Lecture 7: Beginning to End

🌌 Overview

This lecture explores the Big Bang Theory, the expansion of the universe, and how our understanding of the universe’s past gives insight into its future. It begins with a seemingly simple question: Why is the night sky dark? — and uses it to unpack the very structure and timeline of the cosmos.

🌑 Olbers’ Paradox: Why is the Night Sky Dark?

If the universe were infinite in space and time and filled with infinite stars, then the night sky should be blindingly bright.
But it’s not — and this leads to the paradox:

“In an infinite and eternal universe, every line of sight should end on a star.”

Implication:

This contradiction suggests:

The universe is not infinitely old
Or it’s not infinite in size
Or it doesn’t have infinite stars

This opens the door to a finite universe that had a beginning.

🌀 The Expanding Universe

Doppler Shift & Spectroscopy

Light from distant galaxies is redshifted, indicating they are moving away from us.
This is not because we’re the center of the universe — rather, space itself is expanding.

Edwin Hubble’s Discovery:

Distant galaxies move faster → Velocity ∝ Distance
This relation is called Hubble’s Law:
v = H₀ × d

Where:

v = recessional velocity
d = distance
H₀ = Hubble constant (~70 km/s/Mpc)

Consequence:

The universe is expanding
If we rewind time, all matter and energy condense to a single point

💥 The Big Bang

Rewinding the expansion leads to a beginning: the Big Bang
Approximate age of the universe:
t ≈ 1 / H₀ ≈ 14 billion years

This is not the origin of all existence, but rather the start of the observable universe and space-time as we know it.

🧪 Evidence for the Big Bang

1. Cosmic Microwave Background (CMB)

Residual heat from ~400,000 years after the Big Bang.
Universe cooled enough for atoms to form, allowing light to travel freely.

2. Primordial Nucleosynthesis

Within the first 3 minutes, the universe formed:
Hydrogen (most common)
Helium
Trace amounts of Lithium, Beryllium
These ratios match predictions and are found in stars and our own bodies.

“You’re not just star stuff — you’re Big Bang stuff.”

🔭 Henrietta Leavitt & Measuring Distance

Cepheid variable stars used as standard candles.
Leavitt’s Law (Period–Luminosity relationship) enabled measurements of galaxies beyond the Milky Way.

Edwin Hubble applied this:

Discovered Andromeda is outside the Milky Way.
Cemented the existence of other galaxies and the expansion of the universe.

🕳️ Black Holes and the Far Future

The Sun will die ~5 billion years from now.
Eventually, all stars will die: universe filled with white dwarfs, neutron stars, black holes.
After 10¹⁰⁰ years, even black holes may evaporate (via Hawking Radiation).

Final stages:

The universe cools and dims toward heat death
Possibility of quantum fluctuations leading to new universes

🧬 What Comes Next?

We are now observing galaxies as they were, not as they are.
The cosmic horizon limits what we can see: ~45 billion light-years away.

Open questions:

Was there a universe before the Big Bang?
Are there other universes?
Are we alone?

💡 Final Thoughts

This lecture offers a sweeping cosmic narrative:

From a paradox about darkness…
To the realization of a universe with a finite beginning
Supported by multiple lines of evidence
And leading to profound questions about our origins, existence, and destiny