The word "dinosaur", which is derived from
the Greek term for "terrible lizard", is the popular
name for a group of extinct land-dwelling
reptiles. They were the dominant vertebrate animals
during most of the Mesozoic era, which began
225 million years ago and ended 65 million
years ago. Among the dinosaurs were the largest
animals that ever walked the earth, although
some of the earliest dinosaurs were very small.
The Mesozoic era is divided into three periods,
Triassic, Jurassic, and Cretaceous, of approximately
equal length. Dinosaurs first appeared in
the later third of the Triassic period. Experts believe
that dinosaurs developed from a group of
archosauromorph reptiles such as Marasuchus,
which was a lightly built flesh eater about 1.3 meters
long. It was clearly a biped, running on its
hind legs, and the long tail was presumably used
as a balancing organ.
Dinosaurs are divided into two separate orders,
depending on the arrangement and shape of
the hip bones, which determine thewayan animal
walks and holds its body. The saurischians, or
"reptile hips", as they are commonly called, arose
in the early part of the Late Triassic; the ornithischians,
or "bird hips", arose toward the end of
the Triassic period.
Saurischians
The earliest dinosaurs were saurischians, which
are best known from the Ischigualasto Formation
of Argentina. The order Saurischia may be divided
into two major suborders: the theropods, or
"beast-footed dinosaurs", and the sauropods, or
"reptile-footed dinosaurs." The theropods, which
were more primitive than the sauropods, were
primarily bipedal, although many of them probably
used all four feet when walking or resting. The
hind legs were strong and bore birdlike feet, while
the forelimbs bore sharp, curved claws for seizing
and holding prey. All theropods had long tails that
functioned as stabilizers. The head was large, and
the jaws of most of the theropods contained sharp
teeth.
The theropods are divided into two major
groups. A basal group, the ceratosaurs, includes
such dinosaurs as Coelophysis, a small, agile carnivore
with a long, narrow skull represented by
many hundreds of specimens from the Ghost
Ranch Quarry in New Mexico. However, larger
dinosaurs, such as Ceratosaurus, are included
within this group. The remaining theropods,
termed tetanurans, include the Maniraptoriformes,
which share many advanced characteristics
with birds. The largest of these is Tyrannosaurus
rex, from the Late Cretaceous period of
North America, which grew to a weight of 4,500
kilograms, a height of 6 meters, and a length of
15 meters.
The sauropods, which appeared slightly later
in the Triassic than the theropods, have come to
stand as a symbol of gigantism in land animals.
They were all quadrupeds and vegetarians. They
had small skulls, long necks and tails, large barrelshaped
bodies, padded feet, and large claws on
the innermost toe of the forefoot and the innermost
toe of the hind foot. The ancestral stock of the
sauropods were the prosauropods, which were
much smaller than the sauropods. Like most
prosauropods, Plateosaurus had blunt, spatulate
teeth, was an herbivore, and was quadrupedal, although
it was capable of bipedal posture and gait.
The later sauropods had longer necks, and
their skulls were relatively small. The limb bones
became solid and pillarlike to support their great
weight. This category contained the largest of the
dinosaurs, Brachiosaurus, which is estimated to
have weighed 73,000 kilograms. The best known
sauropods are Brontosaurus and Diplodocus, from
the Late Jurassic period of North America. Although
it was once assumed that these huge
beasts had to live in swamps where the water
could support their great weight, it is now clear
that they were terrestrial animals that used their
long necks to eat from trees.
Ornithischians
The sauropods reached their zenith in the Late Jurassic;
the ornithischians replaced them as the
dominant herbivores in the Cretaceous period.
The expansion of this group was associated with
the advent of the flowering plants during the Cretaceous
period. Characteristically, a horny beak
was developed at the front of the mouth, and the
toes ended in rounded or blunt hooves instead of
claws.
The earliest ornithischians were the ornithopods.
Atypical example is Hypsilophodon, a small,
swift dinosaur with a long, slender tail and long,
flexible toes. The most specialized of the ornithopods
were the "duck-billed dinosaurs", also
known as hadrosaurs. Although they had flat
beaks and no anterior teeth, the cheek region had
rows of grinding teeth. The various types of duckbilled
dinosaur can be distinguished by modifications
of the bones associated with the nostrils.
Some were molded into hollow, domelike crests,
bizarre swellings of the nasal region, or long, projecting
tubular structures that were used to warm
the air or to produce sounds. The remaining three
groups of ornithischians presumably evolved
from the primitive ornithopods.
The earliest of these three groups of highly specialized
quadrupeds was the "plated dinosaurs",
or stegosaurs, which first appeared early in the Jurassic
period. This large dinosaur was more than
6 meters long. In comparison to its body size, its
head was extremely small. Stegosaurus had an average
of twenty plates arranged alternately in two
parallel rowsdownthe back. The plates were originally
thought to have been used for protection,
but scientists now believe that the plates could
have been used for thermoregulation. Stegosaurus
died out in the Early Cretaceous period.
The "armored dinosaurs", or ankylosaurs, are
not very well known, even though their remains
have been found over much of the world. Their
armor consisted of a mosaic of studs over the
body, spikes that protected the legs, and, in some
cases, spikes on the tail. They protected themselves
by crouching and drawing in their head
and legs.The last dinosaurs to develop were the "horned
dinosaurs", or ceratopsians. The skull was characterized
by a beaked snout and a bony frill that extended
fromthe back of the head. The ceratopsians
were also distinguished from others by various
patterns of horns. The skull of Triceratops, for example,
had three sharp horns, one on the snout
and one above each eye. The best known of the
small ceratopsians was Protoceratops, which was a
small, hornless dinosaur from the Gobi Desert in
Mongolia.
Studies of dinosaur eggs, nests, trackways, and
bone structures have shown that smaller dinosaurs
probably had a warm-blooded, or endothermic,
metabolism similar to mammals. This is supported
by the discovery of small theropods in
China that show a covering of feathers, presumably
for insulation. Large dinosaurs, such as
sauropods, would have been more efficient as
ectotherms, similar to most modern reptiles.
Extinction Theories
Several theories regarding the dinosaurs' extinction
were first proposed in the late nineteenth and
the early twentieth centuries. According to one
popular theory, dinosaurs were wiped out because
early mammals of the Cretaceous period ate
their eggs. Yet the eggs of many modern reptiles
have faced the same threat and have survived, primarily
because reptiles lay so many eggs. Another
theory suggested that the same animals ate the
plants on which the dinosaurs depended. Although
that is possible, virtual plagues of mammals
would have been required to eradicate the
dinosaurs. Some early scientists also believed that
the dinosaurs became too big for their environment;
that is unlikely, however, because gigantic
dinosaurs had been successful for millions of
years. Changes in the physical environment also
occurred in the Late Mesozoic. Evidence indicates
that the sea levels fell. Geologic evidence shows,
though, that drastic environmental changes had
occurred many times during the dinosaurs' reign
without any detrimental effect.
A theory proposed in early 1979 by Luis
Alvarez andWalter Alvarez suggests that the iridium
that has been found in several samples of sedimentary
layers between the rock of the Cretaceous
and Tertiary periods came from an asteroid
that struck the earth at that time. Such a catastrophic
event could have caused an enormous
cloud of dust to circle the earth and cut off the sunlight,
destroying the plants and the dinosaurs that
depended on them. This theory, however, fails to
explain why so many other animals, such as the
mammals, managed to survive.
Another modern theory places the blame on
the greenhouse effect. It has been argued that the
reduction of the seas that occurred during the Cretaceous
period caused a reduction of marine
plants. As a result, the amount of carbon dioxide
in the air increased, trapping heat from the earth's
surface. A similar theory suggests that the eruption
of a tremendous volcano produced a fatal
amount of carbon dioxide. Neither theory, however,
explains why other animals, especially heatsensitive
reptiles, survived.
The main alternative to the extraterrestrial
catastrophist explanation is a gradual ecosystem
change model. Declines in many groups of organisms
that started well before the Cretaceous-
Tertiary boundary are seen as being caused by
long-term climatic change, as lush tropical environments
were replaced by strongly seasonal,
temperate climates. The best explanation may be
a combination of the two main theories.
Study of Dinosaurs
Scientists study dinosaurs by examining fossils,
which are animal remains that have turned to
stone. If a dinosaur died near a river or in a
swamp, it stood an excellent chance of being
preserved. Its body might sink into the mud,
or floodwaters might float it downstream, where
it would end up on a sandbar, on the bottom of
a lake, or even in the sea. After the flesh decayed,
the bones would be covered by sediments, such
as mud or sand. The weight of accumulated layers
of sediment would compress the remains
and turn them into rock: mud into shale, sand
into sandstone, limey oozes into limestone or
chalk.
The way a fossil is studied is determined by the
category to which it belongs. The first category is
petrified fossils. They may be preserved in two
ways. In replacement, minerals replace the original
substance of the animal after water has dissolved
the soft body parts. In permineralization,
minerals fill in the small air spaces in bones or
shells, thereby preserving the original bone or
shell. The second group of fossils is composed of
natural molds that form when the bodies dissolve.
Scientists make artificial casts of these molds by
filling them with wax, plastic, or plaster. The third
type is prints, which are molds of thin objects,
such as feathers or tracks. Sometimes, even skin is
preserved. Prints are formed when the softmudin
which they are made turns to stone. Scientists can
determine the length and weight of the dinosaur
that made a set of footprints by studying the
depth, size, and distance between them.
Most fossils are found in sedimentary rocks,
which lie beneath three-fourths of the earth. The
best collecting areas are places where the soil has
worn away from the rocks. Areas in Colorado,
Montana, Wyoming, and Alberta, Canada, have
been especially rich in fossils. Most of the finds
consist of no more than scraps of limb bones, odd
vertebrae, loose teeth, or weathered lumps of rock
with broken bone showing on the surface. Once a
scientist has discovered a few fossilized fragments,
he or she combs the area to find the rest of
the animal. If the skeleton is embedded, it is extracted
with the help of a wide variety of tools,
ranging from picks and shovels to pneumatic
drills. Loose fragments are glued back into place,
and parts that are too soft or breakable are hardened
by means of a special resin solution that is
sprayed or painted on.
As the fossil is uncovered, it is encased in a
block of plaster of paris. (A more modern method
uses polyurethane foam instead of plaster.) After
the entire surface is covered, the fossil is rolled
over, and another layer of plaster is added. After
the fossil has been transported to the museum, the
plaster is removed. The "development" stage involves
the removal of the rock around the bones.
The oldest way is by hand, using tools such as
hammers and chisels; a more modern technique
uses electrically powered drills similar to dentists'
drills. Sandblasting and chemicals may also be
employed. After the fossil is cleaned, it is ready for
mounting. The bones are fastened to a steel framework
that makes the skeleton appear to stand by
itself.
Life-Earth Interaction
From the dinosaurs, scientists are learning new
lessons about the physiology of such beasts, their
relationship to the world in which they lived, their
distribution and the bearing of that distribution
on the past arrangements of the continents, various
aspects of evolution, and the reasons that they
became extinct. The dinosaurs played a major part
in the shaping of the natural world. Birds, for example,
are probably their descendants, as evidenced
by the intermediary species Archaeopteryx,
a primitive bird that lived during the Late Jurassic
period; although its beak contained teeth, Archaeopteryx
also had feathers and could fly.
The disappearance of a species that seemed to
rule the world for more than 100 million years
brings into question the notion of a "dominant"
species. Most people believe that mammals are
now the dominant form of life; however, dinosaurs
did not "rule", and neither do mammals. If
one were to list the biological organisms whose influence
on the planet is such that their removal
would produce chaos, then that list would be
headed by microorganisms so small that they can
be seen only through powerful microscopes. The
list would also include the green plants and the
fungi.
The extinction of the dinosaurs also brings into
question the ability of humans to destroy the
world. All species, from the simplest microorganism
to the largest plant or animal, modify their immediate
surroundings. They cannot avoid doing
so. The success of one group, however, does not
imply the failure of the groups it exploits. The
complexity of individual organismsmayincrease,
but the simpler forms do not necessarily disappear.
Life continued after the demise of the dinosaurs
and would probably continue to do so if humankind
were destroyed.
ankylosaurs: a group of later ornithischians
characterized by heavy armor
cerotopsians: a group of later ornithischians
characterized by a beaked snout
and a bony frill on the back of the head
ornithischians: one of the two orders of
dinosaurs; it comprises the "bird-hipped"
dinosaurs
ornithopods: the early, bipedal ornithischians
saurischians: one of the two orders of dinosaurs;
it comprises the "reptile-hipped"
dinosaurs
sauropods: the herbivorous, quadrupedal
saurischians
stegosaurs: a group of later ornithischians
characterized by a row of plates down
the back
thecodonts: an order of Triassic reptiles
thatwere the ancestors of dinosaurs, birds,
and crocodiles
theropods: the carnivorous, primarily bipedal
saurischians
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