Space and astronomy news
We’re thinking big. We’re going to consider the biggest things in the Universe. If you could pull way back, and examine regions of space billions of light-years across, what would you see? How is the Universe arranged at the largest scale? And more importantly… why?
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Large Scale Structures in the Universe- Transcript and show notes.
This week’s Carnival of Space is hosted by The Next Big Future.
Click here to read the Carnival of Space #106
And if you’re interested in looking back, here’s an archive to all the past Carnivals of Space. If you’ve got a space-related blog, you should really join the carnival. Just email an entry to [email protected], and the next host will link to it. It will help get awareness out there about your writing, help you meet others in the space community – and community is what blogging is all about. And if you really want to help out, let Fraser know if you can be a host, and he’ll schedule you into the calendar.
Finally, if you run a space-related blog, please post a link to the Carnival of Space. Help us get the word out.
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Mexico is known for its beaches and historical ruins, but did you know that Mexico has some of the most spectacular volcanoes in North America? It has the tallest volcano in North America (the third tallest mountain in North America), and islands formed from shield volcanoes.
Mexico Volcanoes
We have written many articles about volcanoes for Universe Today. Here’s an article about Costa Rica volcanoes, and here’s a full list of famous volcanoes around the world.
Want more resources on the Earth? Here’s a link to NASA’s Human Spaceflight page, and here’s NASA’s Visible Earth.
We have also recorded an episode of Astronomy Cast about Earth, as part of our tour through the Solar System – Episode 51: Earth.
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Jocotitlan is an stratovolcano located about 60 kilometers northwest of Mexico City. It rises to an elevation of 3,900 meters above sea level, but it’s isolated from any other mountains or peaks in the surrounding plains, rising up 1,300 meters above the Toluca basin.
One of its most prominent features is a horseshoe-shaped escarpment visible from the northeast; it formed when the northeast edge of the caldera collapsed. Whenever this event happened, it created an enormous landslide that buried 80 square kilometers of land to the northeast of the volcano.
Jocotitlan formed in the Pleistocene era (11,000 to 1.8 million years ago) primarily out of andesitic-to-dacitic lava flows. After that there was an obsidian dacitic eruptino and then the creation of a lava dome complex. The volcano produced regular lava flows, pumice-fall eruptions and pyroclastic surges. The last known eruption at Jocotitlan happened about 700 years ago, and produced block-and-ash flows and pyroclastic surges.
We have written many article about volcanoes for Universe Today. Here’s an article about other volcanoes in Mexico, and here’s an article about many famous volcanoes.
Want more resources on the Earth? Here’s a link to NASA’s Human Spaceflight page, and here’s NASA’s Visible Earth.
We have also recorded an episode of Astronomy Cast about Earth, as part of our tour through the Solar System – Episode 51: Earth.
While having lunch with colleagues at Los Alamos National Labs in 1950, physicist Enrico Fermi mused about the likelihood of intelligent life existing elsewhere in the Universe. Fermi, one of the most astute scientists of his day, thought the size and age of the Universe means many advanced civilizations should have already colonized the galaxy, just as humans colonized and explored the Earth. But if such galaxy-wide extraterrestrial civilizations exist, he wondered, where are they?
Some believe this problem, called the Fermi Paradox, means advanced extraterrestrial societies are rare or nonexistent. Others suggest they must destroy themselves before they move on to the stars.
But this week, Jacob D. Haqq-Misra and Seth D. Baum at Penn State University proposed another solution to the Fermi Paradox: that extraterrestrial civilizations haven’t colonized the galaxy because the exponential growth of a civilization required to do so is unsustainable.
The researchers call their idea the “Sustainability Solution”. It states: “The absence of ETI (extra-terrestrial intelligence) observation can be explained by the possibility that exponential or other faster growth is not a sustainable development pattern for intelligent civilizations.”
The researchers base their conclusions on a study of civilizations on Earth. Historically, rapid growth of societies means rapid resource depletion and environmental degradation, usually with dire results. They cite the example of Easter Island, where resource depletion likely caused a collapse of the local population. And they conclude that while there are examples of sustainable growth like the !Kung San people of the Kalahari Desert, exponential growth in population and spatial expansion of a society is almost always linked to unsustainable growth and eventual collapse.
This principle has implications for our current global civilization. Since Earth’s resources are finite and it receives solar radiation at a constant rate, human civilization cannot sustain an indefinite, exponential growth. But even if we survive and advance as a civilization, we may have trouble colonizing the galaxy should we ever decide to do so. And if this limitation applies to us, it may apply to other civilizations as well.
But the Sustainability Solution doesn’t mean ET is not out there. Slower-growth extraterrestrial societies might still communicate by radio or other wavelengths, so current SETI programs still make sense. Or ETI may result in chemical bio-markers in planetary atmospheres which may leave spectroscopic signatures detectable with upcoming generations of Earth and space-based planet-hunting telescopes.
The Sustainability Solution also allows that advanced civilizations may indeed colonize the galaxy, then collapse as resources are consumed at an unsustainable rate.
And some civilizations may send small messenger probes to other stars, which suggests a search for extraterrestrial artifacts (SETA) within our own solar system might be just as fruitful as radio-based SETI. Searches might involve radio or visible detection of extraterrestrial probes orbiting the sun. Or artifacts may even be embedded within planets or moons of our solar system, just like the giant black monoliths in Arthur C. Clarke’s 2001: A Space Odyssey.
In any case, the discovery of artifacts from a slow-growth extraterrestrial civilization would be an example “sustainable development” on a galactic scale.
You can read the original article here.
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Barcena is a volcano located on the island of San Benedicto, the third largest island of the Revillagigedo Islands. The whole island is only about 4.8 km by 2.4 km and Barcena takes up a good chunk of the southern end. Barcena rises to an elevation of 332 meters, forming a volcanic crater.
There has only been on eruption from Barcena in recorded history, but it was a big one. On August 1, 1952, Barcena had a severe Vulcanian eruption measuring 3 on the Volcanic Explosivity Index. It released huge pyroclastic flows that rolled over the entire island, covering it in ash and pumice to a depth of 3 meters. Within less than 2 weeks, it had created a new volcanic cone more than 300 meters high. A second series of eruptions started up later in the year, releasing magma that broke out of the cone and flowed into the ocean. By late 1953, the volcano went dormant again.
The eruption wiped out all the plants and wildlife on the island, making the San Benedicto Rock Wren extinct. Within a few years the plants and wildlife made a return, although the island still looks barren.
We have written many article about volcanoes for Universe Today. Here’s an article about Tacana, a tall stratovolcano that straddles the border between Mexico and Guatemala. And here’s an article about Paricutin, a volcano that suddenly appeared in a farmer’s cornfield.
Want more resources on the Earth? Here’s a link to NASA’s Human Spaceflight page, and here’s NASA’s Visible Earth.
We have also recorded an episode of Astronomy Cast about Earth, as part of our tour through the Solar System – Episode 51: Earth.
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Colima is the name of a state in Mexico, as well as a city. But we’re going to be talking about another feature in Mexico, Colima’s Volcano. Colima is the most active volcano in Mexico, having erupted more than 40 separate times since records were first kept in 1576. The volcano stands at an elevation of 4,330 meters.
Geologists believe that Colima has been active for about 5 million years. Back in the Pleistocene era (between 11,000 and 1.8 million years ago), a huge earthquake triggered a landslide on the volcano, releasing 25 cubic kilometers of debris that traveled 120 km, reaching the Pacific Ocean. Major collapse events like this are believed to happen every few thousand years.
In the Colima volcano complex there are actually two different volcanoes. The older, dormant volcano is known as Nevado de Colima, and it stands at an elevation of 4330 meters. The younger, active volcano is known as the Volcan de Colima – Colima Volcano.
Colima has the potential to be a devastating volcano. There are about 300,000 people living within 40 km of the volcano. It has been chosen by scientists as a “Decade volcano”, and has been singled out for careful study to predict if and when a major eruptive event is happening. There have been several evacuations of the region over the last decade, since a large eruption or lava flow could affect an 11-kilometer radius around the volcano. In a 1999 eruption, Colima blasted out material that reached a distance of 5 km. Fortunately, lava flows from the volcano have never reached inhabited areas.
We have written many articles about volcanoes for Universe Today. Here’s an article about Popocatepeti, another volcano in Mexico. And here’s an article about Paricutin, a volcano that appeared in a cornfield in Mexico.
Want more resources on the Earth? Here’s a link to NASA’s Human Spaceflight page, and here’s NASA’s Visible Earth.
We have also recorded an episode of Astronomy Cast about Earth, as part of our tour through the Solar System – Episode 51: Earth.
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Popocatepetl is a famous volcano. It is one of the most active volcanoes in Mexico, and the second tallest mountain in the country with an elevation of 5,426 meters (it’s the third tallest active volcano in the Northern Hemisphere). It’s located about 70 km southeast from Mexico City, so it can be seen on clear days from the city – especially when it’s erupting clouds of ash many km into the air. It has had more than 20 major eruptions since the arrival of the Spanish in 1519.
The name Popocatepetl comes from the Aztec word for smoking mountain. More than 30 million people live within view of the mountain, including Mexico City and the Pueblo, and hundreds of thousands would be at risk during a major eruption. Pyroclastic flows could endanger villages and towns built up on the volcano’s flanks, and although it has been relatively safe in the last century, it has had several plinian eruptions over the last 10,000 years.
The peak of Popocatepetl is clad is glaciers, and has a steep-walled 450-meter-deep crater at the top. From most vantages, the peak of the mountain looks very symmetrical; although, it does have a side peak called Ventorillo to the northwest. Geologists have determined that three previous major cones were destroyed during the Pleistocene era (between 11,000 and 1.8 million years ago).
Most of the eruptions on Popocatepetl have been mild-to-moderate Vulcanian steam and ash emissions, with some larger explosive eruptions in 1519 and 1663. In 1920, there were some explosive eruptions and a small lava plug at the crater at the top of the volcano. There have been some additional ash cloud events in the 1920s through the 1940s, but the volcano has been largely quiet since then.
We have written many articles about volcanoes for Universe Today. Here’s an article about Paricutin, a famous volcano in Mexico that appeared in a farmer’s cornfield. And here’s a list of famous volcanoes around the world.
Want more resources on the Earth? Here’s a link to NASA’s Human Spaceflight page, and here’s NASA’s Visible Earth.
We have also recorded an episode of Astronomy Cast about Earth, as part of our tour through the Solar System – Episode 51: Earth.
Greetings, fellow SkyWatchers! Are you ready for another great weekend of observing? If you’re thinking that it’s going to be boring because there’s Moon, then think again. If you were paying attention, you’d have noticed that Venus and Mars rose together this morning only about five degrees apart. Need more reasons to get out? Try 13 of them as you challenge yourself to see how many craterlets you can resolve in the mighty Clavius. Stars more to your liking? Then have a look at the Theta Virginis system or beautiful red Omega. Celebrate the Strawberry Moon, locate R Hydrae or just be on hand for an occultation event… It’s all part of the weekend scene! Grab your telescopes or binoculars and I’ll see you in the backyard.
Friday, June 5, 2009 – If you were up early this morning, did you see Venus and Mars no more than 30 minutes before dawn? The pair was very low – only about 20 degrees above the horizon -and about 5 degrees apart.
Now, let’s take a look at John Couch Adams, a discoverer of Neptune who was born on this date in 1819. Said he:
‘‘. . .the beginning of this week of investigating, as soon as possible after taking my degree, the irregularities in the motion of Uranus. . .in order to find out whether they may be attributed to the action of an undiscovered planet beyond it.’’
But that’s not all Adams contributed! He was the first to associate the Leonid meteor shower with the orbital path of a comet, and he also observed the Moon.
As we begin observing Selene this evening, let’s have a look at awesome crater Clavius. As a huge mountain-walled plain, Clavius will appear near the terminator tonight in the lunar Southern Hemisphere, rivaled only in sheer size by similarly structured Deslandres and Baily. Rising 1,646 meters above the surface, the interior wall slopes gently downward for a distance of almost 24 kilometers and spans 225 kilometers. Its crater-strewn walls are over 56 kilometers thick! Clavius is punctuated by many pockmarks and craters; the largest on the southeast wall is named Rutherford. Its twin, Porter, lies to the northeast. Long noted as a test of optics, Clavius crater can offer up to 13 such small craters on a steady night at high power. How many can you see?
If you want to continue tests of resolution, why not visit nearby Theta Virginis (RA 13 09 56 Dec -05 32 20)? It might be close to the Moon, but it’s 415 light-years away from Earth! The primary star is a white A-type subgiant, but it’s also a spectroscopic binary comprising two companions that orbit each other about every 14 years. In turn, this pair is orbited by a 9th magnitude F-type star that is a close 7.1’’ away from the primary. Look for the fourth member of the Theta Virginis system, well away at 70’’ but shining at a feeble magnitude 10.4.
Saturday, June 6, 2009 – Today is all about lunar history! We begin with the 1932 birth on this date of David Scott, the seventh person to walk on the Moon and the first to ride the Lunar Rover on the surface during the Apollo 15 mission. Sharing his birth date, but almost 500 years earlier, was the astronomer Regiomontanus (1436). Regiomontanus made observations of a comet, which were accurate enough to associate it with Comet Halley 210 years later, and his interest in the motion of the Moon led him to make the important observation that lunar distances could be used to determine longitude at sea! Let’s head to the Moon. . .
Although at first glance tonight crater Copernicus will try to steal the scene, head further south to capture another Lunar Club Challenge – Bullialdus. Even binoculars can make out this crater with ease near the center of Mare Nubium. If you’re scoping, power up – this one is fun! Very similar to Copernicus, note Bullialdus’ thick, terraced walls and central peak. If you examine the area around it carefully, you can note it is a much newer crater than shallow Lubiniezsky to its north and almost non-existent Kies to the south. On Bullialdus’ southern flank, it’s easy to make out itsA and B craters, as well as the interesting little Koenig to the southwest. Although it will be a bit overlit, if you head to the southeast shore of Mare Humorum, you can spot crater Regiomontanus as well. It’s just south of Purbach.
Now let’s starhop four finger-widths northwest of Beta Virginis for another unusual star – Omega (RA 11 38 27 Dec +08 08 03). Classed as an M-type red giant, this 480 light-year-distant beauty is also an irregular variable that fluxes by about half a magnitude. Although you won’t notice much change in this 5th magnitude star, it has a very pretty red coloration and is worth the time to view.
Sunday, June 7, 2009 – Today we celebrate the birth of Bernard Burke, co-discoverer of radio waves emitted from Jupiter. Listening to Jupiter’s radio signals is a wonderful hobby that can be practiced by anyone with enough room to set up a dipole antenna. If you’d like more information—or want to hear a recording of Jupiter yourself—visit Radio JOVE on the web! Tonight is Full Strawberry Moon, a name used by every Algonquin tribe in North America because the short season for harvesting the tasty red fruit comes each year during the month of June!
Tonight let’s have a look at a tasty red star – R Hydrae (RA 13 29 42 Dec -23 16 52) located a fist-width south of Spica. R Hydrae was the third long-term variable star discovered and was credited to Maraldi in 1704. Although Hevelius observed it 42 years earlier, it wasn’t recognized as variable because its changes happen over more than a year. At maximum, R reaches near 4th magnitude, but drops well below naked-eye perception to magnitude 10. During Maraldi’s and Hevelius’s time, this incredible star took over 500 days to cycle, but it has speeded up to around 390 days in the present century.
Why such a wide range? Scientists aren’t really sure. R Hydrae is a pulsing M-type giant whose evolution may be progressing more rapidly than expected due to changes in structure. What we do know is that it’s around 325 light-years away and approaching us at 10 kilometers per second! To the telescope, R will have a pronounced red coloration, which deepens near minimum. Nearby is 12th magnitude visual companion star Ho 381, which was first measured for angle position and distance in 1891. Since then, no changes in separation have been noted, leading us to believe the pair may be a true binary.
Now watch as the Moon devours a red star! Brilliant Antares will be less than a half degree away from the limb for most observers and will be occulted for some lucky others! Be sure to check the IOTA website for exact times and locations and enjoy!
Until next week? Ask for the Moon, but keep on reach for the stars!
This week’s awesome images are (in order of appearance): Clavius (credit—Wes Higgins), Theta Virginis (credit—Palomar Observatory, courtesy of Caltech), Bullialdus (credit—Wes Higgins), Omega Virginis (credit—Palomar Observatory, courtesy of Caltech), Nearside of the Moon as imaged by Apollo 11 (credit—NASA) and R Hydrae (credit—Palomar Observatory, courtesy of Caltech). We thank you so much!
When it comes to universes, perhaps one is enough after all.
Many theories in physics and cosmology require the existence of alternate, or parallel, universes. But Dr. Lee Smolin of the Perimeter Institute for Theoretical Physics in Waterloo, Canada, explains the flaws of theories that suggest our universe is just one of many, and which also perpetuate the notion that time does not exist. Smolin, author of the bestselling science book ‘The Trouble with Physics’ and a founding member of the Perimeter Institute, explains his views in the June issue of Physics World.
Smolin explains how theories describing a myriad of possible universes, or a “multiverse”, with many dimensions and particles and forces have become more popular in the last few years. However, through his work with the Brazilian philosopher Roberto Mangabeira Unger, Smolin believes that multiverse theories, which imply that time is not a fundamental concept, are “profoundly mistaken”.
Smolin says a timeless multiverse means our laws of physics can’t be determined from experiment. And he explains the unclear connection between fundamental laws, which are unique and applicable universally, and effective laws, which hold based on what we can actually observe.
Smolin suggests new principles that rethink the notion of physical law to apply to a single universe. These principles say there is only one universe; that all that is real is real in a moment, as part of a succession of moments; and that everything real in each moment is a process of change leading to future moments. As he explains, “If there is just one universe, there is no reason for a separation into laws and initial conditions, as we want a law to explain just one history of one universe.”
He hopes these principles will bring a fresh adventure in science.
If we accept there is only one universe and that time is a fundamental property of nature, then this opens up the possibility that the laws of physics evolve with time. As Smolin writes, “The notion of transcending our time-bound experiences in order to discover truths that hold timelessly is an unrealizable fantasy. When science succeeds, we do nothing of the sort; what we physicists really do is discover laws that hold in the universe we experience within time. This, I would claim, should be enough; anything beyond that is more a religious urge for transcendence than science.”
Source: Institute of Physics