From Ethan Siegel: “Ask Ethan: Can The Universe Still End In A Big Crunch?”

Ethan Siegel
May 13, 2017

One of the biggest advances of the 20th century has been to identify exactly how rich, expansive, and massive our Universe actually is. With approximately two trillion galaxies contained in a volume some 46 billion light years in radius centered on us, our Observable Universe allows us to reconstruct the entire tale of our cosmic history, stretching all the way back to the Big Bang and even, perhaps, slightly before. But what about the future? What about the fate of the Universe? Is that a certainty? That’s what Andy Moss wants to know, as he asks:

“You [wrote] that the Universe is expanding at a decreasing rate. I thought a Nobel Prize was awarded for the “discovery” that the Universe was expanding at an increasing rate. Can you please clarify the leading theories? Is the “Big Crunch” still a possibility?”

The best predictor of future behavior is past behavior, it’s true. But just as people can sometimes surprise us, the Universe might, too.

After the Big Bang, the Universe was almost perfectly uniform, and full of matter, energy and radiation in a rapidly expanding state. The Universe’s evolution at all times is determined by the energy density of what’s inside it. NASA / WMAP science team

The expansion rate of the Universe, at any moment in time, is only dependent on two things: the total energy density present within spacetime and the amount of spatial curvature present. If we understand the laws of gravitation and how the different types of energy evolve over time, we can reconstruct what the expansion rate should have been at any moment in the past. We can also look out at a variety of distant objects at various distances, and measure how that light has been stretched due to the expansion of space. Every galaxy, supernova, molecular gas cloud, etc. — everything that absorbs or emits light — will tell the cosmic history of how the expansion of space has stretched it from the moment it was emitted until we observe it.

The farther a galaxy is, the faster it expands away from us, and the more its light gets redshifted, necessitating that we look at longer and longer wavelengths. Larry McNish of RASC Calgary Center

We’ve been able to conclude, from a variety of independent lines of observation, exactly what the Universe is made out of. The three big, independent lines of observation are:

The temperature fluctuations present in the cosmic microwave background, which encode information about the Universe’s curvature, normal matter, dark matter, neutrino, and total density contents.
The correlations between galaxies on the largest scales — known as baryon acoustic oscillations — which give very strict measurements on the total matter density, the normal matter to dark matter ratio, and the expansion rate throughout time.
And the most distant, luminous standard candles in the Universe, type Ia supernova, which tell us about the expansion rate and dark energy as it evolved over time.

Standard candles (L) and standard rulers (R) are two different techniques astronomers use to measure the expansion of space at various times/distances in the past. NASA/JPL-Caltech

These lines of evidence, combined, all point to one consistent picture of the Universe. They tell us what’s in the Universe today, and give us a cosmology where:

4.9% of the Universe’s energy is in normal matter (like protons, neutrons and electrons),
0.1% of the Universe’s energy is in the form of massive neutrinos (which act like matter at late times and radiation at early times),
0.01% of the Universe’s energy is in the form of radiation (like photons),
27% of the Universe’s energy is in the form of dark matter, and
68% is in the form of energy inherent to space itself: dark energy.

They give us a flat Universe (with 0% curvature), a Universe with no topological defects (magnetic monopoles, cosmic strings, domain walls, or cosmic textures), and a Universe whose past expansion history is known.

The relative importance of different energy components in the Universe at various times in the past. In the future, dark energy will approach 100% importance. E. Siegel

The equations governing General Relativity are very deterministic in this sense: if we know what the Universe is made of today and the laws of gravity, we know exactly how important each component was at every juncture in the past. Early on, radiation and neutrinos dominated. For billions of years, dark matter and normal matter were the most important pieces. And for the past few billion years — and this will get more severe as time goes on — dark energy is the dominant factor in the Universe’s expansion. It’s causing the Universe to accelerate, and this is where the confusion (for most people) begins.

Possible fates of the expanding Universe. Notice the differences of different models in the past. The Cosmic Perspective / Jeffrey O. Bennett, Megan O. Donahue, Nicholas Schneider and Mark Voit.

There are two things we can measure when it comes to the Universe’s expansion: the expansion rate and the speed at which an individual galaxy appears to recede from our perspective. These are related, but they are not the same. The expansion rate, on one hand, talks about how the fabric of space itself stretches over time. It’s always quantified as a speed-per-unit-distance, which is typically given in kilometers-per-second (the speed) per Megaparsec (the distance), where a Megaparsec is about 3.26 million light years.

How matter (top), radiation (middle), and a cosmological constant (bottom) all evolve with time in an expanding Universe. E. Siegel / Beyond the Galaxy

If there were no dark energy, the expansion rate would drop over time, approaching zero, since the matter-and-radiation density would drop to zero as the volume expands. But with dark energy, that expansion rate approaches whatever energy density dark energy has. If dark energy, for example, is a cosmological constant, then the expansion rate asymptotes to a constant value. But if that’s what the expansion rate does, then individual galaxies receding from us will see their speeds accelerate.

Optical image of the distant galaxy Markarian 1018, with an overlay of VLT (radio) data. ESO/CARS Survey

ESO/VLT at Cerro Paranal, with an elevation of 2,635 metres (8,645 ft) above sea level

Imagine the expansion rate is some value: 50 km/s/Mpc. If a galaxy is 20 Mpc away, then it appears to recede from us at 1,000 km/s. But give it time; as the fabric of space expands, this galaxy will eventually be farther from us. By time it’s twice as distant, 40 Mpc away from us, it will appear to recede at 2,000 km/s. Over even more time, it will be ten times as far as it began: 200 Mpc, where it now recedes at 10,000 km/s. By time it gets to a distance of 6,000 Mpc from us, it will appear to recede at 300,000 km/s, which is faster than the speed of light. But this goes on and on; the more time passes, the faster the galaxy appears to move away from us. This is what’s “accelerating” about the Universe: the expansion rate goes down, but the speed an individual galaxy moves away from us just rises and rises over time.

The full UV-visible-IR composite of the Hubble eXtreme Deep Field; the greatest image ever released of the distant Universe. NASA, ESA, H. Teplitz and M. Rafelski (IPAC/Caltech), A. Koekemoer (STScI), R. Windhorst (Arizona State University), and Z. Levay (STScI)

NASA/ESA Hubble Telescope

All of this is consistent with our best measurements: that dark energy represents a constant energy density inherent to space itself. As space stretches, the dark energy density remains constant, and the Universe will end in this “Big Freeze” fate, where everything that isn’t gravitationally bound together (like our local group, galaxy, solar system, etc.) winds up being pushed apart from one another. If dark energy is truly a cosmological constant, then the expansion will continue indefinitely, giving rise to a cold, empty Universe.

When astronomers first realized the universe was accelerating, the conventional wisdom was that it would expand forever. However, until we better understand the nature of dark energy other scenarios for the fate of the universe are possible. This diagram outlines these possible fates. NASA/ESA and A. Riess (STScI)

But if dark energy is dynamic – something theoretically possible but observationally without support – it could yet end in a Big Crunch or a Big Rip. In a Big Crunch, dark energy would weaken and reverse sign, causing the Universe to reach a maximum size, turn around, and contract. It could even give rise to a cyclical Universe, where the “crunch” gives rise to another Big Bang. If dark energy continues to strengthen, however, the opposite fate occurs, where bound structures eventually get torn apart by the increasing expansion rate. The evidence we have today, however, overwhelmingly supports a “Big Freeze,” the condition of expansion continuing at a constant rate forever.

The major science goals of upcoming observatories like the ESA’s Euclid, NASA’s WFIRST, and the ground-based LSST include measuring whether dark energy is truly a cosmological constant or not.

ESA/Euclid spacecraft


LSST Camera, built at SLAC

LSST telescope, currently under construction at Cerro Pachón Chile, a 2,682-meter-high mountain in Coquimbo Region, in northern Chile, alongside the existing Gemini South and Southern Astrophysical Research Telescopes.

Although the leading theoretical idea is, in fact, in favor of constant dark energy, it’s important to entertain all the possibilities not ruled out by our measurements and observations. As far fetched as it may seem, a Big Crunch still isn’t ruled out. With more and better data, we may yet find a compelling hint that reality is even stranger than most of us have imagined!

See the full article here .

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“Starts With A Bang! is a blog/video blog about cosmology, physics, astronomy, and anything else I find interesting enough to write about. I am a firm believer that the highest good in life is learning, and the greatest evil is willful ignorance. The goal of everything on this site is to help inform you about our world, how we came to be here, and to understand how it all works. As I write these pages for you, I hope to not only explain to you what we know, think, and believe, but how we know it, and why we draw the conclusions we do. It is my hope that you find this interesting, informative, and accessible,” says Ethan