Really Rocket Science

Great quote from Sir Arthur in 2001…

The danger of asteroid or comet impact is one of the best reasons for getting into space … I’m very fond
of quoting my friend Larry Niven: “The dinosaurs became extinct because they didn’t have a space program.
And if we become extinct because we don’t have a space program, it’ll serve us right!”

It’s from “Meeting of the Minds: Buzz Aldrin Visits Arthur C. Clarke, Andrew Chaikin, 2001” — one of many great quotes.

Awesome image from the European South Observatory (image credit: ESO/T. Preibisch)…

This broad panorama of the Carina Nebula, a region of massive star formation in the southern skies, was taken in infrared light using the HAWK-I camera on ESO’s Very Large Telescope. Many previously hidden features, scattered across a spectacular celestial landscape of gas, dust and young stars, have emerged.

Sit back a watch this “trailer” about the VLT (Very Large Telescope)…

Get yourself a huge piece to hang on your wall at Big Bang Prints. Good stuff!

Interesting project developing at Cornell University, via grad student Zac Manchester: KickSat. Want one? It’s only a few hundred bucks and will transmit text message from space. That’s cool.

They need help…

I need your help to put as many Sprites into orbit as possible to demonstrate that they can be safely launched and operated. A minimum fundraising goal of $30,000 (that’s 100 people sponsoring one Sprite each) will allow us to build, test, and integrate all the hardware for KickSat and the Sprites.

As soon as funding is in place, we’ll apply for a free launch through several programs, such as NASA’s ELaNa CubeSat program. While we are not guaranteed a free launch, there are many such opportunities each year and I believe this project has enough technical appeal and value to NASA to compete with anything out there.

If at least 400 spacecraft-adventurers sponsor Sprites, we’ll be able to use the additional funding to purchase a commercial launch, which will help ensure us a ride into space and allow us to get there sooner than we could relying on a free launch – by early 2013 if all goes well.

If at least 1000 space pioneers join us by sponsoring Sprites, we’ll be able to dramatically improve and shrink our design by getting custom microchips made. If we can do that, then costs could be driven down so that every school or even every school child could one day have their own spacecraft to explore the solar system.

Yeah, it’s pretty small (3.8 cm) and was promoted by Radio Shack not too long ago.

Last week, while many were awaiting news of fresh electro-gadgets from the CES in Las Vegas, The American Astronomical Society held its 219th meeting in Austin.

At the meeting, research was presented on a vast, one-billion-light-year-wide map showing lots of dark matter…

Astronomers have created a vast cosmic map revealing an intricate web of dark matter and galaxies spanning a distance of one billion light-years.

This unprecedented task was achieved not by observing dark matter directly, but by observing its gravitational effects on ancient light traveling from galaxies that existed when the Universe was half the age it is now.

Constructed by astronomers from the University of British Columbia and University of Edinburgh, this is the largest dark matter map ever built and took five years to complete.

The research was presented at the American Astronomical Society meeting in Austin, Texas, on Monday.

Dark matter pervades the entire observable universe, accounting for 83 percent of the mass of the cosmos. But as it does not scatter or radiate light (or any kind of electromagnetic radiation for that matter), we cannot see it. Naturally, this poses an interesting problem for astronomers hoping to map the stuff.

However, astronomers can indirectly observe dark matter as its mass exerts a gravitational force on the space-time surrounding it. As light travels from distant galaxies, it will be bent around gravitational distortions in space-time — much like the paths of marbles rolling across a bent sheet of plastic — being caused by the dense regions of dark matter.

With this in mind, the international team of astronomers analyzed light from 10 million galaxies in four different regions of the sky — all of which are around 6 billion light-years from Earth.

And the CES? It wasn’t much fun, according to Pogue…

C.E.S. really is primarily a deafening showcase for tablets, thin TV screens, superthin laptops and Android phones.

Check it out: the universe is 96% dark matter.

Located 20.5 light years away (123 trillion miles), Gliese 581g has a 100% chance of sustaining life. The planet is located in the “Goldilocks” zone, which is considered habitable. If you used a rocket traveling at 1/10 the speed of light (19,000 MPH), it would take 200 years to get there — who has time for that, Dave?

It was announced in September:

A team of planet hunters from the University of California (UC) Santa Cruz, and the Carnegie Institution of Washington has announced the discovery of a planet with three times the mass of Earth orbiting a nearby star at a distance that places it squarely in the middle of the star’s “habitable zone.”

This discovery was the result of more than a decade of observations using the W. M. Keck Observatory in Hawaii, one of the world’s largest optical telescopes. The research, sponsored by NASA and the National Science Foundation, placed the planet in an area where liquid water could exist on the planet’s surface. If confirmed, this would be the most Earth-like exoplanet yet discovered and the first strong case for a potentially habitable one.

To astronomers, a “potentially habitable” planet is one that could sustain life, not necessarily one where humans would thrive. Habitability depends on many factors, but having liquid water and an atmosphere are among the most important.

The new findings are based on 11 years of observations of the nearby red dwarf star Gliese 581 using the HIRES spectrometer on the Keck I Telescope. The spectrometer allows precise measurements of a star’s radial velocity (its motion along the line of sight from Earth), which can reveal the presence of planets. The gravitational tug of an orbiting planet causes periodic changes in the radial velocity of the host star. Multiple planets induce complex wobbles in the star’s motion, and astronomers use sophisticated analyses to detect planets and determine their orbits and masses.

Washington State’s Dirk Schulze-Makuch has a group of scientists working on it.

Time Lapse From Space – Literally. The Journey Home. from Fragile Oasis on Vimeo.

Great video by American astronaut — and SUNY Oneonta graduate — Ron Garan…

The video shows his first attempt at time-lapse photography, suggested by his photography instructor Katrina Willoughby. He set up a Nikon D3S camera in the Cupola windowed observatory to take about 500 pictures at 3-second intervals. The project continued using D3S and D2XS cameras.

All the sequences that appear in the video were shot by either Garan or Fossum. It shows the space station’s orbits around the Earth, though the photography seems to speed up the motion.

The breath-taking sights seen on the video include the world from central Africa to Russia, Europe to the Middle East and footage of the United States. It also includes hurricanes Katia and Irene and several lightning storms.

It is set to the music of Peter Gabriel, featuring his songs “Downside Up” and “Down To Earth.”

Stephen Hawking was wrong. He bet Kip Thorne at CalTech that Cygnus X-1 did not contain a black hole. Now we know for sure, with scientists having done a complete description.

Here’s how…

Though Cygnus X-1 has been studied intensely since its discovery, previous attempts to measure its mass and spin suffered from lack of a precise measurement of its distance from Earth. Reid led a team that used the National Science Foundation’s Very Long Baseline Array (VLBA), a continent-wide radio-telescope system, to make a direct trigonometric measurement of the distance. Their VLBA observations provided a distance of 6070 light-years, while previous estimates had ranged from 5800-7800 light-years.

Armed with the new, precise distance measurement, scientists using the Chandra X-Ray Observatory, the Rossi X-Ray Timing Explorer, the Advanced Satellite for Cosmology and Astrophysics, and visible-light observations made over more than two decades, calculated that the black hole in Cygnus X-1 is nearly 15 times more massive than our Sun and is spinning more than 800 times per second.

“This new information gives us strong clues about how the black hole was born, what it weighed and how fast it was spinning,” Reid said. “Getting a good measurement of the distance was crucial,” Reid added.

“We now know that Cygnus X-1 is one of the most massive stellar black holes in the Milky Way,” said Jerry Orosz, of San Diego State University. “It’s spinning as fast as any black hole we’ve ever seen,” he added.

In addition to measuring the distance, the VLBA observations, made during 2009 and 2010, also measured Cygnus X-1’s movement through our Galaxy. That movement, the scientists, said, is too slow for the black hole to have been produced by a supernova explosion. Such an explosion would have given the object a “kick” to a much higher speed.

That top image would make a really good, big print.

A 400-meter wide Near-Earth asteroid will be cutting it close tomorrow. Will you be able to see it? Yes, but it won’t be easy.

Astro Guyz explains…

Closest approach to Earth occurs at 11:29 UTC/06:29 EST at about 202,000 miles distant, placing it high to the south west for observers on the US Eastern Seaboard. (Don’t forget to “fall back” to Standard time on Sunday, November 6^th; you wouldn’t want to miss seeing the asteroid because of  an anachronistic convention, but I digress..)  At its closest approach, 2005 YU₅₅ will glide along at one degree every 7 minutes, easily noticeable after a few minutes of observation at low power. I plan to target selected areas with my GOTO mount, sketch the field, then watch for changes. I may also take some wide-field piggyback stills with the DSLR, but mostly, this one will just be fun to watch. The asteroid will pass through the constellations Aquila, Delphinus, and Pegasus as it heads westward. Interestingly, 2005 YU₅₅ passes within a degree of Altair centered on 6:07:30PM EST only 27 minutes after local sunset, and also makes a very close pass of the star Epsilon Delphini during closest approach. These both make good visual “anchors” to aim your scope at during the appointed time and watch. Keep in mind, the charts provided are rough and “Tampa Bay-centric…” on an approach as close as this one, two factors muddle the precise prediction coordinates of the asteroid; one is the fact the gravitational field of the Earth will change the orbit of 2005 YU55 slightly, and two is that the position will change due to the position of the observer on the Earth and the effect of parallactic shift. Many prediction programs assume the Earthly vantage as a mere point in space, fine for positioning deep sky objects but not so hot for ones passing near the planet. A good place to get updated coordinates is JPL Horizons website which lets you generate an accurate ephemeris for your exact longitude latitude and elevation.

I like pulsars and I love how our friends at NASA GSFC explain it — with animation.

An international team of scientists using NASA’s Fermi Gamma-ray Space Telescope has discovered a surprisingly powerful millisecond pulsar that challenges existing theories about how these objects form.

At the same time, another team has located nine new gamma-ray pulsars in Fermi data, using improved analytical techniques.

A pulsar is a type of neutron star that emits electromagnetic energy at periodic intervals. A neutron star is the closest thing to a black hole that astronomers can observe directly, crushing half a million times more mass than Earth into a sphere no larger than a city. This matter is so compressed that even a teaspoonful weighs as much as Mount Everest.

“With this new batch of pulsars, Fermi now has detected more than 100, which is an exciting milestone when you consider that, before Fermi’s launch in 2008, only seven of them were known to emit gamma rays,” said Pablo Saz Parkinson, an astrophysicist at the Santa Cruz Institute for Particle Physics at the University of California Santa Cruz, and a co-author on two papers detailing the findings.

One group of pulsars combines incredible density with extreme rotation. The fastest of these so-called millisecond pulsars whirls at 43,000 revolutions per minute.

Millisecond pulsars are thought to achieve such speeds because they are gravitationally bound in binary systems with normal stars. During part of their stellar lives, gas flows from the normal star to the pulsar. Over time, the impact of this falling gas gradually spins up the pulsar’s rotation.

The strong magnetic fields and rapid rotation of pulsars cause them to emit powerful beams of energy, from radio waves to gamma rays. Because the star is transferring rotational energy to the pulsar, the pulsar’s spin slows after this transfer is completed.

Typically, millisecond pulsars are around a billion years old. However, in the Nov. 3 issue of Science, the Fermi team reveals a bright, energetic millisecond pulsar only 25 million years old.

The object, named PSR J1823−3021A, lies within NGC 6624, a spherical collection of ancient stars called a globular cluster, one of about 160 similar objects that orbit our galaxy. The cluster is about 10 billion years old and lies about 27,000 light-years away toward the constellation Sagittarius.

Fermi’s Large Area Telescope (LAT) showed that eleven globular clusters emit gamma rays, the cumulative emission of dozens of millisecond pulsars too faint for even Fermi to detect individually. But that’s not the case for NGC 6624.

“It’s amazing that all of the gamma rays we see from this cluster are coming from a single object. It must have formed recently based on how rapidly it’s emitting energy. It’s a bit like finding a screaming baby in a quiet retirement home,” said Paulo Freire, the study’s lead author, at the Max Planck Institute for Radio Astronomy in Bonn, Germany.

J1823−3021A was previously identified as a pulsar by its radio emission, yet of the nine new pulsars, none are millisecond pulsars, and only one was later found to emit radio waves.

Despite its sensitivity, Fermi’s LAT may detect only one gamma ray for every 100,000 rotations of some of these faint pulsars. Yet new analysis techniques applied to the precise position and arrival time of photons collected by the LAT since 2008 were able to identify them.

“We adapted methods originally devised for studying gravitational waves to the problem of finding gamma-ray pulsars, and we were quickly rewarded,” said Bruce Allen, director of the Max Planck Institute for Gravitational Physics in Hannover, Germany. Allen co-authored a paper on the discoveries that was published online today in The Astrophysical Journal.