Chapter 2.1 WH PDF

Summary

This document discusses Human Evolution, looking at the development, evolution, and important aspects of different human species. It explains the concepts based on archaeological findings and how technology evolved.

Full Transcript

Chapter 2 Notes:

Millions of years ago, our distant ancestors descended from the trees, took to walking
upright on the land, and gradually evolved into the species we are today. Their evolution
was influenced by many variables, including changes in climate, diet, and survival
strategies. Over time, humans developed new skills and tools to meet the challenges of
endurance and sought better prospects for themselves through cooperation and
migration.

Understanding these changes and the long-ago origins of our species has required
careful research by archaeologists, anthropologists, genetic scientists, historians,
sociologists, and many others. Through painstaking reconstructions and study, these
specialists have used a relatively small number of archaeological finds and material
remnants of our distant ancestors to paint a striking picture of our prehistoric past, going
back millions of years. The nature of this work, however, requires using some
extrapolation, educated speculation, and outright guesswork to piece together the bits of
unearthed evidence into an intelligible story. This means that even as we have had to
discard old theories when new information has emerged, there remain plenty of things
we’ll simply never know for sure.

Human Evolution
The concept of evolution over time is one we are all likely familiar with. Consider, for
example, how technology has evolved. The first true smartphones appeared on the
market at the beginning of this century, but these complicated devices didn’t spring all at
once from the minds of ambitious engineers. Rather, these engineers built on
technology that had evolved and improved over many decades. In the mid-1800s,
telegraph technology first demonstrated that electricity could be used for long-distance
communication. That technology paved the way for the first telephones, which were
basic and expensive but over many decades became more sophisticated, more
common, and cheaper. By the early 1980s, electronics companies had begun selling
telephones that used radio technology to communicate wirelessly. Over time these
devices were made faster and smaller, and companies added features like cameras,
microprocessors, and eventually internet access. With these evolutionary
transformations, the smartphone was born.
Modern humans are not smartphones, and in human history, chance biological
adaptations to a changing environment drove the evolutionary process rather than the
minds of inventors conceiving of technical innovations. But the evolutionary process that
eventually gave birth to our species resembles the technological evolution of
smartphones and other devices in some important ways. Just like we can trace the
evolution of the smartphone back to the telegraph, so can we trace our own evolution
back to a very distant ancestor called Australopithecus, who lived in eastern and
southern Africa between 2.5 and 4 million years ago. Lucy, previously mentioned, was
of the genus Australopithecus (Figure 2.3). A genus is a taxonomic rank that includes
several similar and related species within it. Like us, members of Lucy’s species
afarensis (named for the Afar region of East Africa where she was found) were capable
of walking upright and likely used tools. Beyond that, however, they were very different
from us. They had plenty of hair like chimpanzees, fingers and arms well suited for
climbing trees, and brains about one-third the size of ours. Despite these differences,
scholars have concluded that the genus Homo (“human”) evolved from Australopithecus
somewhere around two to three million years ago.

Possibly the earliest member of the genus Homo was Homo habilis (Figure 2.4). This
species appears in the archaeological record about two to three million years ago.
Habilis means “handy”; it was thought at one time that this was the first species to have
created stone tools. We now know that stone tools predate Homo habilis, but the name
has stuck. Homo habilis resembles us in many ways, with a large brain similar to ours
as well as small teeth and a face we might recognize as human. But members of the
species also had many ape-like characteristics, such as long arms, hairy bodies, and
adult heights of only three or four feet.

Around two million years ago, a species even more similar to us, Homo erectus,
emerged in East Africa. It likely evolved from Homo habilis. As the name erectus for
“upright” suggests, this species lived entirely on the ground and walked—even
ran—exclusively in an upright position. The consequences of this evolutionary shift were
huge. Being upright meant that the body’s digestive organs were pulled down lower and
into a smaller space. That in turn necessitated a change in diet, away from tough plants
and toward easier-to-digest items like nuts, fruits, tubers, honey, and even meat. Living
on the ground was also more dangerous because it made eluding predators more
difficult. However, the upright position left Homo erectus’s hands free to use tools. This
advantage likely led to further evolutions that made human hands more dexterous over
time, prompting the wider adoption of ever more sophisticated tools.

Members of Homo erectus shared other close similarities with modern humans. They
were about the same height as we are, sometimes reaching just over six feet. They
made and used relatively sophisticated stone tools and relied on fire for both warmth
and cooking food. They likely constructed huts of wood and fur in which to live and
worked cooperatively with each other to hunt and forage. The position of the larynx in
the throat also suggests that Homo erectus may have had some capacity to
communicate vocally, which would have aided in cooperative endeavors. Finally,
archaeologists have uncovered strong evidence that Homo erectus cared for the sick
and elderly. This evidence includes the discovery of the remains of individuals who
suffered from debilitating diseases yet lived a long time, indicating that assistance was
both necessary and provided by others. Together these characteristics made the
species highly adaptable to changing climates and environments, helping explain why
its members survived for so long. Homo erectus populations lived until as recently as
about 100,000 years ago.

Sometime between 1.8 and 1.5 million years ago, Homo erectus started migrating into
other parts of Africa and beyond, reaching North Africa, the Near East, Europe, and
East and South Asia over hundreds of thousands of years. The reasons for this
extensive migration are still debated, but they likely included climate change and the
desire to follow certain types of prey. Homo erectus appears to have stayed close to
rivers and lakes during migration, hunting and eating animals like rhinoceroses, bears,
pigs, and crocodiles, as discoveries in the Near East have confirmed. Populations
evolved to adapt to the different environmental conditions into which they moved. Over
time this led to a diversity of human species, including Homo heidelbergensis; Homo
neanderthalensis, or Neanderthals; Denisovans; and modern humans, or Homo
sapiens (sapiens means “wise”). Some of these species, like Denisovans and
Neanderthals, emerged outside Africa. Others, like Homo heidelbergensis and Homo
sapiens, emerged in Africa first and later migrated to other areas.

The extent to which these different human species interacted with each other remains
unclear. DNA evidence from a bone found in Siberia has shown that a girl (who died at
age thirteen) was born there of a Denisovan father and a Neanderthal mother. Another
recent study demonstrated that modern European and Middle Eastern populations have
between 1 and 4 percent Neanderthal DNA. This appears to suggest that mating
between Homo sapiens and Neanderthals was quite common. The careful work of
archaeologists and other scholars has also made clear that some species evolved from
others. For example, both Neanderthals and Denisovans appear to have evolved from
populations of Homo heidelbergensis.

At some point between forty thousand and fifteen thousand years ago, the diversity of
human species declined and only Homo sapiens remained. Two models attempt to
explain why. The first and most commonly accepted is the “out of Africa” model. This
theory suggests that modern humans emerged first in Africa approximately 200,000
years ago and then, approximately 100,000 years ago, expanded out of Africa and
replaced all other human species. The second model is often called the “multiregional
evolution model” and proposes that Homo sapiens evolved from Homo erectus in
several places around the same time. This model emerged as an explanation for the
great diversity of modern human traits in different populations around the world. But it
relies primarily on the study of fossils and archaeological records rather than on genetic
data.

These theories about human evolution are not necessarily mutually exclusive, and the
real answer to the puzzle may be a combination of the two. For example, it’s entirely
possible that modern humans or a common ancestor did emerge first in Africa. Then, as
this species expanded around the world, it mixed its genetic information with that of
other human species. The DNA evidence collected in recent years certainly suggests a
more complicated picture, and the debate has not yet been settled. The tools of both
archaeology and molecular genetics continue to reveal new insights into the puzzle of
human evolution and the rise of Homo sapiens. And the conclusions we can draw about
our distant past will continue to change as we learn more.

Why Did Humans Move and Where Did They Go?
Archeological evidence indicates that Homo sapiens began migrating out of eastern and
southern Africa as early as 200,000 years ago. This expansion took early humans
deeper south, west, and north as far as the Mediterranean Sea. Approximately 100,000
years ago, groups of Homo sapiens left the African continent and began a global
migration that lasted for tens of thousands of years (Figure 2.6). After crossing the Sinai
into southwest Asia, early migrants out of Africa likely followed the coasts of Asia, and
by about seventy thousand years ago, they had made their way into India and China.

Some groups continued moving south through Malaysia, into Indonesia and beyond. In
places like Papua New Guinea and Australia, there is evidence of settlements at least
forty-five thousand years old. Others groups making their way into southwest Asia from
northern Africa entered Europe around forty thousand years ago, moving either along
the Mediterranean coast or by way of Turkey into the Danube valley. By twenty-five
thousand years ago, Homo sapiens had reached Siberia and other parts of northern
Asia. And approximately fifteen thousand years ago, some groups in Asia crossed into
North America, eventually reaching the tip of South America and settling at various
locations in between.

This timeline has been pieced together based on the analysis of several archaeological
finds. But our knowledge is still limited, and new discoveries frequently require
adjustments to the proposed dates and patterns of global human migration. For
example, we now know that because the Earth was in its most recent ice age during this
period, areas currently covered by water were then dry land. This is true for large
portions of maritime Southeast Asia as well as the Bering Strait between Asia and North
America. Humans were able to walk as far south as Java and from Asia into Alaska.

Yet they also roamed as far as Australia, which was not connected by land to Asia in
this period. This means they must have used rafts of some type, probably by crossing
short distances between islands. Likewise, discoveries of human habitation dating from
fourteen thousand years ago in South America suggest that rafts or boats of some kind
may also have been used to skirt the North and South American coasts. No crafts have
been or may ever be found, but we must assume they existed.

More interesting still, analysis of the remains of the eight-thousand-year-old Kennewick
Man discovered in 1996 in Washington State reveals anatomical features more
consistent with Southeast Asian populations than with those traditionally assumed to
have populated the Americas. This discovery complicates the version of human
migration we think we know, and if anything, it suggests there is much about the
process that we may never fully understand.

But what triggered this migration in the first place? Despite the uncertainties, we can
draw some speculative conclusions. We know that around the same time Homo sapiens
began leaving Africa, the climate there was becoming increasingly dry. Drier conditions
meant fewer of the plants and animals humans needed to survive were available.
Modern humans were hunter-gatherers like their evolutionary ancestors, meaning they
survived by employing the strategies of hunting animals and gathering wild plants rather
than by planting crops and raising livestock. As hunter-gathering societies regularly
forage over a large area, any scarcity of resources in some places or abundance in
others encourages movement. In the lifetime of a single individual, a large-scale
migration would have been barely perceptible, if at all. But over tens of thousands of
years, human populations traversed an enormous portion of the globe. Nor did they go
in a single direction or all at once. Groups likely moved back and forth over areas,
responding to the climatic conditions and availability of resources. There were long
periods of relative stasis punctuated by movement, creating waves of migration in
various directions.

As humans moved into new environments, they adjusted their strategies to be
successful under new conditions. This meant learning to gather different types of plants
and hunt different types of animals they came into contact with, including mastodons,
woolly mammoths and rhinos, various types of grazing animals, and giant sloths and
beavers. The arrival of humans who were highly effective at survival occasionally
accompanied major transformations in their new environments. Scientists who study
now-extinct animals have recognized for some time that human hunting likely
contributed to the decline of a number of these species. Before humans arrived
approximately forty-five thousand years ago, for example, Australia was home to a
number of large reptiles, a marsupial lion (which carried its young in a pouch), and huge
wombats and kangaroos (Figure 2.7). These species began to vanish around the same
time humans reached Australia and well before the climatic warming that led to the
extinction of large animals in other places.

Early Human Technologies
To understand how early humans lived hundreds of thousands and even millions of
years ago, scholars use the tools of archaeology to analyze the objects left behind.
Many were made of materials like wood, animal skin, and earth, which rarely endure in
the archaeological record. Bone items are somewhat more durable and have
occasionally survived. But our window into the distant past is quite small. Stone items
are the most likely to have lasted long enough for us to study them today. Beginning
possibly as early as 3.3 million years ago, our distant pre-human ancestors began using
stone tools for a variety of purposes. This event marks the start of the Paleolithic Age
(lithos means “stone”), which lasted until nearly twelve thousand years ago.

The earliest known human-made stone tools date from about 2.6 million years ago.
They were likely first created by Homo habilis, by smashing smooth rocks together to
create crudely sharpened edges. The resulting implements are often described as
Oldowan tools, and their use continued until about 1.7 million years ago. While a
seemingly simple adaptation from our perspective, the development of Oldowan tools in
fact represents a huge leap in human engineering ability. These sharpened stones
served a variety of cutting, scraping, and chopping purposes. They were highly efficient
tools for killing animals, butchering meat, smashing bones to access marrow, and a host
of similar tasks.

Beginning around 1.7 million years ago, some ancient humans began to develop a new
and more sophisticated style of stone tool by carefully chipping away smaller flakes of
the stone core to create a teardrop-shaped implement often described as a hand-axe.
Far thinner and sharper than the Oldowan tools, hand-axes were even better at the
cutting, scraping, and chopping tasks for which they were designed. They were such an
improvement over earlier tools that archaeologists have given them their own name.
They are called Acheulean tools (pronounced ah-SHOOL-ee-an), after Saint-Acheul,
the site in France where they were first found in the nineteenth century CE. Since then,
more Acheulean tools have been uncovered in Africa, the Middle East, and India and
scattered in parts of East Asia
Far superior to the Oldowan variety, Acheulean tools remained the dominant style of
stone tool until as recently as about 250,000 years ago. At that time a new type of
utensil emerged in Europe, North Africa, and southwestern Asia. Called Mousterian
tools, these implements were smaller hand-axes and tools made from stone flakes
rather than cores. In older traditions, the flakes had been removed in order to shape the
core as desired, such as into a hand-axe. But in the Mousterian tradition, sometimes the
flakes were chipped off in such a way that they themselves could be used as small
knives for cutting meat, scraping leather, and serving as spearheads attached to shafts
(Figure 2.9). Advances to the Mousterian techniques later led to other tool traditions. By
around forty-five thousand years ago, humans were making a great diversity of
specialized tools from stone flakes. These included a variety of scrapers as well as
engraving tools for carving and carefully reshaping softer materials like bone and antler
into either tools or works of art.

Another important tool of our human ancestors was fire. When exactly humans began
controlling fire remains a topic of debate. There is evidence that earlier ancestors like
Homo erectus used it, but we don’t know whether they were able to start fires or merely
used and perpetuated those that naturally occurred. It’s clear, however, that by at least
about 125,000 years ago, if not much earlier, modern humans had learned to start and
control fires.

Controlled fires were useful for staying warm in cold climates, scaring off predators, and
cooking meat to make it easier to consume and digest. Archaeological finds also
suggest that controlled fires aided in the manufacture of certain tools. Wooden spears
could be hardened in the flame, making them more effective hunting implements. Some
types of stone could be treated with heat to make them easier to chip and mold. Fire
also played an important social function. Gathering around the heat and light likely
aided in bonding and helped build the social connections vital for cooperative activities
and group survival.

Sitting around a fire may also have been an occasion for early humans to display one of
their most powerful tools, the unique ability to use sounds as language. There is some
speculation that earlier human ancestors like Homo erectus were able to make sound
and possibly had a type of language. We’ll never know for sure. But we do know that
modern humans are capable of making a great variety of different sounds. Biologists
calculate that we can produce fifty different phonemes, or distinctive sounds. When
strung together in a sophisticated manner, these phonemes can produce many tens of
thousands of words to describe what we see, feel, do, and imagine. Beginning at least
100,000 years ago, modern humans began using language in this fashion, gaining a
major advantage over competing animals. With language, they could coordinate daily
tasks, work much more efficiently in groups, communicate abstract ideas, and pass
important information to successive generations. Few tools aided modern humans more
than their ability to communicate with complex languages.

While they left no record of their discussions, early humans did leave a number of
impressive artistic depictions. The work that has survived includes small animal and
human sculptures, usually made of carved bone or stone. The human-shaped items are
often of large, possibly pregnant, women and might have served as symbols of fertility.
There are also preserved hand prints, created by placing a hand on stone and blowing
pigment around it to preserve the image of its shape.

Some of the most stunning prehistoric art still in existence today consists of cave
paintings dating as far back as forty thousand years. Many painted caves have been
discovered in Spain and France, but there are also examples in England, Italy,
Germany, Russia, and Indonesia. The paintings in the Cave of Altamira in northern
Spain are prime examples of this type of art. Within the cave, and dating to about
thirty-six thousand years ago, are more than two dozen large images of animals
including bison, bulls, horses, deer, and boars. Each is painted in impressive detail
using combinations of charcoal and ochre (a pigment made from clay) to produce bold
reds, yellows, browns, and blacks. In many instances, the artists incorporated features
of the cave walls as part of their designs, giving three-dimensional shape and definition
to the animals they drew

The significance that cave paintings held for the people who created them may never be
fully understood. It was once believed the images were designed to be popularly
admired as interesting decorations, not unlike the ornaments we put in our homes
today. But given that they are often deep in the dark interiors of the caves, where
sunlight could not reach, this interpretation has mostly been abandoned.

With limited insight into the minds of the artists, scholars have concluded that the art
likely served some unknown religious purpose. Many speculate that the caves could
have been used by shamans—men and women thought to have a special knowledge of
the spiritual world—who might have crawled deep into the interior to commune in
ceremonies with a type of spiritual force. Such interpretations remain little more than
educated guesses. What is indisputable is that the art demonstrates that even tens of
thousands of years ago humans had the unique ability to reproduce the world around
them in complex, symbolic fashion, through images we can immediately recognize
today.