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3.4: Formation of the Universe

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    12775
  • Before Hubble, most astronomers thought that the universe didn’t change. But if the universe is expanding, what does that say about where it was in the past? If the universe is expanding, the next logical thought is that in the past it had to have been smaller.

    The Big Bang Theory

    The Big Bang theory is the most widely accepted cosmological explanation of how the universe formed. If we start at the present and go back into the past, the universe is contracting, getting smaller and smaller. What is the end result of a contracting universe? According to the Big Bang theory, the universe began about 13.7 billion years ago. Everything that is now in the universe was squeezed into a very small volume. Imagine all of the known universe in a single, hot, chaotic mass. An enormous explosion—a big bang—caused the universe to start expanding rapidly. All the matter and energy in the universe, and even space itself, came out of this explosion. What came before the Big Bang? There is no way for scientists to know since there is no remaining evidence.

    Timeline of the universe measuring the big bang expansion over a time period of 13.7 billion years. The initial point of the universe began with quantum fluctuations and inflation. This was followed by the Afterglow light patter, which lasted approximately 380,000 years. There was a period of a darkness, and then the first stars appeared about 400 million years later. Since then, galaxies and planets have developed as dark energy has accelerated expansion.
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    After the Big Bang

    In the first few moments after the Big Bang, the universe was unimaginably hot and dense. As the universe expanded, it became less dense and began to cool. After only a few seconds, protons, neutrons, and electrons could form. After a few minutes, those subatomic particles came together to create hydrogen. Energy in the universe was great enough to initiate nuclear fusion and hydrogen nuclei were fused into helium nuclei. The first neutral atoms that included electrons did not form until about 380,000 years later.The matter in the early universe was not smoothly distributed across space. Dense clumps of matter held close together by gravity were spread around. Eventually, these clumps formed countless trillions of stars, billions of galaxies, and other structures that now form most of the visible mass of the universe. If you look at an image of galaxies at the far edge of what we can see, you are looking at great distances. But you are also looking across a different type of distance. What do those far away galaxies represent? Because it takes so long for light from so far away to reach us, you are also looking back in time.

    This illustration separates the XDF into three planes showing foreground, background, and very far background galaxies. These divisions reflect different epochs in the evolving universe. Fully mature galaxies are in the foreground plane that shows galaxies as they looked fewer than 5 billion years ago. The universe is rich in evolving, nearly mature galaxies from 5 to 9 billion years ago. Beyond 9 billion years the universe is awash in compact galaxies and proto-galaxies, blazing with young stars.
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    • Stephen Hawking - The Big Bang. Authored by: The Cosmos Is Also Within Us. Located at: https://youtu.be/gs-yWMuBNr4. License: All Rights Reserved. License Terms: Standard YouTube License
    • CERN's supercollider. Authored by: Brian Cox. Provided by: TED-Ed. Located at: https://youtu.be/u8C2Un6Gjhk. License: All Rights Reserved. License Terms: Standard YouTube License
    • Why is our universe fine-tuned for life?. Authored by: Brian Greene. Provided by: TED. Located at: https://youtu.be/bf7BXwVeyWw. License: All Rights Reserved. License Terms: Standard YouTube License
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