Most Distant Galaxy Observed by Hubble and Spitzer Space Telescopes

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The newly discovered galaxy, named MACS0647-JD, is very young and only a tiny fraction of the size of our Milky Way.

NASA's Great Observatories Find Candidate for Most Distant Galaxy

WASHINGTON -- By combining the power of NASA's Hubble and Spitzer space telescopes and one of nature's own natural "zoom lenses" in space, astronomers have set a new record for finding the most distant galaxy seen in the universe.

The farthest galaxy appears as a diminutive blob that is only a tiny fraction of the size of our Milky Way galaxy. But it offers a peek back into a time when the universe was 3 percent of its present age of 13.7 billion years. The newly discovered galaxy, named MACS0647-JD, was observed 420 million years after the Big Bang, the theorized beginning of the universe. Its light has traveled 13.3 billion years to reach Earth.

This find is the latest discovery from a program that uses natural zoom lenses to reveal distant galaxies in the early universe. The Cluster Lensing And Supernova Survey with Hubble (CLASH), an international group led by Marc Postman of the Space Telescope Science Institute in Baltimore, Md., is using massive galaxy clusters as cosmic telescopes to magnify distant galaxies behind them. This effect is called gravitational lensing.

Along the way, 8 billion years into its journey, light from MACS0647-JD took a detour along multiple paths around the massive galaxy cluster MACS J0647+7015. Without the cluster's magnification powers, astronomers would not have seen this remote galaxy. Because of gravitational lensing, the CLASH research team was able to observe three magnified images of MACS0647-JD with the Hubble telescope. The cluster's gravity boosted the light from the faraway galaxy, making the images appear about eight, seven, and two times brighter than they otherwise would that enabled astronomers to detect the galaxy more efficiently and with greater confidence.

"This cluster does what no manmade telescope can do," said Postman. "Without the magnification, it would require a Herculean effort to observe this galaxy."

MACS0647-JD is so small it may be in the first steps of forming a larger galaxy. An analysis shows the galaxy is less than 600 light-years wide. Based on observations of somewhat closer galaxies, astronomers estimate that a typical galaxy of a similar age should be about 2,000 light-years wide. For comparison, the Large Magellanic Cloud, a dwarf galaxy companion to the Milky Way, is 14,000 light-years wide. Our Milky Way is 150,000 light-years across.

"This object may be one of many building blocks of a galaxy," said the study's lead author, Dan Coe of the Space Telescope Science Institute. "Over the next 13 billion years, it may have dozens, hundreds, or even thousands of merging events with other galaxies and galaxy fragments."

Read More: NASA - NASA's Great Observatories Find Candidate for Most Distant Galaxy

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The Ultimate Map: How Big Is The Universe?

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Universe Time Line

Our Universe consists of galaxies and galaxy clusters expanding at an accelerating rate in all directions connected by a cosmic web of gravity. Is there a boundary to the Universe and therefore to an ultimate map of the Universe? Is the Universe infinite in all directions?

Would a map of the Universe be the ultimate map created by humanity? Time will tell, but Anthony Aguirre has an even bigger idea. What if there are other Universes, even an infinity of Universes? Could these Universes ultimately be mapped in relation to our Universe and others? That would truly be the ultimate, and never-ending, map!

How Big Is The Universe? (BBC)

It is one of the most baffling questions that scientists can ask: how big is the Universe that we live in?

Horizon follows the cosmologists who are creating the most ambitious map in history - a map of everything in existence....

See more about the video here.



Temperature Map of the Measurable Universe: WMAP Full Sky 7 Years


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Hubble eXtreme Deep Field Team: Observing the Evolving Universe

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Hubble eXtreme Deep Field: a new, improved portrait of mankind's deepest-ever view of the Universe

Original Announcement => Farthest View Ever of the Universe: Hubble eXtreme Deep Field

Hubble Space Telescope: Deepest View Ever of the Universe

This is an extraordinary accomplishment and webinar. The public was invited to participate in a "Meet the Hubble eXtreme Deep Field Observing Team" webinar, where three key astronomers of the XDF observing team described how they assembled the landmark image and explained what it tells us about the evolving universe. The webinar begins at 4:00 in video below.

Ray Villard (STScI) introduced and moderated the panel. The team present were Garth Illingworth, Dan McGee, and Pascal Oesch, all from University of California Santa Cruz. Each presented background and procedures on the eXtreme Deep Field image. Some notable concepts, facts, and quotes are below the video.



Hubble eXtreme Deep Field: Some Notable Concepts, Facts, Quotes

Ultimately the search is for the first galaxies. XDF is key to understanding the origins of galaxies, the search for the first galaxies, when and how did galaxies form and grow, how the Milky Way and Andromeda formed.

Hubble is a time machine: XDF sees galaxies forming 13.2 billion years ago, 450 million years after the Big Bang, and sees back in time through 96% of the life of the Universe.

Galaxies earlier than 800 million years after the Big Bang can only be seen in infrared light. XDF reveals these galaxies unseen in deepest visible-light Hubble Utra Deep Field images.

Hubble is at its limit of detection, for finding any earlier galaxies (400 million years after the Big Bang). The James Webb Space Telescope (JWST) will discover the first galaxies and probably the first stars. The gain in efficiency and resolution will be a factor of 100 with the JWST and will be "astonishingly powerful". The project is working towards a 2018 launch date.

The Universe is basically the same in any direction, is symmetric. No asymmetries have been detected.

XDF is full of galaxies and there might be even more fainter galaxies beyond the image that cannot be currently seen. There are more galaxies, and fainter galaxies, in the image than expected beforehand. The Universe is full of tiny, little galaxies in the early times that are building up.

The numbers of galaxies, in redshift 12 to 15, is estimated to decrease. The number of galaxies probably increased around redshift 10. Beyond the redshift is the cosmic glow, the cosmic microwave background, from the Big Bang.

Very small gravitational lensing effect in XDF. Galaxy clusters and very large galaxies were avoided which cause this effect. There is tiny "weak lensing" effect in image.

The age of the galaxy images, particularly using powerful microwave telescopes, has been determined independently. Beyond the scope of the XDF to determine.

XDF is not designed to search for or detect dark energy or dark matter. Supernova searches originally detected dark energy. Galaxy cluster and weak lensing large-scale observations originally detected dark matter.

Deep in the XDF image, the early galaxies are smaller with more intense light and much closer together. The Universe was a tenth (1/10) if its size now. Presumably these galaxies would build up to larger current galaxies such as the Milky Way and Andromeda. The early galaxies are the seeds from which current galaxies evolved. These early galaxies grew, collided, merged in a very dynamic and dramatic process.

The cosmic microwave background was about 400,000 years after the Big Bang, very soon afterwards. The limit of the XDF is 400 million years after the Big Bang. Perhaps first galaxies formed about 150 to 200 million years after the Big Bang. Perhaps the first stars came together about 100 - 150 million years after the Big Bang. Before that were the Dark Ages. The first stars and galaxies ended the Dark Ages.

The earliest galaxies observed are moving away from each other as the Universe expands, increasingly separating from each other. A small fraction of these galaxies were pulled towards each other by gravity, if close enough. The example of the expanding balloon with dots on it...

XDF and Hubble cannot detect individual stars within the early galaxies. The James Webb Space Telescope (JWST) probably will not be able to either and therefore will not be able to detect the individual "first stars". The JWST will probably be able to detect early supernova, however.

XDF is really about galaxies and not about the formation of the Universe itself. A major change in the Universe occurred from about a few hundred million years to 900 million years after the Big Bang. The change from neutral hydrogen to ionized hydrogen in the Universe and within the XDF time frame was most likely caused by the galaxies. XDF will not add significantly to cosmology, however.

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Farthest View Ever of the Universe: Hubble eXtreme Deep Field

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Hubble eXtreme Deep Field: a new, improved portrait of mankind's deepest-ever view of the Universe

Countless planets, stars, galaxies, clusters...

Farthest View Ever of the Universe: Hubble eXtreme Deep Field

SEPTEMBER 25, 2012: Like photographers assembling a portfolio of best shots, astronomers have assembled a new, improved portrait of mankind's deepest-ever view of the universe. Called the eXtreme Deep Field, or XDF, the photo was assembled by combining 10 years of NASA Hubble Space Telescope photographs taken of a patch of sky at the center of the original Hubble Ultra Deep Field. The XDF is a small fraction of the angular diameter of the full Moon. The Hubble Ultra Deep Field is an image of a small area of space in the constellation Fornax, created using Hubble Space Telescope data from 2003 and 2004. By collecting faint light over many hours of observation, it revealed thousands of galaxies, both nearby and very distant, making it the deepest image of the universe ever taken at that time. The new full-color XDF image reaches much fainter galaxies and includes very deep exposures in red light from Hubble's new infrared camera, enabling new studies of the earliest galaxies in the universe. The XDF contains about 5,500 galaxies even within its smaller field of view. The faintest galaxies are one ten-billionth the brightness of what the human eye can see.

Fly Through the Hubble eXtreme Deep Field This video takes you through Hubble's deepest view of the universe, from its location in the sky to the dimmest, most distant galaxies.



Hubble Extreme Deep Field Pushes Back Frontiers of Time and Space This video explains how astronomers meticulously assembled mankind's deepest view of the universe from combining Hubble Space Telescope exposures taken over the past decade. Guest scientists are Dr. Garth Illingworth and Dr. Marc Postman.









The public is invited to participate in a "Meet the Hubble eXtreme Deep Field Observing Team" webinar, where three key astronomers of the XDF observing team will describe how they assembled the landmark image and explain what it tells us about the evolving universe. Participants will be able to send in questions for the panel of experts to discuss. The webinar will be broadcast at 1:00 p.m. EDT on Thursday, September 27, 2012. To participate in the webinar, please visit: http://hubblesite.org/go/xdf/ .

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NASA Spitzer and Hubble Space Telescopes Observe Most Distant Galaxy Ever Seen?

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Newly discovered galaxy known as MACS 1149-JD (Image credit: NASA/ESA/STScI/JHU)

A Glimmer From a Dark Cosmic Era

WASHINGTON (NASA) -- With the combined power of NASA's Spitzer and Hubble space telescopes, as well as a cosmic magnification effect, astronomers have spotted what could be the most distant galaxy ever seen. Light from the primordial galaxy traveled approximately 13.2 billion light-years before reaching NASA's telescopes, shining forth from the so-called cosmic dark ages when the universe was just 3.6 percent of its present age.

Astronomers relied on gravitational lensing to catch sight of the early, distant galaxy. In this phenomenon, predicted by Albert Einstein a century ago, the gravity of foreground objects warps and magnifies the light from background objects.

In the big image at left, the many galaxies of a massive cluster called MACS J1149+2223 dominate the scene. Gravitational lensing by the giant cluster brightened the light from the newfound galaxy, known as MACS 1149-JD, some 15 times, bringing the remote object into view.

At upper right, a partial zoom-in shows MACS 1149-JD in more detail, and a deeper zoom appears to the lower right. In these visible and infrared light images from Hubble, MACS 1149-JD looks like a dim, red speck. The small galaxy's starlight has been stretched into longer wavelengths, or "redshifted," by the expansion of the universe. MACS 1149-JD's stars originally emitted the infrared light seen here at much shorter, higher-energy wavelengths, such as ultraviolet.

The far-off galaxy existed within an important era when the universe transformed from a starless expanse during the dark ages to a recognizable cosmos full of galaxies. The discovery of the faint, small galaxy opens a window onto the deepest, remotest epochs of cosmic history.


Hubble Space Telescope

NASA Telescopes Spy Ultra-Distant Galaxy Amidst Cosmic 'Dark Ages'

WASHINGTON (NASA) -- With the combined power of NASA's Spitzer and Hubble space telescopes, as well as a cosmic magnification effect, astronomers have spotted what could be the most distant galaxy ever seen. Light from the young galaxy captured by the orbiting observatories first shone when our 13.7-billion-year-old universe was just 500 million years old.

The far-off galaxy existed within an important era when the universe began to transit from the so-called cosmic dark ages. During this period, the universe went from a dark, starless expanse to a recognizable cosmos full of galaxies. The discovery of the faint, small galaxy opens a window onto the deepest, remotest epochs of cosmic history.

"This galaxy is the most distant object we have ever observed with high confidence," said Wei Zheng, a principal research scientist in the department of physics and astronomy at Johns Hopkins University in Baltimore and lead author of a new paper appearing in Nature. "Future work involving this galaxy, as well as others like it that we hope to find, will allow us to study the universe's earliest objects and how the dark ages ended."

Light from the primordial galaxy traveled approximately 13.2 billion light-years before reaching NASA's telescopes. In other words, the starlight snagged by Hubble and Spitzer left the galaxy when the universe was just 3.6 percent of its present age. Technically speaking, the galaxy has a redshift, or "z," of 9.6. The term redshift refers to how much an object's light has shifted into longer wavelengths as a result of the expansion of the universe. Astronomers use redshift to describe cosmic distances.

Unlike previous detections of galaxy candidates in this age range, which were only glimpsed in a single color, or waveband, this newfound galaxy has been seen in five different wavebands. As part of the Cluster Lensing And Supernova Survey with Hubble Program, the Hubble Space Telescope registered the newly described, far-flung galaxy in four visible and infrared wavelength bands. Spitzer measured it in a fifth, longer-wavelength infrared band, placing the discovery on firmer ground.

Objects at these extreme distances are mostly beyond the detection sensitivity of today's largest telescopes. To catch sight of these early, distant galaxies, astronomers rely on gravitational lensing. In this phenomenon, predicted by Albert Einstein a century ago, the gravity of foreground objects warps and magnifies the light from background objects. A massive galaxy cluster situated between our galaxy and the newfound galaxy magnified the newfound galaxy's light, brightening the remote object some 15 times and bringing it into view.

Based on the Hubble and Spitzer observations, astronomers think the distant galaxy was less than 200 million years old when it was viewed. It also is small and compact, containing only about 1 percent of the Milky Way's mass. According to leading cosmological theories, the first galaxies indeed should have started out tiny. They then progressively merged, eventually accumulating into the sizable galaxies of the more modern universe.

These first galaxies likely played the dominant role in the epoch of reionization, the event that signaled the demise of the universe's dark ages. This epoch began about 400,000 years after the Big Bang when neutral hydrogen gas formed from cooling particles. The first luminous stars and their host galaxies emerged a few hundred million years later. The energy released by these earliest galaxies is thought to have caused the neutral hydrogen strewn throughout the universe to ionize, or lose an electron, a state that the gas has remained in since that time.

"In essence, during the epoch of reionization, the lights came on in the universe," said paper co-author Leonidas Moustakas, a research scientist at NASA's Jet Propulsion Laboratory, a division of the California Institute of Technology in Pasadena, Calif.

Astronomers plan to study the rise of the first stars and galaxies and the epoch of reionization with the successor to both Hubble and Spitzer, NASA's James Webb Telescope, which is scheduled for launch in 2018. The newly described distant galaxy likely will be a prime target.


Spitzer Space Telescope

For more information about Spitzer, visit: http://www.nasa.gov/spitzer

For more information about Hubble, visit: http://www.nasa.gov/hubble

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Hubble, Swift Detect First-Ever Changes in an Exoplanet Atmosphere

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This artist's rendering illustrates the evaporation of HD 189733b's atmosphere in response to a powerful eruption from its host star. NASA's Hubble Space Telescope detected the escaping gases and NASA's Swift satellite caught the stellar flare.
(Credit: NASA's Goddard Space Flight Center)

Hubble, Swift Detect First-Ever Changes in an Exoplanet Atmosphere

An international team of astronomers using data from NASA's Hubble Space Telescope has made an unparalleled observation, detecting significant changes in the atmosphere of a planet located beyond our solar system. The scientists conclude the atmospheric variations occurred in response to a powerful eruption on the planet's host star, an event observed by NASA's Swift satellite.

"The multiwavelength coverage by Hubble and Swift has given us an unprecedented view of the interaction between a flare on an active star and the atmosphere of a giant planet," said lead researcher Alain Lecavelier des Etangs at the Paris Institute of Astrophysics (IAP), part of the French National Scientific Research Center located at Pierre and Marie Curie University in Paris.

The exoplanet is HD 189733b, a gas giant similar to Jupiter, but about 14 percent larger and more massive. The planet circles its star at a distance of only 3 million miles, or about 30 times closer than Earth's distance from the sun, and completes an orbit every 2.2 days. Its star, named HD 189733A, is about 80 percent the size and mass of our sun.

Exo-Planet Hot Flareup Astronomers classify the planet as a "hot Jupiter." Previous Hubble observations show that the planet's deep atmosphere reaches a temperature of about 1,900 degrees Fahrenheit (1,030 C). HD 189733b periodically passes across, or transits, its parent star, and these events give astronomers an opportunity to probe its atmosphere and environment. In a previous study, a group led by Lecavelier des Etangs used Hubble to show that hydrogen gas was escaping from the planet's upper atmosphere. The finding made HD 189733b only the second-known "evaporating" exoplanet at the time. The system is just 63 light-years away, so close that its star can be seen with binoculars near the famous Dumbbell Nebula. This makes HD 189733b an ideal target for studying the processes that drive atmospheric escape.




The exoplanet HD 189733b lies so near its star that it completes an orbit every 2.2 days. In late 2011, NASA's Hubble Space Telescope found that the planet's upper atmosphere was streaming away at speeds exceeding 300,000 mph. Just before the Hubble observation, NASA's Swift detected the star blasting out a strong X-ray flare, one powerful enough to blow away part of the planet's atmosphere. (Credit: NASA's Goddard Space Flight Center)

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Hubble Space Telescope: Best Images

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Hubble Space Telescope

The Hubble Space Telescope was launched on April 24, 1990. NASA & ESA have selected some of the best images, one for each year in service, in the video below. These include images of Saturn and rings, the colorful Orion Nebula, Herbig Haro 2, Messier 100, Shoemaker-Levy 9 Hits Jupiter, the classic Eagle Nebula, the odd and unusual NGC 6826, the red planet Mars, the amazing Ring Nebula, Keyhole Nebula, NGC 1999, ESO 510-G13, the striking Cone Nebula, the legendary Hubble Ultra Deep Field, the surreal Antennae Galaxies, the vast Orion Nebula, the "diamonds" of Messier 9, NGC 4874, the glowing NGC 2818, the symmetric Bug Nebula, Centaurus A, and the Tarantula Nebula.

Hubble Space Telescope - The Best Images From Over Two Decades In Orbit Hubblecast 54: 22 Years In Images. To celebrate the 22nd anniversary of the NASA/ESA Hubble Space Telescope, this episode of the Hubblecast gives a slideshow of some of the best images from over two decades in orbit.




Eagle Nebula


NGC 6826

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