at right angles to the others is lined with sensory hair cells and contains a non-viscous fluid. This arrangement provides a Great White with continuous information on its acceleration and the orientation of its body in all three spatial dimensions.
Lateral Line-Like other sharks, the Great White has a row of sensitive vibration-detectors, called the "lateral line", running along each of its flanks. Together, the two lateral lines allow a Great White to 'feel' the direction of erratic water disturbances caused by struggling or injured animals that might make easy prey.
Gills-All sharks breathe by means of gills, but those of the Great White are exceptionally large. Each gill filament consists of a feather-like arrangement of thin-skinned plates. Each of these plates contains tiny arteries called "capillaries" that carry blood in a direction opposite to that of water flow over the gills. This "counter-current" arrangement allows the Great White efficient uptake of dissolved oxygen from the water, enabling it to pursue an active predatory lifestyle.
Heat Exchangers-Although its heart and gills operate at environmental temperatures, portions of the Great White's circulatory system have been modified to allow retention of body heat. On its way back to the heart, blood inside the veins is heated by muscle contraction and other metabolic processes. This heat is transferred to the arterial blood as it passes through a tightly-intermeshed network of tiny veins and arteries. These veins and arteries carry blood in opposite directions, allowing efficient transfer of metabolic heat in what is termed a "counter-current heat exchanger". The Great White has such heat exchangers around its brain, stomach, and swimming muscles, enabling it to function effectively in waters too cold for most other sharks.
Fins-like other sharks, the Great White has paired and unpaired fins. The pectoral and pelvic fins are paired, while the first dorsal, second dorsal, anal and caudal (tail) fins are unpaired. The pectoral fins control banking, turning, ascending, descending and breaking as well as acting as important signaling structures. The first dorsal fin is important in preventing unwanted roll, keeping the shark on an even trim. The caudal fin is the main propulsive structure, featuring an efficient crescentic shape and supported on either side by sturdy keels. All these fins allow the Great White to finely control its movement through the water
Behavior
This shark is known as the most dangerous in the Ocean, which is a true fact. But the bloodthirsty image of this magnificent creature is mostly dreamed up in the movies and for television ratings. In reality, Great White attacks are extremely rare, even when people swim in close proximity to them. This creature is also known as the Carcharodon Carcharias, White Shark, White Pointer, or the White Death. This truly is an amazing creature and one of the most advanced predators in the animal kingdom. They look scary, are very powerful, have exceptional speed and maneuverability, and are expert hunters. Great White Shark attacks are extremely rare, even when humans are swimming nearby. Humans are not specifically targeted by sharks and that includes the Great White. In the Mediterranean Sea, for example, there have only been 31 confirmed attacks against humans in the last two centuries, most non-fatal. They simply aren’t interested in us. It is almost never an “attack” against humans. Sharks, like other fish, will exhibit a behavior called test biting. Basically, they were interested in what they saw and thought you might be a food source. After an initial test bite on a human, sharks almost never return again. That’s why fatalities from shark bites are so rare. On extremely rare occasions, sharks will attack a human. It is believed this only happens when the shark thinks your silhouette is a seal. But again, when the shark discovers you’re a person and not a seal, they quickly retreat.
This shark is known as the most dangerous in the Ocean, which is a true fact. But the bloodthirsty image of this magnificent creature is mostly dreamed up in the movies and for television ratings. In reality, Great White attacks are extremely rare, even when people swim in close proximity to them. This creature is also known as the Carcharodon Carcharias, White Shark, White Pointer, or the White Death. This truly is an amazing creature and one of the most advanced predators in the animal kingdom. They look scary, are very powerful, have exceptional speed and maneuverability, and are expert hunters. Great White Shark attacks are extremely rare, even when humans are swimming nearby. Humans are not specifically targeted by sharks and that includes the Great White. In the Mediterranean Sea, for example, there have only been 31 confirmed attacks against humans in the last two centuries, most non-fatal. They simply aren’t interested in us. It is almost never an “attack” against humans. Sharks, like other fish, will exhibit a behavior called test biting. Basically, they were interested in what they saw and thought you might be a food source. After an initial test bite on a human, sharks almost never return again. That’s why fatalities from shark bites are so rare. On extremely rare occasions, sharks will attack a human. It is believed this only happens when the shark thinks your silhouette is a seal. But again, when the shark discovers you’re a person and not a seal, they quickly retreat.
Habitat
The Great White is primarily an inhabitant of cool temperate waters over continental and insular shelves. It seems to prefer areas with rocky bottoms, but it has been recorded over sandy bottoms and on coral reefs as well as in the deep-sea. It was formerly
thought that Great Whites do not enter kelp forests, but this has been shown to be false: not only do they enter kelp forests, they apparently also feed there.
The Great White is primarily an inhabitant of cool temperate waters over continental and insular shelves. It seems to prefer areas with rocky bottoms, but it has been recorded over sandy bottoms and on coral reefs as well as in the deep-sea. It was formerly
thought that Great Whites do not enter kelp forests, but this has been shown to be false: not only do they enter kelp forests, they apparently also feed there.