Planck mission brings universe into sharp focus

The most accurate and detailed map ever made of the oldest light in the universe reveals new information about its age, contents, and origins.

By Jet Propulsion Laboratory, Pasadena, California, NASA Headquarters, Washington, D.C. — Published: March 21, 2013

This full-sky map from the Planck mission shows matter between Earth and the edge of the observable universe. Regions with less mass show up as lighter areas while regions with more mass are darker. // ESA/NASA/JPL-Caltech

The Planck space mission has released the most accurate and detailed map ever made of the oldest light in the universe, revealing new information about its age, contents, and origins.

Planck is a European Space Agency (ESA) mission. NASA contributed mission-enabling technology for both of Planck’s science instruments, and U.S., European, and Canadian scientists worked together to analyze the Planck data.

The map results suggest the universe is expanding more slowly than scientists thought and is 13.8 billion years old, 100 million years older than previous estimates. The data also show there is less dark energy and more matter, both normal and dark matter, in the universe than previously known. Dark matter is an invisible substance that can only be seen through the effects of its gravity while dark energy is pushing our universe apart. The nature of both remains mysterious.

“Astronomers worldwide have been on the edge of their seats waiting for this map,” said Joan Centrella from NASA Headquarters in Washington, D.C. “These measurements are profoundly important to many areas of science, as well as future space missions. We are so pleased to have worked with the European Space Agency on such a historic endeavor.”

The map, based on the mission’s first 15.5 months of all-sky observations, reveals tiny temperature fluctuations in the cosmic microwave background, ancient light that has traveled for billions of years from the early universe to reach us. The patterns of light represent the seeds of galaxies and clusters of galaxies we see around us today.

“As that ancient light travels to us, matter acts like an obstacle course getting in its way and changing the patterns slightly,” said Charles Lawrence of NASA’s Jet Propulsion Laboratory in Pasadena, California. “The Planck map reveals not only the very young universe, but also matter, including dark matter, everywhere in the universe.”

The age, contents, and other fundamental traits of our universe are described in a simple model developed by scientists called the standard model of cosmology. These new data have allowed scientists to test and improve the accuracy of this model with the greatest precision yet. At the same time, some curious features are observed that don’t quite fit with the simple picture. For example, the model assumes the sky is the same everywhere, but the light patterns are asymmetrical on two halves of the sky, and there is a spot extending over a patch of sky that is larger than expected.

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ESA and the Planck Collaboration

Best map ever of the universe

This map shows the oldest light in our universe, as detected with the greatest precision yet by the Planck mission. The ancient light, called the cosmic microwave background, was imprinted on the sky when the universe was 370,000 years old.

“On one hand, we have a simple model that fits our observations extremely well, but on the other hand, we see some strange features, which force us to rethink some of our basic assumptions,” said Jan Tauber of ESA’s Planck project based in the Netherlands. “This is the beginning of a new journey, and we expect our continued analysis of Planck data will help shed light on this conundrum.”

The findings also test theories describing inflation, a dramatic expansion of the universe that occurred immediately after its birth. In far less time than it takes to blink an eye, the universe blew up by 100 trillion trillion times in size. The new map, by showing that matter seems to be distributed randomly, suggests that random processes were at play in the very early universe on minute “quantum” scales. This allows scientists to rule out many complex inflation theories in favor of simple ones.

“Patterns over huge patches of sky tell us about what was happening on the tiniest of scales in the moments just after our universe was born,” Lawrence said.

Planck launched in 2009 and has been scanning the skies ever since, mapping the cosmic microwave background, the afterglow of the theorized Big Bang that created our universe. This relic radiation provides scientists with a snapshot of the universe 370,000 years after the Big Bang. Light existed before this time, but it was locked in a hot plasma similar to a candle flame, which later cooled and set the light free.

The cosmic microwave background is remarkably uniform over the entire sky, but tiny variations reveal the imprints of sound waves triggered by quantum fluctuations in the universe just moments after it was born. These imprints, appearing as splotches in the Planck map, are the seeds from which matter grew, forming stars and galaxies. Prior balloon-based and space missions learned a great deal by studying these patterns, including NASA’s Wilkinson Microwave Anisotropy Probe (WMAP) and the Cosmic Background Explorer (COBE), which earned the 2006 Nobel Prize in Physics.

Planck is the successor to these satellites, covering a wider range of light frequencies with improved sensitivity and resolution. Its measurements reveal light patterns as small as one-twelfth of a degree on the sky.

“Planck is like the Ferrari of cosmic microwave background missions,” said Krzysztof Gorski from the Jet Propulsion Laboratory in Pasadena, California. “You fine-tune the technology to get more precise results. For a car, that can mean an increase in speed and winning races. For Planck, it results in giving astronomers a treasure-trove of spectacular data and bringing forth a deeper understanding of the properties and history of the universe.”

The newly estimated expansion rate of the universe, known as Hubble’s constant, is 67.15 plus or minus 1.2 kilometers/second/megaparsec. A megaparsec is roughly 3 million light-years. This is less than prior estimates derived from space telescopes, such as NASA’s Spitzer and Hubble, using a different technique. The new estimate of dark matter content in the universe is 26.8 percent, up from 24 percent, while dark energy falls to 68.3 percent, down from 71.4 percent. Normal matter now is 4.9 percent, up from 4.6 percent.

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CHRIS BAKER said:

I've seen nothing that tells me how they deal with the "shadow" that should be created, as far as I know, by our own Milky Way galaxy. Is the CMB radiation not affected? Are they making adjustments based on their ideas of what is there? Is it possible they are wrong and the dark matter is simply lumps of matter that are to small and cool to be seen? That dark energy is simply a mis-measurement of the inertia of the original bang?

Submitted: 4/1/2013 7:34:19 AM (CST)

JEFFREY A KIEHN from CALIFORNIA said:

The Planck data is incredible. It has given theorists lots to chew on and enough information to toss out many competing ideas of inflation and some of particle physics. For example, we can now be fairly confident there are only three flavors of neutrinos- some theories had discussed the possibility of four. Pinning the Hubble Constant down to 67 km/sec/MPc +/- 1.2 from around 72 km/sec/MPc (with larger uncertainty) is a huge result. I can't wait for more research into this data to tell us more amazing things!

Along with the official announcement of the Higgs boson earlier this month, it has been a wonderful month for physics!

Submitted: 3/30/2013 1:00:54 AM (CST)

GERMAIN DUBE said:

And if the universe would breathe in and out,...we would be in the out expension...

Submitted: 3/29/2013 7:25:58 PM (CST)

SAM NAUMAN from TEXAS said:

Wait another 10 years and more recalculations will emerge. This reminds me of the belief in flat earth that was accepted as fact 600 or 700 years ago. The truth is we make many deductions based on flimsy observations. I realize scientists and cosmologists have to start somewhere but still...

Submitted: 3/29/2013 10:57:46 AM (CST)

ROBERT STENTON from OHIO said:

Printed in black and white, the universe appears not one but up to ten definite large circles and ovals spaning to about 1/5 the total width and height area or about 70 degrees. One area even appears to have a bulls eye of seveal circles perfectly inside the other located near the upper- left- middle. Any ideas on what these spots represent. Does the universe have large structures or am I just seeing spots before my eyes?

Submitted: 3/29/2013 9:26:17 AM (CST)

JAMES MAIER from MARYLAND said:

Isn't it time for those who believe in "dark matter" and "dark energy" to recalculate their initial and subsequent matter and energy values?

Submitted: 3/22/2013 3:47:36 AM (CST)

ROBERT L OLDERSHAW from MASSACHUSETTS said:

One possible explanation for the newly verified dipole anisotropy in the CMB is that the structure of the cosmos has a fractal geometry and nature's hierarchy extends far beyond the observable universe.

Unlike the radical idea of a multiverse of 10^500 different universes with random properties, the discrete fractal paradigm proposes one unified physics for the entire cosmos. It is a new paradigm that is based on enlarging the symmetry properties of nature, rather than invoking ad hoc and thoroughly untestable speculations.

Robert L. Oldershaw
http://www3.amherst.edu/~rloldershaw
Discrete Scale Relativity/Fractal Cosmology

Submitted: 3/21/2013 5:13:21 PM (CST)

	Sun	Sun	Moon
RISE	—		—	PHASE	—
SET	—		—	DISK	—

	Mercury	Mercury	Venus	Venus
RISE	—		—
SET	—		—
		—		—

Planck mission brings universe into sharp focus

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