the big bang theory how the universe formed. cosmology the study of the nature and evolution of the...

The Big Bang Theory

How the Universe Formed.

CosmologyThe study of the nature and evolution of the universe.

Not the study of Bill CosbyNot the study of cosmetics and beauty supplies.

Assumptions Made

Assumption 1 :

The universality of physical laws

-> The laws of physics are the same everywhere

FG GM1M2

d2

FG

GM

1

M

2

d2

and

Assumptions Made

Assumption 1 :


Assumption 2 :

The cosmos is homogeneous

-> Matter and radiation are spread out uniformly w/ no large gaps or bunches.

HomogeneousUniverse

Non-HomogeneousUniverse

Assumptions Made

Assumption 1 :


Assumption 2 :


Assumption 3:

The universe is isotropic

-> same properties in all directions

-> no center and no direction

IsotropicUniverse

AnisotropicUniverse

US

US

Assumptions MadeAssumption 1 :


Assumption 2 :


Assumption 3:

The universe is isotropic

Now

Let’s Create

The Universe !!

Imagine

Imagine

NOTHING

Imagine

NOTHINGNothing to see !

Imagine


Nothing to hear !

Imagine


Nothing to hear !

Nothing to feel !

Imagine


Nothing to hear !

Nothing to feel !

Nothing to think !

No Matter !

No Matter !

No Energy !

No Matter !

No Energy !

No Time !

No Pizza !!!!!!!!!

NOTHING

Then, about 13.7 billion years ago,

something happened …..

An infinitely small point of energy is formed.

It disrupts the “nothingness” and begins to expand.

This is where and when the universe began.

Energy and time are created, but no matter !!!

Primeval Fireball

The universe is in an extremely high state of energy, with temperatures estimated to be

greater than 1032 K.

It is just #$?! hot !!!!

But this ball of energy quickly expands and cools.

Heavy Particle EraThe temperature is greater than 1012 K

Less than 0.000001 seconds after the Big Bang

At these temperatures photons collide to produce massive particles and antiparticles, such as

protons and antiprotons.

Heavy Particle Era

The temperature is greater than 1012 K


These massive particles and antiparticles also collide and annihilate each other producing more

photons.

Heavy Particle EraThe temperature is greater than 1012 K


At the end of this era, the universe is a thick soup of heavy particles, antiparticles and energy.

The most important particles present are the protons.

Light Particle EraThe temperature is greater than 6x109 K

Less than 6 seconds after the Big Bang

Because of the lower temperatures during this era, the photons present can’t produce anymore heavy particles. These photons can collide to produce light particles and antiparticles, like

electrons and positrons.



During this era protons and electrons interact to form neutrons. Antiprotons and positrons

interact in the same way.

Proton (+)

Electron (-)

Neutron



Some of the neutrons decay back into protons and electrons. The neutrons which survive are

very important for the next era.

Proton (+)

Electron (-)

Neutron



At the end of this era the universe consists of heavy and light particles (protons & electrons).

The universe also has neutrons.



At the end of this era the universe consists of heavy and light particles (protons & electrons).

The universe also has neutrons.

The low temperatures don’t allow any more matter/antimatter pairs to form from colliding photons and no more neutrons can be formed.

Nucleosynthesis EraThe temperature is around 109 K


The neutrons which remain react with the protons to form an isotope of Hydrogen called

Deuterium. (1 proton and 1 neutron)



The neutrons which remain react with the protons to form an isotope of Hydrogen called

Deuterium. (1 proton and 1 neutron)

All neutrons either become part of the Deuterium or decay.



Deuterium fuses to form Helium. At this point the total mass of the Helium formed is about

25% the total mass of the universe.



Deuterium fuses to form Helium. At this point the total mass of the Helium formed is about

25% the total mass of the universe.

Some Tritium (Hydrogen with 2 neutrons), Lithium and Berylium also form.

Nucleosynthesis Era

The temperature is around 109 K


In the first 5 minutes after the Big Bang, heavy and light particles and antiparticles are formed.

Nucleosynthesis Era



In the first 5 minutes after the Big Bang, heavy and light particles and antiparticles are formed.

Neutrons are formed from protons and electrons, these neutrons combine with the protons to form

the first stable nuclei of atoms. (Note: These atoms still have not captured the electrons, too

much energy)

Nucleosynthesis Era


About 1 million years after the Big Bang

At these low temperatures the nuclei which have formed can now capture electrons and become

neutral.

Nucleosynthesis Era


About 1 million years after the Big Bang

At these low temperatures the nuclei which have formed can now capture electrons and become

neutral.

This allows light and radiation to pass through the neutral atoms and expand throughout the

universe cooling to around 2.7 K

Matter Era

The temperature is less than 3000 K

Over 1 million years after the Big Bang

With the radiation and matter freed from each other, the pressures which kept the matter from

clumping together is now greatly reduced.

Matter Era





Matter is able to clump together forming galaxies, stars, and the Earth.

Matter Era





Matter is able to clump together forming galaxies, stars, and the Earth.

We are still in this era.

Evidence of the Big Bang

No human was present at the beginning of the universe, so how do we know

this is what happened ?

What evidence is there ?


We can’t test our ideas by creating little universes (although this would be

really cool.)

What evidence is there ?


To answer this question we must first recall how science is done.



Scientists first create a model based on observations.




Then scientists make predictions based on these models.




Then scientists make predictions based on these models.

Scientists then try and verify these predictions experimentally or observationally.


Prediction

The most abundant element in the universe should be Hydrogen.


Prediction

The most abundant element in the universe should be Hydrogen.

Observation

Although we clearly can’t test the entire universe, all celestial objects we can see tell us that the most

abundant element in each is hydrogen.


Prediction

The concentration of Helium should be greater than 25%.


Prediction

The concentration of Helium should be greater than 25%.

Observation

Directly observing evidence of helium is difficult, but when we can measure its concentration in stars we

find that it ranges from 27 to 30 % Helium.


Prediction

The universe should be expanding

Edwin Hubble Vesto M. Slipher


Prediction

The universe should be expanding

Observation

In 1928, Edwin Hubble and Vesto M. Slipher, confirmed separately that the universe is expanding. They used the Doppler Red Shift of stars and galaxies

to prove this.


Prediction

When the universe began, the four fundamental forces were actually one force.


Prediction


Observation

This hasn’t been completely proven, but there is an incredible amount of symmetry between the forces,

look at Coulomb’s Law (Electrical Force) and Newton’s Law of Gravitation (Gravitational Force).


Prediction


Observation

In 1983, at Cern Labs, particles were slammed together in their accelerator at extremely high

temperatures and the Electromagnetic Force and the Weak Force were shown to be one force called the

Electroweak force.

Evidence of the Big BangDirect Observation of the Visible Universe

It takes a finite amount of time for light to travel a distance. In one second light travel about 300,000,000 meters.



The distance light travels in a year is called a light year (ly).



The distance light travels in a year is called a light year (ly).

When we look at objects, like stars and galaxies we are actually looking into their past.

Direct Observation of the Visible Universe

• It takes light from the Sun approximately 8.3 minutes to reach the Earth

• This means that if we are looking at the Sun we see how it was 8.3 minutes ago. We are looking into the past.


• Alpha Centauri is 4.3 ly away.

• This means it takes light from this star 4.3 years to reach us.

• We are looking 4.3 years into the past.


• The galactic center is 20,000 to 30,000 ly away.

• This means it takes light from the galactic center 20,000 to 30,000 years to reach us.

• We are looking 20,000 to 30,000 years into the past.


• The Andromeda galaxy is 2 million ly away.

• This means it takes light from this galaxy 2 million years to reach us.

• We are looking 2 million years into the past.


• The Hydra Cluster is 3.6 billion ly away.

• This means it takes light from this cluster of galaxies 3.6 billion years to reach us.

• We are looking 3.6 billion years into the past.


• This galaxy is 13.2 billion ly away.

• This means it takes light from this galaxy 13.2 billion years to reach us.

• We are looking 13.2 billion years into the past. Not real long after the Big Bang


Background Radiation

A crucial moment in the creation of the universe was when the atoms that were present became neutral and the radiation was

able to flow through it and expand with the universe.

This allowed matter to begin clumping to form the structures we observe in the universe.


Prediction

The temperature of the background radiation is 2.7 K

Robert Wilson

Arno Penzias


Prediction

The temperature of the background radiation is 2.7 K

Observation

In 1964, Robert Wilson & Arno Penzias, detected this background radiation and determined its temperature to be 3.5 K. For this they received the Nobel Prize in

Physics. Further experiments have found that temperature to be 2.7 K.

Map of the Background Radiation

In 2003 the WMAP satellite mapped the cosmic background

radiation, further confirming its

temperature to be 2.7 K.

This map also gave us great detail about the early universe and it

allowed us to refine the age of the universe to

13.7 billion years.

Map of the Background Radiation

This picture shows us how the universe looked 379,000 years after the Big Bang.

Now

Let’s Destroy

The Universe !!

The End of the Universe

There are three possible futures for our universe.

Which one will be our fate depends on the total mass of the universe or more

accurately, its density.


It was Albert Einstein who calculated a critical density

for the universe.



for the universe.

This value is about 5 x 10-27 kg/m3 .



for the universe.

This value is about 5 x 10-27 kg/m3 .

The fate of the universe depends on whether or not

the density is above or below this value.


The density of the universe is less than the critical value of 5 x 10-27 kg/m3

The gravitational pull of the universe will not be enough to stop the expansion of the universe.




The universe will expand forever.




The universe will expand forever.

The overall temperature of the universe will decrease



The stars will all eventually burn out and no new stars will form.



The stars will all eventually burn out and no new stars will form.

Protons will eventually begin to decay. This is when the matter era will end and the universe will become just a soup of quarks and other subatomic particles.


The density of the universe is equal to the critical value of 5 x 10-27 kg/m3

The gravitational pull of the universe will ultimately stop the expansion of the universe.


The density of the universe is equal to the critical value of 5 x 10-27 kg/m3

The gravitational pull of the universe will ultimately stop the expansion of the universe.

An equilibrium will be reached and the universe will last forever in this state (it may or may not be the

matter era).


The density of the universe is greater than the critical value of 5 x 10-27 kg/m3

The gravitational pull of the universe will ultimately stop the expansion and cause the universe to collapse.




The universe will return to one point and time.




The universe will return to one point and time.

Will the universe begin again ????


Currently scientists have determined the density of the universe to be less than 5 x 10-27 kg/m3.



If this is true the universe will expand forever.




BRRRRRRRRR !!!!!!!!




BRRRRRRRRR !!!!!!!!

However the discovery of dark matter could change the ultimate fate of the universe.

the big bang theory how the universe formed. cosmology the study of the nature and evolution of the...

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