Cosmology, the study of the universe as a
whole, has been turned on its head by a stunning discovery that the universe is flying apart
in all directions at an ever-increasing rate. Is the universe bursting at the seams? Or is nature somehow fooling us? The astronomers whose data revealed this accelerating
universe have been awarded the Nobel Prize for Physics. And yet, since 1998, when the discovery was
first announced, scientists have struggled to come to grips with a mysterious presence
that now appears to control the future of the cosmos: dark energy. On remote mountaintops around the world, major
astronomical centers hum along, with state of the art digital sensors, computers, air
conditioning, infrastructure, and motors to turn the giant telescopes. Deep in Chile's Atacama desert, the Paranal
Observatory is an astronomical Mecca. This facility draws two megawatts of power,
enough for around two thousand homes. What astronomers get for all this is photons,
tiny mass-less particles of light. They stream in from across time and space
by the trillions from nearby sources, down to one or two per second from objects at the
edge of the visible universe. In this age of precision astronomy, observers
have been studying the properties of these particles, to find clues to how stars live
and die, how galaxies form, how black holes grow, and more. But for all we've learned, we are finding
out just how much still eludes our grasp, how short our efforts to understand the workings
of the universe still fall. Cosmology, the study of the universe as a
whole, goes back to the ancient Greeks. With no telescopes or other optical instruments
to probe the stars... observers constructed models designed to make sense of what they
saw. Their earliest theories stated that all matter
in the Universe is composed of some combination of four elements. Earth. Water. Fire. And Air. Each arises from opposing properties of heat
and cold, dry and wet, acting upon more primitive forms of matter. Aristotle took it a step further. He held that the universe is divided into
two parts, the realm of Earth, in which everything is composed of the four substances, and the
realm of the stars and planets. These bodies are made up of a fifth substance,
unchanging and incorruptible, called aether or quintessence. The Greek idea that the universe is a series
of concentric circles, with Earth at the center, yielded to a wealth of new discoveries about
the universe. That Earth is a planet. In a solar system. Located in a giant wheel of stars and gas,
a galaxy. Bound by gravity to a local group of 30 galaxies. Bound, in turn, to a cluster of over a thousand
galaxies, and to a supercluster with tens of thousands of galaxies This, our cosmic region, takes up a volume
about 100 million light years across, set within a larger pattern of galaxy filaments,
superclusters, and enormous empty voids. Earth is but a speck, within a firmament so
vast we can scarcely imagine it. For all we've learned from snatching photons,
the most basic nature of the universe has only grown more mysterious. Ironically, modern models have recalled the
mysterious fifth element conjured by the Greeks to explain a universe that appears to move
in ways not easily explained. To understand the predicament now faced by
scientists, let's see how they got there in the first place. A hundred years ago, most astronomers believed
the universe consisted of a grand disk, the Milky Way. They saw stars, like our own sun, moving around
it amid giant regions of dust and luminous gas. The overall size and shape of this "island
universe" appeared static and unchanging. That view posed a challenge to Albert Einstein,
who sought to explore the role that gravity, a dynamic force, plays in the universe as
a whole. There is a now legendary story in which Einstein
tried to show why the gravity of all the stars and gas out there didn't simply cause the
universe to collapse into a heap. He reasoned that there must be some repulsive
force that countered gravity and held the Universe up. He called this force the "cosmological constant." Represented in his equations by the Greek
letter Lambda, it's often referred to as a fudge factor. In 1916, the idea seemed reasonable. The Dutch physicist Willem de Sitter solved
Einstein's equations with a cosmological constant, lending support to the idea of a static universe. Now enter the American astronomer, Vesto Slipher. Working at the Lowell Observatory in Arizona,
he examined a series of fuzzy patches in the sky called spiral nebulae, what we know as
galaxies. He found that their light was slightly shifted
in color. It's similar to the way a siren distorts,
as an ambulance races past us. If an object is moving toward Earth, the wavelength
of its light is compressed, making it bluer. If it's moving away, the light gets stretched
out, making it redder. 12 of the 15 nebulae that Slipher examined
were red-shifted, a sign they are racing away from us. Edwin Hubble, a young astronomer, went in
for a closer look. Using the giant new Hooker telescope in Southern
California, he scoured the nebulae for a type of pulsating star, called a Cepheid. The rate at which their light rises and falls
is an indicator of their intrinsic brightness. By measuring their apparent brightness, Hubble
could calculate the distance to their host galaxies. Combining distances with redshifts, he found
that the farther away these spirals are, the faster they are moving away from us. This relationship, called the Hubble Constant,
showed that the universe is not static, but expanding. Einstein acknowledged the breakthrough, and
admitted that his famous fudge factor was the greatest blunder of his career. The discovery revolutionized astronomy because
it redefined the universe as a dynamic realm. But if he were around today, Einstein would
be surprised to see his own failed idea return. If the universe is expanding, it must have
emerged from a dense and hot primordial state. A cosmic fireball, we now call the big bang,
would have supplied the initial kick. Even as the universe expanded, gravity began
drawing matter together into a web-like structure that gave rise to galaxies and stars. If there's enough matter out there, will gravity
oneday reign in the big bang, and cause the universe to collapse in on itself? To find out, astronomers renewed Hubble's
quest to precisely measure the cosmic expansion rate. Working with the Hubble space telescope, and
giant new observatories on land, they sought to measure distances far deeper than Hubble
ever could. People are talking about doing precision cosmology
for the first time. Because it used to be, "Cosmology, well we
have a rough idea of how big the universe is, maybe to a factor of two or three." But now with these new measurements we're
really getting a handle on the overall density and structure of the universe. And what they are telling us is not what we
expected to hear. Hubble's mileage markers were the cepheids. Today, astronomers look for stars like our
sun in their death throes. They spend their lives gradually consuming
the hydrogen gas that makes up their cores. At the end of the line, the dying star swells
and sheds its outer layers, leaving behind a tiny sphere the size of Earth. It's so dense that if you could scoop out
a teaspoonful of matter from its core, it would weight a thousand metric tons. If this white dwarf happens to orbit another
dying star, it may begin to draw upon the companion's expanding outer layers. At a critical threshold, it can grow no more,
and it explodes. Scientists at the University of Chicago and
Argonne National Lab have been simulating the thermonuclear reaction that begins deep
within the star. A nuclear flame sends hot ash rising to the
surface. It breaks out then begins to wrap around the
star. A collision on the other side of the star
triggers the explosion. Because type 1A supernovae are all thought
to explode in the same way, and because they are extremely bright, they are ideal for measuring
extreme distances. It's like looking at cars with identical headlights
approaching on a highway. The dimmer they appear, the farther away they
are. By documenting explosions through the depth
of the universe, two groups of astronomers had hoped to find out how quickly gravity
has been reigning in the cosmos. Capturing the trickle of photons from events
six or eight billion years ago would test the sensitivity of even the most powerful
modern telescopes. When they spotted a type 1a supernova, astronomers
looked at how much its light was shifted to the red. The larger the shift, the more the universe
had expanded since the explosion. They combined this measurement with its distance,
based on the apparent brightness of the supernovae. Some explosions looked dimmer than expected
based on their redshift. That meant their light had traveled over a
greater distance to reach us. That led the two teams to the same conclusion,
that the cosmic expansion rate had been slower in the deep past. For the universe to reach its current size,
the expansion had to actually accelerate. Scientists have known since the 1930s that
the universe is not necessarily the way it appears. Back then, astronomer Fritz Zwicky measured
the rotation rate of spiral galaxies and found that their gravitational pull was over 100
times greater than what he expected based on the amount of matter he could see. There must be some gravitational presence,
Zwicky surmised, that you can't see with a telescope. He dubbed it "dark matter." Scientists today have successfully recreated
the structure of the universe in computer simulations by incorporating dark matter in
the gravitational sources that sculpted galaxy clusters and filaments. Apparently, there's another unseen presence
at work in the universe, called "dark energy." And it's whisper thin. For comparison's sake, water has a density
of 1 gram per cubic centimeter. Dark energy is a mere 10-29 grams per cubic
centimeter. That's a point followed by 28 zeros and a
1, the equivalent of 5 hydrogen atoms in a cubic meter. In their scan of the early universe using
the WMAP satellite, scientists concluded that matter and dark matter account for only about
26% of the content of the universe. The remainder, then, is dark energy. Since 1998, something totally unexpected happened,
which is that we discovered not only that our universe is expanding, this expansion
is accelerating. You know, this is a classical "who ordered
that?" type situation. If 70% or so is dark energy in the universe,
you know about 70% of the surface of the Earth is covered with water. Imagine we didn't have a clue what water was. This is the situation we're in. So what exactly is it? The simplest answer takes us back to Einstein
and his repulsive force, the cosmological constant. It's the idea that empty space is actually
a seething stew of particles popping in and out of existence. It's a type of energy that is constantly welling
up from the vacuum. This description is reminiscent of the sudden
and violent outpouring of energy that many scientists believe launched our universe in
the first place. Long after the big bang, vacuum energy exerted
enough pressure over extremely large scales to push the universe out. And, as the universe grew larger, more and
more of it came into existence, causing the expansion to accelerate. Another explanation takes its name from Aristotle's
Quintessence. While similar to vacuum energy, in theory
it can vary over time. There are still other theories. One unifies dark energy and dark matter into
a single dark fluid that alters the action of gravity on large scales. Another digs deep into a warren of hidden
physics... to suggest that the push of dark energy may one day turn to a pull. This theory predicts that in about ten billion
years, the universe will begin cascading back together in a big crunch destined to reduce
all of creation to the size of a proton. Is there a way out of all this cosmic confusion? Some scientists suggest that the findings
derived from type 1A supernovae might be based on an illusion... that the measurements are
due not to cosmic acceleration, but to large-scale factors we have not yet detected. Since Nicolaus Copernicus showed that the
Earth rotates around the sun, cosmologists have based their theories on the idea that
we exist in no special place. In that case, our view of the universe is
similar to any other vantage point in the universe. That assumption has allowed us to extrapolate
what we see to a vast scale. We concluded, for example, that the universe
has expanded in a uniform manner. That explains the uniform temperature of light
from the early universe, within which we can see a pattern of variations. And it explains the uniform distribution of
galaxies, within which we see a pattern of filaments and clusters. Is it possible that we are still only seeing
part of a much grander cosmic map? It's like looking at a desert and assuming
the rest of the world is flat, when in fact it's filled with oceans and mountain ranges. Perhaps there are non-uniform cosmic structures
larger than our field of view, forming bulges or bubbles. For argument's sake, if we are located in
the center of a giant bubble, then supernovae out on the fringes might seem to be accelerating
away. Or if we're in a region of higher density,
the universe might appear headed for collapse. For now, it looks like the discovery of the
accelerating universe is holding up. Scientists using NASA's Galaxy Evolution Explorer
telescope confirmed the finding by using galaxies in the distant universe as another kind of
mileage marker. As another check, they calculated the speed
that galaxies should collapse into clusters based on their collective gravity. The data showed that something is holding
them back, and breaking their fall into the clusters. The discovery of dark energy is a major accomplishment
in this age of precision cosmology. Ironically, its effects may well be lost on
our distant descendents. Right now, we're in the outer suburbs of a
great cosmic metropolis, the Virgo Supercluster. In time, gravity will drag the Milky Way and
the rest of the local group into the city limits, then stir us into the giant melting
pot of a mega-galaxy. By then, if the wider universe is accelerating
outward, we'll see little evidence of where it all came from. Distant galaxies visible today will begin
to pass beyond our vision at speeds exceeding that of light. Those distant generations will know less about
the nature of time and space than we do today. For now, as the data trickles in one photon
at a time, our minds struggle to unravel the mysteries of a dark universe, as they race
ever faster beyond our dim horizons. 6
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