Guillaume Blanchard / ESO

Comet Lovejoy streaks through the pre-dawn skies above the European Southern Observatory's Paranal Observatory in Chile on Dec. 22.

If anyone questioned whether Comet Lovejoy would become the star of the season — and a lot of people did — the pictures of the past few days have removed any doubt. In the Southern Hemisphere, the death-defying comet is truly this year's "Star of Wonder."

Not only do we have an amazing video of the long-tailed iceball rising from the horizon, as seen from the International Space Station, we also have the stunning pictures and video released today by the European Southern Observatory. Skywatchers at the ESO's Paranal Observatory in Chile captured the comet against the glittering backdrop of the Milky Way.

"For me, this comet is a Christmas present to the people who will stay at Paranal over Christmas," said Guillaume Blanchard, who snapped a picture of dawn at Paranal with the Milky Way and Lovejoy dominating the sky.

Gabriel Brammer put together a time-lapse sequence of the comet rising just before the sun. For devotees of the night sky, it's the latest must-see video. The clip also features the pencil-thin laser beam that Paranal's Very Large Telescope uses as a guide star for its astronomical observations. Expand the video to full screen to increase the awesomeness.

"With this spectacular sequence of the 2011 Christmas Comet Lovejoy, ESO would like to wish everyone a Merry Christmas and a Happy New Year," the observatory's staff says in today's image advisory.

Amen to that!

More about Comet Lovejoy:

• 'Amazing' view of comet from space
• Lovely Lovejoy! Comet shot at sunrise
• Sun rips comet's tail during close encounter
• Still more pictures from IceinSpace.com.au

M. Kornmesser / ESO

This artist's impression shows galaxies at a time less than a billion years after the big bang, when the Universe was still partially filled with hydrogen fog that absorbed ultraviolet light. New observations with the European Southern Observatory's Very Large Telescope are probing this phase of the early universe by studying the light from some of the most distant galaxies ever detected.

Two studies shed additional light on a murky question: How did the cosmic fog that enveloped the universe in its early days dissipate?

In one study, researchers suggest that whatever happened, happened quickly ... and they say it probably had to do with the hot blast of the first generation of stars. Another suggests how the fog-blasting mechanism worked ... and why it might be tricky to see the effect.

First, about that cosmic fog: Cosmologists have worked out a model for the development of the early cosmos that's a good match for their observations, and the model indicates that for the first few hundred thousand years of its existence, the universe consisted of a hot, murky stew of subatomic particles.

About 400,000 years after the big bang, things had cooled down enough for electrons and protons to come together and form a fog of neutral hydrogen gas. This marked a period that astronomers call the "Dark Ages." Eventually, gravity did its magic, and clouds of hydrogen coalesced to create the first stars and galaxies. The remaining hydrogen became electrically charged — "reionized," in geek-speak — and was cleared away.

Today, astronomers can see only as far back as the period of reionization, even if they're using the most powerful telescopes in the world. The best they can do is observe what was happening to galaxies while the reionization was taking place. And that's exactly what astronomers did during a three-year survey that's described in a research paper to be published in the Astrophysical Journal.

Timeline of the early universe
"Archaeologists can reconstruct a timeline of the past from the artifacts they find in different layers of soil. Astronomers can go one better: We can look directly into the remote past and observe the faint light from different galaxies in cosmic evolution," the project's leader, Adriano Fontana of INAF Rome Astronomical Observatory, said today in a news release from the European Southern Observatory. "The differences between the galaxies tell us about the changing conditions in the universe over this important period, and how quickly these changes were occurring."

The team conducted their survey using the ESO's Very Large Telescope in Chile. Astronomers identified five extremely faraway galaxies, based on their redshift, and placed them in a timeline that started at 780 million years after the big bang (which is thought to have occurred 13.7 billion years ago) and ended about a billion years after the big bang. They also measured how much of the galaxies' ultraviolet light was absorbed by the hydrogen fog surrounding the galaxies.

The paper's lead author, Laura Pentericci of INAF Rome Astronomical Observatory, said there was a "dramatic difference" in the amount of light blocked by the oldest vs. the youngest galaxies in the sample.

"When the universe was only 780 million years old, this neutral hydrogen was quite abundant, filling from 10 to 50 percent of the universe's volume," she said in the news release. "But only 200 million years later, the amount of neutral hydrogen had dropped to a very low level, similar to what we see today. It seems that reionization must have happened quicker than astronomers previously thought."

The findings also favor a particular hypothesis for the mechanism behind the reionization. Some theorists say the fog was cleared by radiation blazing forth from the first generation of stars, while others point to the intense radiation given off as matter falls toward black holes.

"The detailed analysis of the faint light from two of the most distant galaxies we found suggsts that the very first generation of stars may have contributed to the energy output observed," said another member of the research team, Eros Vanzella of the INAF Trieste Observatory. "These would have been very young and massive stars, about 5,000 times younger and 100 times more massive than the sun, and they may have been able to dissolve the primordial fog and make it transparent."

Confirming or disproving that hypothesis would require further observations, either from space telescopes or from better ground-based instruments such as the ESO's planned European Extremely Large Telescope.

Jordan Zastrow / Univ. of Mich.

In this three-color image of the dwarf starburst galaxy NGC 5253, green corresponds to starlight. The yellow shows the gas that is being lit up by the starburst at the galaxy's core. The red shows where ultraviolet light from massive stars is evaporating gas, exposing the central starburst along a narrow cone.

Building the case for blazing stars
Another study, published in Astrophysical Journal Letters, provides further support for the blazing-star hypothesis. Astronomers observed a dwarf starburst galaxy known as NGC 5253, about 11 million light-years away in the constellation Centaurus, using the Magellan Telescopes at Las Campanas Observatory in Chile.

NGC 5253 is nowhere near as old as the galaxies that the Italian researchers surveyed, but it does provide a clearer, closer-up view of the phenomenon that might have been at work during the reionization period. "This galaxy is nearby, but we're trying to use it to better understand what was going on in the early universe," the study's lead author, Jordan Zastrow of the University of Michigan, told me.

When Zastrow and her colleagues used special filters to analyze the light from the galaxy, they determined that extreme ultraviolet radiation was blasting out of the galaxy's center and causing hydrogen gas in the interstellar medium to dissipate. "We are not directly seeing the ultraviolet light," Zastrow emphasized in a news release. "We are seeing its signature in the gas around the galaxy."

The signature of the blast shows up in the team's color-coded picture of NGC 5253 as a reddish-yellow tail snaking out toward the lower left corner of the frame. "It appears to be happening over a very narrow region, a very narrow cone," Zastrow said.

The gas within such a galaxy would normally absorb the ultraviolet radiation, but the researchers suggest that superwinds from the galaxy's massive stars helped clear a passageway through the galactic gas, letting more of the light break through.

Starburst galaxies are rarely found in the nearby universe, but they're thought to have been very common in the early universe. NGC 5253 just might be showing astronomers a rerun of the gas-clearing process that marked the age of ionization. But the galaxy is also showing astronomers why it's been hard to see similar processes at work in other galaxies.

"The opening that is letting the UV light out is very small, which makes this light challenging to detect," Zastrow said. "We can think of it as a lighthouse. If the lamp is pointed toward you, you can see the light. If it's pointed away from you, you can't see it. We believe the orientation of the galaxy is important as to whether we can detect escaping UV radiation."

Astronomers might want to take this narrow-beam effect into account as they build their scenarios for how the cosmic fog cleared, Zastrow told me. "Particularly because this issue is so interesting, and so important for our cosmic history, the important thing is to better understand what is actually possible in terms of learning how it could have happened," she said.

More about cosmic frontiers:

• Scientists pinpoint the farthest galaxy
• Hubble spots farthest galaxy ... again
• Galactic births came early
• Scientists learn how galaxies grew up

In addition to Pentericci, Fontana and Vanzella, authors of "Spectroscopic Confirmation of Z~7 LBGs: Probing the Earliest Galaxies and the Epoch of Reionization" include M. Castellaon, A. Grazian, M. Dijkstra, K. Boutsia, S. Cristiani, M. Dickinson, E. Giallongo, M. Giavalisco, R. Maiolino, A. Moorwood and P. Santini.

In addition to Zastrow, authors of "An Ionization Cone in the Dwarf Starburst Galaxy NGC 5253" include M.S. Oey, Sylvain Veilleux, Michael McDonald and Crystal L. Martin.

Connect with the Cosmic Log community by "liking" the log's Facebook page, following @b0yle on Twitter or adding me to your Google+ circle. You can also check out "The Case for Pluto," my book about the controversial dwarf planet and the search for other worlds.

ESO / Igor Chekalin

This image of the Orion Nebula was captured using the Wide Field Imager camera on the MPG/ESO 2.2-meter telescope at the La Silla Observatory in Chile. This image is a composite of several exposures taken through five different filters. The exposure times were about 52 minutes through each filter.

The Orion Nebula is one of the best-known star-forming regions in our celestial neighborhood, but astronomers can still find some "hidden treasures" if they just look at the nebula in a different light.

Case in point: this ethereal picture of the Orion Nebula, featured today by the European Southern Observatory in Chile. The image is based on data from the MPG/ESO 2.2-meter telescope at the La Silla Observatory in Chile, and submitted by Russia's Igor Chekalin for the ESO's Hidden Treasures astrophotography competition. This particular image took seventh place. Another one of Chekalin's entries, showing the M78 reflection nebula in Orion, won first prize (and earned Chekalin a trip to Chile).

The Orion Nebula, also known as M42, is a huge complex of gas and dust where massive stars are constantly being squeezed into existence. It's about 1,350 light-years away, which is pretty close by astronomical standards. You've probably already figured out that the nebula is in the constellation Orion, which is at center stage in the night sky at this time of year.

The hidden treasures that Chekalin found were data sets from roughly 52-minute exposures taken in five different wavelengths. The rays of light that passed through a red filter and through a filter sensitive to glowing hydrogen gas are represented as red in this image. Light in the yellow-green part of the spectrum is shown here as green. The blue-filter image is reproduced as blue, and ultraviolet shows up as purple. The result is a beautiful picture that sheds new light on the nebula's gauzy structure.

For additional perspectives, check out this ESO vidcast from last year, which compares infrared and visible-light imagery of the Orion Nebula:

The infrared-vs.-visible view is a major focus for NASA researchers using the brand-new Stratospheric Observatory for Infrared Astronomy, or SOFIA. During last week's winter meeting of the American Astronomical Society in Seattle, the researchers in charge of SOFIA's airborne telescope showed off an infrared mosaic image of the Orion Nebula that was captured during their "Short Science 1" observing program in December.

Infrared-sensitive telescopes are particularly good at tracing the structures within dusty star-forming regions. Here's a comparison of the Hubble Space Telescope's visible-light view (left), ESO's near-infrared view (middle) and SOFIA's mid-infrared view (right):

NASA

These images show the Orion Nebula as seen by the Hubble Space Telescope in visible light (left), the European Southern Observatory in near-infrared wavelengths (middle) and the SOFIA airborne observatory in mid-infrared wavelengths (right). Credits for the visible-light image: NASA/ESA/HST/AURA/STScI/O'Dell & Wong. Near-infrared image: ESO/McCaughrean et al. Mid-infrared image: NASA/DLR/SOFIA/USRA/DSI/FORCAST Team.

The dense cloud of interstellar dust at upper left is completely opaque in visible light, partially transparent in the near-infrared and glowing with heat in the mid-infrared. Dust-shrouded stars can easily be seen shining at upper right in the mid-infrared, but they're less apparent in the near-infrared and completely hidden in visible light. In contrast, the hot stars of the Trapezium Cluster sparkle in visible light and near-infrared, but are barely visible in SOFIA's mid-infrared view.

For astronomers, this isn't just a game of hide-and-seek. Comparing different views, in different wavelengths, is how scientists figure out what's going on deep within distant nebulas and galaxies. The scientific insights gained through such comparisons are the true "hidden treasures" of the cosmos.

More wonders in multiple wavelengths:

• Telescopes do a triple take
• Hubble's new superpowers
• Scientists team up on telescopes
• 10 Hubble targets you can find too

Connect with the Cosmic Log community by hitting the "like" button on the Cosmic Log Facebook page or following msnbc.com's science editor, Alan Boyle, on Twitter (@b0yle). Boyle has also written a book about Pluto as well as the past and present search for planets. To learn more, click your way to the website for "The Case for Pluto."