Formation of Earth PowerPoint.ppt

Origin of the Universe
The universe began
about 14.4 billion years
ago
The Big Bang Theory
states that, in the
beginning, the universe
was all in one place
All of its matter and
energy were squished
into an infinitely small
point, a singularity
Then it exploded

Origin of the Universe
The tremendous
amount of material
blown out by the
explosion eventually
formed the stars and
galaxies
After about 10 billion
years, our solar system
began to form

We know how the Earth and Solar System are today
and this allows us to work backwards and determine
how the Earth and Solar System were formed
Plus we can out into the universe for clues on how
stars and planets are currently being formed
Birth of the Solar System

In cosmogony, the Nebular Hypothesis is the
currently accepted argument about how a Solar
System can form
The Nebular Hypothesis

We have now discovered over two hundred planets
orbiting other stars
The processes that created our solar system have
also created an uncountable number of other solar
systems
Other Solar Systems

A large gas cloud (nebula) begins to condense
Most of the mass is in the center, there is
turbulence in the outer parts

The turbulent
eddies collect
matter measuring
meters across
Small chunks
grow and collide,
eventually
becoming large
aggregates of gas
and solid chunks

Pictures from the Hubble Space Telescope show
newborn stars emerging from dense, compact pockets
of interstellar gas called evaporating gaseous globules

Gravitational attraction causes the mass of gas
and dust to slowly contract and it begins to rotate
The dust and matter slowly falls towards the
center

The multi-colored area shows a dust disk
surrounding a newborn star
The red-orange area at the center represents the
brightest region, which contains the young star
It is surrounded by the cooler, dusty disk, which
appears as yellow, green and blue
The diameter of the disk is about 20 times larger
than our entire solar system
False Color Image of Protostar

After sufficient mass and density was achieved in
the Sun, the temperature rose to one million °C,
resulting in thermonuclear fusion.
H atom + H atom = He atom + energy
The Sun

Gravitational forces allow the inner planets to
accrue and compact solid matter (including light
and heavy atoms)
Solar radiation blew gases (primarily hydrogen,
helium) away from inner planets
These gases were collected and condensed into the
gas giants (Jupiter, Saturn, Uranus, Neptune)
Beyond Neptune, ice and frozen gases form Pluto,
Sedna and the Kuiper Belt Objects
Left-over debris form comets and asteroids
Protoplanets

Fig. 1.9
Venus, Earth and Mars
These maps are color coded to display different
elevations on the surface of each planet

Earth is ~ 4,570,000,000 years old
The Age of the Earth
Meteorites give us access to debris left over
from the formation of the solar system
We can date meteorites using radioactive
isotopes and their decay products

Bombardment From Space
For the first half billion years of its existence, the
surface of the Earth was repeatedly pulverized by
asteroids and comets of all sizes
One of these collisions formed the Moon

Formation of the Moon
The Giant Impact
Hypothesis predicts
that around 50 million
years after the initial
creation of Earth, a
planet about the size of
Mars collided with Earth
This idea was first
proposed about 30
years ago, but it took
calculations by modern
high-speed computers
to prove the feasibility

This collision had to be very spectacular!
A considerable amount of material was blown off
into space, but most fell back onto the Earth

Part of the material from the collision remained
in orbit around the Earth
By the process collision and accretion, this
orbiting material coalesced into the Moon
The early Moon orbited very close to the Earth

The Early Earth Heats Up
1. Collisions (Transfer of
kinetic energy into
heat)
2. Compression
3. Radioactivity of
elements (e.g. uranium,
potassium, or thorium)
Three major factors that caused heating and melting
in the early Earth’s interior:

The Core
About 100 million years after initial accretion,
temperatures at depths of 400 to 800 km below the
Earth’s surface reach the melting point of iron
In a process called global
chemical differential, the
heavier elements, including
the melted iron, began to
sink down into the core of
the Earth, while the lighter
elements such as oxygen
and silica floated up towards
the surface

Global Chemical Differentiation
This global chemical differential was completed by
about 4.3 billion years ago, and the Earth had
developed a inner and outer core, a mantle and crust

Chemical Composition of Earth
Whole Earth:
Fe+O+Si+Mg = 93%
Crust:
Si+O+Al = 82%
Each of the major layers has a distinctive
chemical composition, with the crust being
quite different from the Earth as a whole

Lithosphere: strong, rocky outer shell of the solid
Earth including all the crust and the upper part of
the mantle to a depth of ~100 km (forms the
plates)
Asthenosphere: weak,ductile layer of the mantle
beneath the lithosphere; deforms to
accommodate the motions of the overlying plates
Deep Mantle: mantle beneath the asthenosphere
(~400 to 2900 km in depth)
Outer core: liquid shell composed of mostly iron
Inner core: innermost sphere composed primarily
of solid iron

Continents: Formed from solidified magma that
floated up from the Mantle
Oceans and Atmosphere:
Fluid and gaseous outer
layers believed to have
been created by out-
gassing of gases and
fluids from volcanic
eruptions (in a process
called volatile transfer)

The Evolving Atmosphere
Right after its creation, the Earth is thought to have
had a thin atmosphere composed primarily of
helium (He) and hydrogen (H) gases
The Earths gravity
could not hold these
light gases and they
easily escaped into
outer space
Today, H and He are
very rare in our
atmosphere

For the next several hundred million years,
volcanic out-gassing began to create a thicker
atmosphere composed of a wide variety of gases
The gases that were released were probably similar
to those created by modern volcanic eruptions

These would include:
Water vapor (H2O)
Sulfur dioxide (SO2)
Hydrogen sulfide (H2S)
Carbon dioxide (CO2)
Carbon Monoxide (CO)
Ammonia (NH3)
Methane (CH4)
Note that oxygen (O2) gas is not created by
volcanic eruptions

It is hypothesized that water vapor escaping from
the interior of the Earth via countless volcanic
eruptions created the oceans (this took hundreds
of millions of years)
Creating the Oceans

Astronomers also
hypothesize that
comets impacting the
Earth were a major
source of water that
contributed to creation
of the oceans
Remember, that
comets are best
described as “dirty ice
balls”
Creating the Oceans

Creating the Oceans
The earliest evidence of surface water on
Earth dates back about 3.8 billion years

A billion Year Old Earth
By 3.5 billion years ago, when the Earth was a
billion years old, it had a thick atmosphere
composed of CO2, methane, water vapor and
other volcanic gases
By human standards
this early atmosphere
was very poisonous
It contained almost no
oxygen
Remember, today our
atmosphere is 21%
oxygen

By 3.5 billion years ago, the Earth also had
extensive oceans and seas of salt water, which
contained many dissolved elements, such as
iron

But most important, by 3.5 billion years
ago, there was life on Earth

The Continents
By 2.5 billion years ago, the
continents had been formed
The density of the continental
crust (2.8 gr/cm3) is lighter
that the crust found on ocean
bottoms (3.2 gr/cm3), so the
continents rise above the
ocean floor
A question that remains
unanswered is, when did
plate tectonics start?

Formation of Earth PowerPoint.ppt

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