{"id":25470,"date":"2023-03-24T19:10:28","date_gmt":"2023-03-24T18:10:28","guid":{"rendered":"https:\/\/www.sciencefocus.com\/?p=69250"},"modified":"2023-03-24T19:37:13","modified_gmt":"2023-03-24T18:37:13","slug":"the-six-numbers-that-define-the-entire-universe","status":"publish","type":"rss_feed","link":"https:\/\/c01.purpledshub.com\/bbcsciencefocus\/rss_feed\/the-six-numbers-that-define-the-entire-universe\/","title":{"rendered":"The six numbers that define the entire Universe"},"content":{"rendered":"

In this edited extract from The Little Book of Cosmology, physicist Prof Lyman Page explains how our model of the Universe relies on just six parameters. <\/p>

By Prof Lyman Page\n \t\t<\/p>

Published: Friday, 24 March 2023 at 12:00 am<\/p>

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How do we study the Universe as a whole?<\/p>\n

My work focuses on the cosmic microwave background<\/a> (CMB) \u2013 the faint energy remnants of the Big Bang<\/a> \u2013 and how measuring it can guide our path to understanding the Universe. But there are many other ways to study the cosmos, and the physicists who study it specialise in everything from General Relativity, to thermodynamics, to elementary particle theory.<\/p>\n

We make observations in nearly every wavelength regime accessible to measurement and with state-of-the-art particle detectors. The observations come from nearby and from the farthest reaches of space. All of this evidence and theory can be put together into a surprisingly simple standard model of cosmology, which has just six parameters. These are the numbers that define our entire Universe.<\/p>\n

The contents of the Universe<\/h2>\n

The first three parameters tell us about the contents of the Universe. We describe them as fractions of a total matter and energy budget, like the components of a pie chart. The first parameter describes the amount of normal matter<\/em>, or atoms, in the Universe, and it says that atoms account for just 5 per cent of the Universe.<\/p>\n

The second parameter describes dark matter<\/em>, some type of new fundamental particle that we do not yet understand, which accounts for 25 per cent of the Universe.<\/p>\n

Remarkably, the amount of dark matter, which we can derive from our measurements of the minute temperature fluctuations in the cosmic microwave background radiation, agrees with the value deduced from observations of the motions of stars and galaxies. However, the value we derive from the CMB measurements is much more precise.<\/p>\n

Our measurements also tell us something else. Because the CMB comes to us from the decoupling era<\/em> \u2013 when the early Universe had cooled enough to set photons free from the hot plasma that had bound them for several hundred thousand years after the Big Bang, causing the Universe became transparent \u2013 we can see that dark matter clearly existed in the early Universe. What\u2019s more, we can see that atoms, the stuff of which we are made, accounts for just one-sixth of the total mass in the Universe.<\/p>\n

The third parameter is the cosmological constant<\/em>, the mysterious dark energy that is at the root of the accelerating expansion of the Universe. This accounts for 70 per cent of the Universe\u2019s total matter and energy budget. We do not know what this dark energy is either, but we know it exists, because we have directly measured its presence through the cosmic acceleration.<\/p>\n

Forming stars and galaxies<\/h2>\n

The fourth parameter is the optical depth<\/em>, or how opaque the Universe was to the photons travelling through it. This is the most astrophysical of all the parameters of the standard model of cosmology. By this, we mean that it captures our rather scant knowledge of the entire complex process of the formation and subsequent explosion of the first stars and the formation of the first galaxies in the Universe.<\/p>\n

The intense light from these early stars and galaxies broke apart the hydrogen that was prevalent in the cosmos into its constituent protons and electrons, causing the reionisation <\/em>of the Universe. In this process, about 5-8 per cent of the CMB photons \u2013 the photons that had been released at the time of decoupling \u2014 were rescattered.<\/p>\n

Read more:<\/strong><\/p>\n