ESA: Planck unveils the Universe – now and then

[bystander]

Planck unveils the Universe – now and then
ESA Space Science | Planck | 05 July 2010

ESA’s Planck mission has delivered its first all-sky image. It not only provides new insight into the way stars and galaxies form but also tells us how the Universe itself came to life after the Big Bang.

“This is the moment that Planck was conceived for,” says ESA Director of Science and Robotic Exploration, David Southwood. “We’re not giving the answer. We are opening the door to an Eldorado where scientists can seek the nuggets that will lead to deeper understanding of how our Universe came to be and how it works now. The image itself and its remarkable quality is a tribute to the engineers who built and have operated Planck. Now the scientific harvest must begin.”

From the closest portions of the Milky Way to the furthest reaches of space and time, the new all-sky Planck image is an extraordinary treasure chest of new data for astronomers.

The microwave sky as seen by Planck

Click to view full size image

This multi-frequency all-sky image of the microwave sky has been composed using data from Planck covering the electromagnetic spectrum from 30 GHz to 857 GHz.

The mottled structure of the CMBR, with its tiny temperature fluctuations reflecting the primordial density variations from which today’s cosmic structure originated, is clearly visible in the high-latitude regions of the map. The central band is the plane of our Galaxy. A large portion of the image is dominated by the diffuse emission from its gas and dust. The image was derived from data collected by Planck during its first all-sky survey and comes from observations taken between August 2009 and June 2010. This image is a low- resolution version of the full data set.

To the right of the main image, below the plane of the Galaxy, is a large cloud of gas in our Galaxy. The obvious arc of light surrounding it is Barnard’s Loop – the expanding bubble of an exploded star. Planck has seen whole other galaxies. The great spiral galaxy in Andromeda, 2.2 million light-years from Earth, appears as a sliver of microwave light, released by the coldest dust in its giant body. Other, more distant, galaxies with supermassive black holes appear as single points of microwaves dotting the image.

Credits: ESA/LFI & HFI Consortia

[bystander]

The sky according to Planck
Bad Astronomy | 05 July 2010

The European Space Agency just released the first all-sky survey taken by their Planck orbiting observatory, and it’s a beauty!

Click to view full size image

[youtube]http://www.youtube.com/watch?v=eE7-6fQ9 ... r_embedded[/youtube]

Planck observes the sky from the far infrared all the way out to near radio frequencies, detecting cold gas and dust, star forming regions, and even the subtle and cooling glow of the background fire from the Big Bang itself. In this image, infrared is blue, and the longer wavelengths (out toward the radio part of the spectrum) are progressively more red ...

The line running horizontally across the image is the Milky Way galaxy itself. The galaxy is a flat disk, and we’re inside it, so it looks like a line ... The wispy material in the image is dust blown up out of the disk by the fierce combined winds of thousands of young massive stars when they are born, and also when they die and explode ... The reddish glow you can see near the poles of the picture is from the Cosmic Microwave Background, the fading glow of the Big Bang ...

The ESA put up a helpful map indicating where some more familiar objects are. For example, Orion is almost all the way to the right, and the big puffy pink circle halfway to the left is the star-forming region in Cygnus, the Swan.

If you want to explore this image more, I suggest heading over to Chromoscope, an interactive map that lets you switch between different wavelengths of light, from radio up to gamma rays. It’s a nifty tool to show you how the sky changes when you observe it in different light.

[bystander]

Planck’s new view of the cosmic theatre
ESA Space Science | 2011 Jan 11

Click to view full size image

The first scientific results from ESA’s Planck mission were released at a press briefing today in Paris. The findings focus on the coldest objects in the Universe, from within our Galaxy to the distant reaches of space.

If William Shakespeare were an astronomer living today, he might write that “All the Universe is a stage, and all the galaxies merely players.” Planck is bringing us new views of both the stage and players, revealing the drama of the evolution of our Universe.

Following the publication by ESA of the first full-sky Planck image in July last year, today sees the release of the first scientific results from the mission.

These results are being presented by the Planck Collaboration at a major scientific conference in Paris this week, based on 25 papers submitted to the journal Astronomy & Astrophysics.

The basis of many of these results is the Planck mission’s ‘Early Release Compact Source Catalogue’, the equivalent of a cast list.

Drawn from Planck’s continuing survey of the entire sky at millimetre and submillimetre wavelengths, the catalogue contains thousands of very cold, individual sources which the scientific community is now free to explore.

“This is a great moment for Planck. Until now, everything has been about collecting data and showing off their potential. Now, at last, we can begin the discoveries,” says Jan Tauber, ESA Project Scientist for Planck.

We can think of the Universe as a stage on which the great cosmic drama plays out over three acts.

Visible-light telescopes see little more than the final act: the tapestry of galaxies around us. But by making measurements at wavelengths between the infrared and radio, Planck is able to work back in time and show us the preceding two acts. The results released today contain important new information about the middle act, when the galaxies were being assembled.

Planck has found evidence for an otherwise invisible population of galaxies shrouded in dust billions of years in the past, which formed stars at rates some 10–1000 times higher than we see in our own Galaxy today. Measurements of this population had never been made at these wavelengths before. “This is a first step, we are just learning how to work with these data and extract the most information,” says Jean-Loup Puget, CNRS-Université Paris Sud, Orsay, France.

Eventually, Planck will show us the best views yet of the Universe’s first act: the formation of the first large-scale structures in the Universe, where the galaxies were later born. These structures are traced by the cosmic microwave background radiation, released just 380 000 years after the Big Bang, as the Universe was cooling.

However, in order to see it properly, contaminating emission from a whole host of foreground sources must first be removed. These include the individual objects contained in the Early Release Compact Source Catalogue, as well as various sources of diffuse emission.

Today, an important step towards removing this contamination was also announced. The ‘anomalous microwave emission’ is a diffuse glow most strongly associated with the dense, dusty regions of our Galaxy, but its origin has been a puzzle for decades.

However, data collected across Planck’s unprecedented wide wavelength range confirm the theory that it is coming from dust grains set spinning at several tens of billion times a second by collisions with either fast-moving atoms or packets of ultraviolet light.

This new understanding helps to remove this local microwave ‘fog’ from the Planck data with greater precision, leaving the cosmic microwave background untouched.

“This is a great result made possible by the exceptional quality of the Planck data,” says Clive Dickinson, University of Manchester, UK.

Among the many other results presented today, Planck has shown new details of yet other actors on the cosmic stage: distant clusters of galaxies. These show up in the Planck data as compact silhouettes against the cosmic microwave background.

The Planck Collaboration has identified 189 so far, including 20 previously unknown clusters that are being confirmed by ESA’s XMM-Newton X-ray observatory.

By surveying the whole sky, Planck stands the best chance of finding the most massive examples of these clusters. They are rare and their number is a sensitive probe of the kind of Universe we live in, how fast it is expanding, and how much matter it contains.

“These observations will be used as bricks to build our understanding of the Universe,” says Nabila Aghanim, CNRS-Université Paris Sud, Orsay, France.

“Today’s results are the tip of the scientific iceberg. Planck is exceeding expectations thanks to the dedication of everyone involved in the project,” says David Southwood, ESA Director of Science and Robotic Exploration.

“However, beyond those announced today, this catalogue contains the raw material for many more discoveries. Even then, we haven’t got to the real treasure yet, the cosmic microwave background itself.”

Planck continues to survey the Universe. Its next data release is scheduled for January 2013 and will reveal the cosmic microwave background in unprecedented detail, the opening act of the cosmic drama, a picture of the beginning of everything.

Planck Mission Peels Back Layers of the Universe
NASA JPL-Caltech Planck | 2011 Jan 11

[url=http://www.nasa.gov/mission_pages/planck/planck20110111-i.html]Clumps of Cold Stuff Across the Sky[/url] [i](Credit: ESA/NASA/JPL-Caltech)[/i]

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The Planck mission released a new data catalogue Tuesday from initial maps of the entire sky. The catalogue includes thousands of never-before-seen dusty cocoons where stars are forming, and some of the most massive clusters of galaxies ever observed. Planck is a European Space Agency mission with significant contributions from NASA.

"NASA is pleased to support this important mission, and we have eagerly awaited Planck's first discoveries," said Jon Morse, NASA's Astrophysics Division director at the agency's headquarters in Washington. "We look forward to continued collaboration with ESA and more outstanding science to come."

Planck launched in May 2009 on a mission to detect light from just a few hundred thousand years after the Big Bang, an explosive event at the dawn of the universe approximately 13.7 billion years ago. The spacecraft's state-of-the-art detectors ultimately will survey the whole sky at least four times, measuring the cosmic microwave background, or radiation left over from the Big Bang. The data will help scientists decipher clues about the evolution, fate and fabric of our universe. While these cosmology results won't be ready for another two years or so, early observations of specific objects in our Milky Way galaxy, as well as more distant galaxies, are being released.

"The data we're releasing now are from what lies between us and the cosmic microwave background," said Charles Lawrence, the U.S. project scientist for Planck at NASA's Jet Propulsion Laboratory in Pasadena, Calif. We ultimately will subtract these data out to get at our cosmic microwave background signal. But by themselves, these early observations offer up new information about objects in our universe -- both close and far away, and everything in between."

Planck observes the sky at nine wavelengths of light, ranging from infrared to radio waves. Its technology has greatly improved sensitivity and resolution over its predecessor missions, NASA's Cosmic Background Explorer and Wilkinson Microwave Anisotropy Probe.

The result is a windfall of data on known and never-before-seen cosmic objects. Planck has catalogued approximately 10,000 star-forming "cold cores," thousands of which are newly discovered. The cores are dark and dusty nurseries where baby stars are just beginning to take shape. They also are some of the coldest places in the universe. Planck's new catalogue includes some of the coldest cores ever seen, with temperatures as low as seven degrees above absolute zero, or minus 447 degrees Fahrenheit. In order to see the coldest gas and dust in the Milky Way, Planck's detectors were chilled to only 0.1 Kelvin.

The new catalogue also contains some of the most massive clusters of galaxies known, including a handful of newfound ones. The most massive of these holds the equivalent of a million billion suns worth of mass, making it one of the most massive galaxy clusters known.

Galaxies in our universe are bound together into these larger clusters, forming a lumpy network across the cosmos. Scientists study the clusters to learn more about the evolution of galaxies and dark matter and dark energy -- the exotic substances that constitute the majority of our universe.

"Because Planck is observing the whole sky, it is giving us a comprehensive look at how all the smaller structures of the universe are connected to the whole," said Jim Bartlett, a U.S. Planck team member at JPL and the Astroparticule et Cosmologie-Universite Paris Diderot in France.

Planck's new catalogue also includes unique data on the pools of hot gas that permeate roughly 14,000 smaller clusters of galaxies; the best data yet on the cosmic infrared background, which is made up of light from stars evolving in the early universe; and new observations of extremely energetic galaxies spewing radio jets. The catalogue covers about one-and-a-half sky scans.

More information on Planck is online at http://www.nasa.gov/planck and http://www.esa.int/planck .

Planck satellite team uncovers secrets of the Universe
University of British Columbia | 2011 Jan 11

Highlights from the latest research include:

• A new list of the coldest clumps of gas and dust within our own galaxy: Planck’s multi-colour survey allows these objects to be picked out easily. Dense cores of dust and gas were found with temperatures as low as just seven degrees above absolute zero (or -266 degrees Celsius). Now that their locations are known, follow-up studies with other telescopes will help understand how these clouds are turning into stars.
• Strong evidence for the existence of what astronomers call “anomalous” dust: interstellar grains of material that behave in an unexpected way, the anomalous dust emits a different light spectrum from other thermally emitting grains. The most likely explanation is that the spectrum peaks at such short wavelengths because dust particles are spinning billions of times a second.
• Clusters of hundreds of galaxies discovered through their effect on the cosmic “background”: This “SZ effect,” named after Russian astrophysicists Rashid Sunyaev and Yakov Zeldovich, results from the scattering of the background by hot electrons in the clusters. This action is akin to putting a coloured filter onto the microwave sky, altering the spectrum in the direction of the cluster. Planck’s combination of multiple wavelength bands has allowed the detection of about 200 clusters. The Cosmic Infrared Background is a glow at infrared and microwave wavelengths, coming from the total light emitted by dust across all the galaxies in the Universe. Planck allows astronomers to study the evolution of these galaxies, by comparing variations across the sky among different wavelength bands.

Canadian astronomers unveil a new survey of the Universe
Canadian Space Agency | 2011 Jan 11

Planck unveils wonders of the Universe
Science & Technology Facilities Council | 2011 Jan 11

Planck unveils wonders of the Universe
University of Manchester | 2011 Jan 11

[bystander]

First Science from Planck
Discover Blogs | Cosmic Variance | Sean Carroll | 2011 Jan 11

The Planck Surveyor satellite, a European mission to observe the cosmic microwave background (and various things that get in the way), has released its first science results. 25 papers in all!

I haven’t absorbed all the goodness as yet, so I’ll just point you to more interesting resources — e.g. blog posts by Peter Coles or Andrew Jaffe, or this BBC article if you prefer your media more mainstream. Note that these are not, for the most part, results about the cosmic microwave background and all the yummy cosmological goodness one hopes to derive therefrom. There’s a lot about dust in our own galaxy, as well as infrared emission from some of the very earliest galaxies in the universe. (Much of this is relevant, of course, to straightening out possible anomalies in the actual CMB.)

CMB results are expected circa January 2013. That’s when I’ll win my bet with Max Tegmark.

Satellite Spies Stellar Hatcheries
Science NOW | Govert Schilling | 2011 Jan 11

Planck telescope sees Universe's cool stuff
Nature News | Space & Astronomy | Geoff Brumfiel | 2011 Jan 11

[bystander]

Toronto astronomers among those announcing first scientific results of Planck satellite mission
University of Toronto | Kim Luke | 2011 Jan 11

Will shed light on star-forming galaxies; reveals presence of dark gas

University of Toronto astronomers are in Paris today (Jan. 11) as part of an international conference announcing the first scientific results of the Plank space telescope mission.

Launched in May, 2009, the telescope has nearly completed three of its four planned surveys of the entire sky, providing astronomers a glimpse of conditions near the beginning of the universe and providing data that will help answer the big questions: How was the universe formed? How has it evolved to its present form? And what shape will it take in future?

The most sensitive telescope ever designed to study the cosmic microwave background --the remnants of radiation from the Big Bang some 13 billion years ago and the oldest source of light in the universe -- Planck's detectors measure the temperature of this light, searching for regions that are slightly warmer or colder than the average. These small fluctuations in temperature, called anisotropies, provided the seeds for the formation of galaxies that exist today.

The problem is that the radiation left over from the Big Bang is distorted by objects in the foreground, like galaxies, stars, gas and dust. The Planck team has produced a guidebook of 10,000 foreground objects that will become targets for future study, and charted new types of astrophysical structures:

• 189 gigantic clusters of galaxies, including 20 that have never been seen before;
• cold dust clouds where stars are forming, among the coldest ever discovered, and the first all-sky census;
• dark gas, a previously undetected type of molecular gas found clinging to the edges of giant molecular clouds in the Milky Way,
  and which may have an impact on galaxy formation and evolution; and,
• microwave emission from a population of tiny dust particles, or large molecules, that spin up to ten billion times per second.

The Planck survey will help researchers trace the large-scale distribution of star-forming galaxies, as well as provide information about the still-unclear link between dark matter and star-forming galaxies. Some astronomers believe that dark matter may provide the skeleton for galaxies to form and evolve. The Planck catalogue will also shed new light on well known — but poorly understood — objects, like compact clumps of cold dust that string together to form huge filaments in our own galaxy, the Milky Way. These extremely cold objects may hold clues to the history of how stars form.

[bystander]

15,000 New Celestial Objects
Max Planck Gesellschaft | 2011 Jan 13
Max Planck Institute for Astrophysics

Scientists of the "Planck" satellite mission present first results in a conference in Paris

The 15 000 objects in the '[url=http://www.sciops.esa.int/index.php?project=planck&page=Planck_Legacy_Archive]Early Release Compact Source Catalogue[/url]', where galactic objects – mainly compact dust clouds – are shown in green, and extragalactic objects – mainly radio galaxies and galaxies with a large thermal emission from dust – are shown in yellow. The larger yellow blob to the lower right is the Large Magellanic Cloud, a dwarf galaxy orbiting the Milky Way. [i](© ESA / Planck Collaboration)[/i]

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In its first year in operation, the “Planck Surveyor” satellite has achieved impressive results: a catalogue with 15000 celestial objects such as galaxy clusters, quasars, radio galaxies, nearby galaxies and galactic dust clouds, 25 scientific papers, as well as the most precise measurement of the far infrared background to date, which reveals star formation in the early universe. The Max Planck Institute for Astrophysics developed important software components for Planck and is heavily involved in the scientific interpretation of the mission data.

So far, Planck has produced three complete scans of the whole sky, thus fulfilling its primary objective. However, as it continues to function perfectly, the satellite will probably stay in operation until the start of 2012 and continue to provide data. The results gained from the first year of Planck data were first presented on 11 January 2011, where many of these results are based on the “Early Release Compact Source Catalogue” with some 15 000 new celestial objects. The early release of this data enables scientists to arrange for detailed follow-up observations with other telescopes such as the Herschel space telescope with operates at similar wavelengths.

At the same time as the catalogue, 25 scientific papers are published with topics covering many orders of magnitude and objects and ranging from studies of individual objects in the catalogue and analyses of galactic emission to the first cosmological results on galaxy clusters and the light of early galaxies. Highlights of these papers include:

• confirmation of the anomalous microwave radiation emitted by galactic dust and probably due to the fast rotation of small, electrically charged dust particles;
• a map of a dark gaseous component in our galaxy, only visible in microwaves;
• the precise measurement of 189 galaxy clusters and the discovery of 20 new galaxy clusters with the Suyaev-Zeldovich effect, arising from the interaction of the cosmic background radiation with the hot gas (up to 100 million degrees) in the atmosphere of galaxy clusters;
• the first measurement of the theoretically predicted Suyaev-Zeldovich effect also in smaller galaxy clusters, which now makes possible a nearly complete inventory of the previously invisible gas in the universe;
• a detailed measurement of the far infrared emission of all star forming galaxies in the universe. The scientists can now observe the history of galaxy formation, looking back to an epoch when the universe was only 2 billion years old, just one sevenths of its present age.

The results presented at this Planck conference mainly cover the astrophysical by-products of the Planck mission. The data related to Planck’s primary goal, the cosmic microwave background, the resulting conclusions regarding the age, structure and composition of the universe as well as insights into its origins will probably be published in 2013.

Until then, the noise signal from space but also from the instruments has to be understood in more detail. The team at the Max Planck Institute for Astrophysics will contribute to this effort – their software for simulating and processing the data will continue to be in daily use. The software development at the Institute received financial support from the Max Planck Society and Germany's national research centre for aeronautics and space (DLR).

[bystander]

Planck Space Observatory Begins To Reveal Its Secrets
Technology Review | the physics arXiv blog | KFC | 2011 Jan 13

Click to view full size image

The first data from one of the most important space observatories is set to change the way we understand at the Universe

It's a big week for astronomers, who have an exciting new dataset to play with courtesy of the Planck Space Observatory, which is currently surveying the skies while orbiting the L2 Lagrangian Point some 1.5 million kilometres from Earth.

Planck's most important goal is to measure the cosmic microwave background, the echo of the Big Bang, in unprecedented detail. In fact, it's unlikely that any future spacecraft will do better. That's because the quality of the final data depends on how well astronomers can subtract nearer objects from the background rather than on the inherent resolution of Planck's instruments themselves. Whatever picture emerges is likely to be as good as it gets.

But the Planck mission has other goals too. Astronomers want to use it to build up a map of galaxy clusters on huge scales, to spot instances of gravitational lensing of the CMB and to look at the Milky Way, the planets and the Sun.

Planck has been collecting data continuously since 13 August 2009 and has almost completed three surveys of the entire sky.

This week, the Planck Collaboration of over 200 scientists from around the world release a first set of data early. They're doing this so astronomers can train other instruments on any objects of interest.

In particular, they want to give the Herschel infrared space observatory a chance to peak at any goodies Planck uncovers. Herschel was launched with Planck and is also orbiting L2 cooled by liquid helium which is gradually boiling away. Consequently, Herschel has a limited lifespan of only 3 years, which it is already more than half-way through.

The Planck Collaboration has released its data in 23 papers placed on the arXiv this week. It's clear the data is beginning to throw new light on mysteries such as the strange emissions from dust in the Magellanic Clouds and the properties of the interstellar medium in our galaxy.

But it's also clear that we're going to hear a lot more about Planck in the coming years. I've placed links to all the new papers below, in case you want to get a head start.

• arXiv:1101.1721: Planck Early Results: ERCSC Validation and Extreme Radio Sources
  arXiv:1101.2022: Planck Early Results: The Planck mission
  arXiv:1101.2023: Planck Early Results: The thermal performance of Planck
  arXiv:1101.2024: Planck Early Results: The all-sky Early Sunyaev-Zeldovich cluster sample
  arXiv:1101.2025: Planck Early Results: XMM-Newton follow-up for validation of Planck cluster candidates
  arXiv:1101.2026: Planck Early Results: Calibration of the local galaxy cluster Sunyaev-Zeldovich scaling relations
  arXiv:1101.2027: Planck Early Results: Cluster Sunyaev-Zeldovich optical scaling relations
  arXiv:1101.2028: Planck Early Results: The Power Spectrum Of Cosmic Infrared Background Anisotropies
  arXiv:1101.2029: Planck Early Results: All sky temperature and dust optical depth from Planck and IRAS: Constraints on the "dark gas" in our galaxy
  arXiv:1101.2031: Planck Early Results: New Light on Anomalous Microwave Emission from Spinning Dust Grains
  arXiv:1101.2032: Planck Early Results: Properties of the interstellar medium in the Galactic plane
  arXiv:1101.2034: Planck Early Results: The submillimetre properties of a sample of Galactic cold clumps
  arXiv:1101.2035: Planck Early Results: The Galactic Cold Core Population revealed by the first all-sky survey
  arXiv:1101.2036: Planck Early Results: Dust in the diffuse interstellar medium and the Galactic halo
  arXiv:1101.2037: Planck Early Results: Thermal dust in Nearby Molecular Clouds
  arXiv:1101.2038: Planck Early Results: First assessment of the Low Frequency Instrument in-flight performance
  arXiv:1101.2039: Planck Early Results: first assessment of the High Frequency Instrument in-flight performance
  arXiv:1101.2040: Planck Early Results: The Low Frequency Instrument data processing
  arXiv:1101.2041: Planck Early Results: The Early Release Compact Source Catalog
  arXiv:1101.2043: Planck Early Results: Statistical analysis of Sunyaev-Zeldovich scaling relations for X-ray galaxy clusters
  arXiv:1101.2044: Planck Early Results: Statistical properties of extragalactic radio sources in the Planck Early Release Compact Source Catalogue
  arXiv:1101.2045: Planck Early Results: The Planck View of Nearby Galaxies
  arXiv:1101.2046: Planck Early Results: Origin of the submm excess dust emission in the Magellanic Clouds
  arXiv:1101.2047: Planck Early Results: Spectral energy distributions and radio continuum spectra of northern extragalactic radio sources
  arXiv:1101.2048: Planck Early Results: The High Frequency Instrument data processing