Q1: dust	Q2: space expands	Q3: random H.L.	Q4: helium	Q5: 3K?	Q6: omega

The Four Pillars of Big Bang Cosmology

1. Olbers' Paradox: You've made this observation yourself, thousands of times. The sky is dark at night. See?:
   
   Duh, you say. That's the POINT of night-time! But this simple observation leads to a simple question with a not-so-simple answer. 'Why is the sky dark at night?' is the question. Because the Universe had a beginning, is the answer.
   Consider a Universe which is infinite in size, and also infinite in age. In this case, you have a Universe which has an infinite number of stars in it, all grouped into an infinite number of galaxies, walls and voids. If this is the Universe that we live in, then in any direction you look in the sky, you should see light coming from those stars and galaxies.
   
   It's like standing in a forest. If the forest is very large, then any direction you look, you will see the bark of a tree. To you, the horizon will be uniformly tree-colored. If the Universe is infinite, then any direction you look, you should see a star. To you, the entire sky should be uniformly 'star-colored', i.e. bright. In an infinite Universe, the sky should be bright at night. UNLESS... unless the Universe is not infinitely old. If the Universe has existed for only a finite period of time, then the light from the most distant objects hasn't had time to get here yet, and we should have a mostly dark sky. Which we do! Thus this simple question has a not-so-simple answer---the Universe had a beginning.
   Aside: there is another way out of this paradox. The Universe might not be infinite in size. The observable Universe might be the entire thing. But this is unsavory for several reasons. The most straight-forward of these is that if the observable Universe is the entire thing, then we must be at the center of the actual Universe. How many times to we have to make fools of ourselves before we stop thinking that we are so special that we would be at the center of things?! At least three, apparently... So it is generally accepted, without concrete proof, that the Universe is infinite in size, just so we don't make the same dumb mistake one more time.
   If Olbers' Paradox was all the information we had, no one would be convinced. But it's not.
2. The Expanding Universe: Einstein, in the early years of the last century, predicted that the Universe is unstable (i.e. expands or contracts). He hated this. He was uncomfortable, and didn't like it, and didn't believe it, and was, in fact, so uncomfortable that he invented a 'fudge factor' for his equations in order to force the Universe to sit still. He admitted that he was fudging his numbers, that he was making things up, but he couldn't help himself. An unstable Universe would mean a beginning and an end, and he couldn't handle it.
   Then, in the 1920's, Hubble came along, and observed the velocities and distances of galaxies, and determined that the Universe was, in fact, expanding.
   
   Einstein called his fudge factor 'the biggest blunder' of his life. He was driven by his intellectual honesty to accept a changing Universe, but sadly missed making one of the greatest astronomical discoveries of all time, because he was trapped by his preconceived notions of how the Universe SHOULD be. He was a human being, after all...
   Run the movie backwards. Out there, we see a relatively cold, low-density Universe that is decreasing in density all the time. What happens if we play it in reverse? The Universe comes to higher and higher densities, getting hotter and hotter. At some point in the distant past, the Universe was extremely hot, and extremely dense (but still infinite in size---it hurts your head to think about, I know!). So extremely hot and dense, in fact, that matter as we know it didn't exist. The entire Universe was much like the singularity of a black hole---too hot and too dense for our physics to describe. This is a hot, dense beginning to the Universe. After this, the Universe expands outward. By definition, the Universe begins with a Big Bang. All that from an observation Einstein could have predicted from the maths, but didn't, because it scared him.
3. The Helium Abundance: This is one of the 'derivative' observations. If there was a Big Bang, we should be able to say something about the amount of helium in the Universe, and thereby test the Big Bang. If the predicted values are nothing like the actual values, the Big Bang is trash, and we can throw it out. So, the Universe starts out hot, and then cools down pretty fast, as it expands. This means that there was a time when the conditions were exactly right to form Helium in the entire Universe at once. But after that, the Universe was too cold for fusion nearly everywhere (except in the centers of stars!). Theory predicts the amount of Helium in the Universe should be about 25% (10% from the Big Bang, and ~15% since then, made in stars). This would not be an interesting pillar of support for the Big Bang if it were not EXACTLY the observation that we make!
4. The Cosmic Microwave Background Radiation (CMBR): This is the second of the 'derivative' observations. If there was a Big Bang, we should be able to test the predictions of the theory. If the predictions are nothing like the observed reality, the Big Bang is trash, and we can throw it out and start over.
   The very early Universe was extremely hot and dense---like the center of the Sun. Imagine yourself at the center of the Sun. You couldn't even see your hand in front of your face, even if it was in a special melt-proof suit. Why? Because the Sun is opaque---light can't travel freely through the Sun! The early Universe was too hot for atoms to form, so light never traveled very far at once before it was absorbed. As the temperature falls, atoms begin to form, and the Universe becomes transparent at ~100,000 years after the Big Bang. Radiation is decoupled from matter---i.e. is free to move about space. This is the decoupling era. After this, the Universe is matter-dominated. The radiation that was liberated at that time should still be around, and is. We observe it as the Cosmic Microwave Background Radiation.
   The existence of CMBR and its detection were nearly simultaneous (astronomically speaking). There's a rather funny story about Penzias and Wilson building a radio telescope and thinking the hiss they were receiving came from pigeons. But it didn't. It came from the Big Bang, as they later figured out.
   In 1989 and 1990, a spacecraft named the Cosmic Background Explorer (COBE) was launched, and observed the CMBR. These observations were among the best agreements between theory and prediction ever in astronomy. This is a triumph of modern astrophysics---it's so amazing that at the meeting where it was announced, the team received a standing ovation for their work. (Yes, astronomers are geeks---what are you going to do about it?!)
   
   When this was emitted, the Universe had a temperature of 3000 K. But it looks to us like a blackbody at 3 (actually 2.736) K. How can this be?
   Cosmological Redshift: the Universe is stretching (expanding). As the light travels through it, it gets stretched too, so becomes longer wavelength, lower frequency, redder, looks like a cooler object.
   Here is a picture of the CMBR over the whole sky, with the picture oriented so that the Milky Way is in the middle of the picture.
   The first panel in the above image includes variations in the CMBR due to the fact that the Sun travels around the center of the Galaxy. But this is a very well known phenomenon, and we can subtract it out to get...
   the second panel, which includes contributions to the CMBR from nearby stuff (such as dust and gas in our own Galaxy). But our own Galaxy is pretty well observed, and so we can make a model of it and subtract it out to get...
   the third panel. This panel shows the CMBR as it comes to us from a few hundred thousand years after the Big Bang. It is critical for you to realize what you are looking at. You are looking at light which has been traveling to you since the moment that the Universe became transparent. This is the earliest we will ever be able to see, EVER. You are looking at the Universe when it was very, very young, before any galaxies formed. Wow.
   From this picture, we can find out some things about the Universe. First, the CMBR is remarkably isotropic (same in all directions). The red and blue bumps that you see differ by only one part 10,000 from the 'true' CMBR temperature of 2.73 K. This means that one part might be 2.7301 K, and another part might be 2.7299 K. To you and me, that's pretty much identical. This proves that the temperature and density were nearly uniform everywhere in the Universe at decoupling.
   These variations, however, are important, because they are probably density enhancements that lead to galaxies/clusters. In fact, we can predict what the size of these fluctuations should be, given that we have such and so many galaxies in our current Universe, spread out to a given density. So, of course, we made a model of the Universe, which predicts that the size of the variations should be about one degree on the sky (if the Universe is flat, among other things...). We then went out and sent up a balloon to measure the variations. Take a look at the results:
   
   This plot shows that the size of the fluctuations in the CMBR are about 1 degree on the sky. This is exactly the size predicted by models of a flat Universe. Here we have further evidence that the curvature of the entire Universe is flat.

• The red line shows you where omega is 1. i.e. the region of the plot which gives a flat Universe.
• In the upper left of the plot, you can see that if omega-lambda is much much larger than omega-matter, then there was no Big Bang.
• In the lower right of the plot, you can see that if omega-matter is much much larger than omega-lambda, the Universe will eventually recollapse (because it weighs so much that the mass will pull it all back together again).
• Above and to the right of the red line, where the plot says closed, the curvature is positive, so the Universe is finite yet unbounded. In the region above the gray 'recollapsing' line, the Universe will expand forever.
• Below and to the left of the red line, the curvature is negative, and the Universe is infinite, and will not recollapse.

1. t<10^-43s : density > 10⁹⁵ kg/m³ : T > 10³² K
   This is the 'Planck' era. Unknown physics; quantum gravity
2. t=10^-43-10^-35s : density: 10⁹⁵ -> 10⁷⁵ kg/m³ : T: 10³² -> 10²⁷ K
   This is the 'GUT' era (Grand Unified Theory) The electromagnetic, strong and weak forces were all one at this time. Gravity has separated and become a distinguishable force.
3. t=10^-35-10^-4s : density: 10⁷⁵ -> 10¹⁶ kg/m³ : T: 10²⁷ -> 10¹² K
   This is the 'Hadron' era. Radiation is intense, uniform, like a bright fog. dense mixture of radiation and matter. all particles are the same temperature. high energy light produces pairs, and they annihilate.
4. t=10^-4-10²s : density: 10¹⁶ -> 10⁴ kg/m³ : T: 10¹² -> 10⁹ K
   This is the 'Lepton' era. neutrinos decouple (move freely) Universe too cool to make heavy particles (protons, neutrons), but can still annihilate---most matter destroyed.
5. t=10²-10³s : density: 10⁴ -> 10^-13 kg/m³ : T: 10⁹ -> 10⁴ K
   This is the 'Nuclear' era. deuterium/helium form. neutrons, protons have low enough energy to stick together. light no longer has enough energy to tear them apart. by 10³ seconds, temperature too low to manufacture helium. Most helium in the Universe is primordial helium---was made in the first 900 seconds.

1. Strucure? What causes fluctuations?
2. Flatness? Why is omega-nought so close to 1?
3. Horizon? Why is Universe so isotropic when one edge can't have communicated with the other within the age of the Universe?