Cosmology and the Origin of Life

After neutrino decoupling:

electron+anti-electron photon+photon is now favored over the reverse reaction photon+photon electron+anti-electron

Thus, after the neutrinos decouple, the Universe gets an "extra" source of photons (heating) which the neutrinos never see. Hence the neutrino background is colder (lower energy) than the photon background

Census is now: 76% protons; 24% neutrons or roughly a 3:1 ratio of protons to neutrons

We are now at the end of particle creation from the photon field

The Universe consists of protons, neutrons and electrons plus a photon background and a neutrino background. However, the neutrons are in danger of decaying away completely. No more neutrons, no elements, no life.

opps ...

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Epoch #4:

• time = 14 seconds
• temperature = 3 billion degrees

Electrons and anti-electrons now freeze out. These are the lighest particles that we know of and hence have the longest formation window.

All these electron and anti-electron pairs now annihilate thus producing the final photon background with characteristics such that there are one billion photons for each particle.

Stable nuclei (e.g. Helium) can't form yet because the Universe is expanding very fast and is still filled with very high energy photons.

At this time, there are 83% protons and 17% neutrons and the neutrons are decaying to 0%.

Epoch #5:

• time = 3 minutes
• temperature = one billion degrees

Conditions in the universe (temperature and density) are now very similar to conditions inside a star.

Universe is now 87% protons and 13% neutrons

p/n ratio is 7

What prevents the decay of neutrons?

Unless neutrons are bound in an atomic nuclei, they will decay. Therefore we need to make atomic nuclei.

How do we do this?

Thermonuclear Fusion

Making Helium:

But, deuterium is a very fragile nucleus and can easily be broken apart by a high energy photon (which are also created when the anti-electron meets an electron).

pn + photon --> p + n (which will decay in 900 seconds)

Now there is an interesting race condition:

Will deuterium combine with another proton to make a nucleus with 3 nucleons or will it be photodissociated before it can do this?

This race condition depends on the density of protons:

• if the density is high then deuterium will fuse with another proton to make ³He

• if the density is low then most of the deuterium will be photo- dissociated before making ³He

• a high density universe means a low density of deuterium

• a low density universe means a low density of Helium (3 and 4).

So things are trying to proceed as follows:

The end result is the conversion of 2 protons and 2 neutrons into 1 ⁴Helium nucleus.

Before the Reaction:

• 14 protons and 2 neutrons

After the reaction

• 12 protons and 1 ⁴Helium nucleus

The mass of ⁴Helium is about 4 times the mass of a proton

Now we can make a prediction:

The helium abundance reflects three things:

1. The p/n ratio at the time that nucleosynthesis starts
2. The ratio of photons to baryons
3. The actual baryon density

Element Production beyond helium:

• Lithium/Boron Production
• It stops at Boron

We have now finished the first step in the process

Overview of the First Three Minutes:

Observations:

• The Universe is Expanding
• Currently there is a photon background that peaks in the Microwave part of the spectrum. This indicates the current temperature of the Universe is 3K.
• The ratio of photons to baryons now is 1 billion to one.

The observations indicate that the universe is expanding and cooling (just like an expanding gas cools). Hence, in the past the Universe was hotter and denser than it is currently. Extrapolation to the distant past demands that the Universe was very hot and very dense.

The condition of thermal equilibrium means that the behavior of the Universe at any epoch is dependent on its Temperature.

At early times, the energy density of the photons was so high that you could get particle creation from the photon field and/or energy creation from the matter field.

photon+photon <=====> particle + anti-particle

The kinds of particles +anti-particles that are created depends strictly on the average energy per photon which depends only on the temperature.

If photon energy is less than m_pc² then m_p can't be created; only particles with mass less than m_p will be created.

Since a proton is 2000 times heavier than an electron, the window of opportunity for creating electrons from the photon field is a lot longer than for creating protons.

In the very early Universe, lots of strange pairs of particles could have been produced from Quantum Fluctuations --> we know very little of this physics.

10^-6 seconds to 0.1 second was the window of opportunity for creating protons and neutrons and other "normal" particles.

The Universe was opaque to neutrinos prior to it being a second old and this kept the abundance of protons equal to that of neutrons.

At 1 second the neutrinos escape and the neutrons start to decay. The only thing that prevents their decay is zero is the formation of atomic nuclei via thermonuclear fusion.

This fusion epoch starts around t=3 minutes and lasts until t=15 minutes. The proton-to-neutron ratio at the start of this epoch is 7-to-1. This ratio makes a solid prediction about The Helium Abundance of the Universe which is described above.

Three big unknowns in the above are:

• What is the physics of the very early Universe when all the forces were unified.

• What physics determined the masses of the particles? That is, why does a proton weigh what it does?

• What physics determined the matter-vs-anti-matter asymmetry. That is, why for every 1 billion anti-protons there was 1 billion and 1 protons.

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