Here’s a preview of highlights in the night sky this month:
Bonus: Here is a nice view of the aurora as seen from the Int. Space Station:
Monthly Archives: February 2015
Update on Kepler exoplanet finding mission
Dr. William Borucki, the force behind the Kepler exo-planet finding observatory, gave an update last night on the John Batchelor radio program: John Batchelor Hotel Mars, Wednesday, 2-4-15 – Thespaceshow’s Blog –
David Livingston, who co-hosts the weekly Hotel Mars segment on the John Batchelor show, gave this summary of the show:
John Batchelor and I welcomed Dr. William (Bill) Borucki back to the show to discuss the recently announced discovery of the small five planet system 11.2 billion years old, Kepler-444. This is approximately 2.5 times older than the Earth. We discussed the exoplanet search, rocky planets and their early formation, the surprises contained within the discovery of Kepler-444, and life detection in the habitable zone. As it turns out, the five small planets orbit their sun in 10 days so they are far too hot for life. However, Dr. Borucki did at one point during our discussion estimate the number of planetary candidates that were possible in the habitable zone. One can see Kepler-444 with binoculars so I asked our guest where to look to find it. He also said it was a triple star system! Among the surprises included the discover of dust and metal that early and the discovery that stars formed so very early at all.
NASA lunar orbiter finds crater slopes facing pole contain more hydrogen
The Lunar Reconnaissance Orbiter finds that in craters on the southern hemisphere of the Moon, the slopes facing towards the south have more hydrogen embedded in them than the north facing slopes. The south facing slopes receive somewhat less light than the slopes facing north and so this presumably results in slightly less evaporation. The amount of hydrogen, which to some degree may be in water molecules, is still extremely small and would be very difficult to extract. (There is strong evidence that some craters at the poles, whose floors never see any sunlight at all, have significant amounts of mine-able water ice.)
NASA’s LRO Discovers Lunar Hydrogen More Abundant
on Moon’s Pole-Facing Slopes
Space travel is difficult and expensive – it would cost thousands of dollars to launch a bottle of water to the moon. The recent discovery of hydrogen-bearing molecules, possibly including water, on the moon has explorers excited because these deposits could be mined if they are sufficiently abundant, sparing the considerable expense of bringing water from Earth. Lunar water could be used for drinking or its components – hydrogen and oxygen – could be used to manufacture important products on the surface that future visitors to the moon will need, like rocket fuel and breathable air.
LRO image [Large version] of the moon’s Hayn Crater, located just northeast of Mare Humboldtianum, dramatically illuminated by the low Sun casting long shadows across the crater floor. Image Credit: NASA/GSFC/Arizona State University
Recent observations by NASA’s Lunar Reconnaissance Orbiter (LRO) spacecraft indicate these deposits may be slightly more abundant on crater slopes in the southern hemisphere that face the lunar South Pole. “There’s an average of about 23 parts-per-million-by-weight (ppmw) more hydrogen on Pole-Facing Slopes (PFS) than on Equator-Facing Slopes (EFS),” said Timothy McClanahan of NASA’s Goddard Space Flight Center in Greenbelt, Maryland.
This is the first time a widespread geochemical difference in hydrogen abundance between PFS and EFS on the moon has been detected. It is equal to a one-percent difference in the neutron signal detected by LRO’s Lunar Exploration Neutron Detector (LEND) instrument. McClanahan is lead author of a paper about this research published online October 19 in the journal Icarus.
The hydrogen-bearing material is volatile (easily vaporized), and may be in the form of water molecules (two hydrogen atoms bound to an oxygen atom) or hydroxyl molecules (an oxygen bound to a hydrogen) that are loosely bound to the lunar surface. The cause of the discrepancy between PFS and EFS may be similar to how the Sun mobilizes or redistributes frozen water from warmer to colder places on the surface of the Earth, according to McClanahan.
“Here in the northern hemisphere, if you go outside on a sunny day after a snowfall, you’ll notice that there’s more snow on north-facing slopes because they lose water at slower rates than the more sunlit south-facing slopes” said McClanahan. “We think a similar phenomenon is happening with the volatiles on the moon – PFS don’t get as much sunlight as EFS, so this easily vaporized material stays longer and possibly accumulates to a greater extent on PFS.”
The team observed the greater hydrogen abundance on PFS in the topography of the moon’s southern hemisphere, beginning at between 50 and 60 degrees south latitude. Slopes closer to the South Pole show a larger hydrogen concentration difference. Also, hydrogen was detected in greater concentrations on the larger PFS, about 45 ppmw near the poles. Spatially broader slopes provide more detectable signals than smaller slopes. The result indicates that PFS have greater hydrogen concentrations than their surrounding regions. Also, the LEND measurements over the larger EFS don’t contrast with their surrounding regions, which indicates EFS have hydrogen concentrations that are equal to their surroundings, according to McClanahan. The team thinks more hydrogen may be found on PFS in northern hemisphere craters as well, but they are still gathering and analyzing LEND data for this region.
There are different possible sources for the hydrogen on the moon. Comets and some asteroids contain large amounts of water, and impacts by these objects may bring hydrogen to the moon. Hydrogen-bearing molecules could also be created on the lunar surface by interaction with the solar wind. The solar wind is a thin stream of gas that’s constantly blown off the Sun. Most of it is hydrogen, and this hydrogen may interact with oxygen in silicate rock and dust on the moon to form hydroxyl and possibly water molecules. After these molecules arrive at the moon, it is thought they get energized by sunlight and then bounce across the lunar surface; and they get stuck, at least temporarily, in colder and more shadowy areas.
Since the 1960’s scientists thought that only in permanently shadowed areas in craters near the lunar poles was it cold enough to accumulate this volatile material, but recent observations by a number of spacecraft, including LRO, suggest that hydrogen on the moon is more widespread.
It’s uncertain if the hydrogen is abundant enough to economically mine. “The amounts we are detecting are still drier than the driest desert on Earth,” said McClanahan. However, the resolution of the LEND instrument is greater than the size of most PFS, so smaller PFS slopes, perhaps approaching yards in size, may have significantly higher abundances, and indications are that the greatest hydrogen concentrations are within the permanently shaded regions, according to McClanahan.
The team made the observations using LRO’s LEND instrument, which detects hydrogen by counting the number of subatomic particles called neutrons flying off the lunar surface. The neutrons are produced when the lunar surface gets bombarded by cosmic rays. Space is permeated by cosmic rays, which are high-speed particles produced by powerful events like flares on the Sun or exploding stars in deep space. Cosmic rays shatter atoms in material near the lunar surface, generating neutrons that bounce from atom to atom like a billiard ball. Some neutrons happen to bounce back into space where they can be counted by neutron detectors.
Neutrons from cosmic ray collisions have a wide range of speeds, and hydrogen atoms are most efficient at stopping neutrons in their medium speed range, called epithermal neutrons. Collisions with hydrogen atoms in the lunar regolith reduce the numbers of epithermal neutrons that fly into space. The more hydrogen present, the fewer epithermal neutrons the LEND detector will count.
The team interpreted a widespread decrease in the number of epithermal neutrons detected by LEND as a signal that hydrogen is present on PFS. They combined data from LEND with lunar topography and illumination maps derived from LRO’s LOLA instrument (Lunar Orbiter Laser Altimeter), and temperature maps from LRO’s Diviner instrument (Diviner Lunar Radiometer Experiment) to discover the greater hydrogen abundance and associated surface conditions on PFS.
In addition to seeing if the same pattern exists in the moon’s northern hemisphere, the team wants to see if the hydrogen abundance changes with the transition from day to night. If so, it would substantiate existing evidence of a very active production and cycling of hydrogen on the lunar surface, according to McClanahan.
The research was funded by NASA’s LRO mission. LEND was supplied by the Russian Federal Space Agency Roscosmos. Launched on June 18, 2009, LRO has collected a treasure trove of data with its seven powerful instruments, making an invaluable contribution to our knowledge about the moon. LRO is managed by NASA’s Goddard Space Flight Center in Greenbelt, Maryland, for the Science Mission Directorate at NASA Headquarters in Washington.
Bill Steigerwald
NASA Goddard Space Flight Center, Greenbelt, Maryland
Carnival of Space #391 – The Universe
The Universe blog hosts the latest Carnival of Space.
New Horizons returns new images of Pluto
The New Horizons spacecraft moves ever closer to Pluto and to its fly-by this summer. Here are new pictures taken by the satellite of the Pluto system:
Happy Birthday Clyde Tombaugh:
New Horizons Returns New Images of Pluto
Pluto discoverer Clyde Tombaugh could only dream of a spacecraft flying past the small planet he spotted on the edges of the solar system in 1930. Yet the newest views of Pluto from NASA’s approaching New Horizons probe – released today, on the late American astronomer’s birthday – hint at just how close that dream is to coming true.
Tombaugh, who died in 1997, was born on Feb. 4, 1906.
“This is our birthday tribute to Professor Tombaugh and the Tombaugh family, in honor of his discovery and life achievements — which truly became a harbinger of 21st century planetary astronomy,” said New Horizons Principal Investigator Alan Stern, from the Southwest Research Institute, Boulder, Colorado. “These images of Pluto, clearly brighter and closer than those New Horizons took last July from twice as far away, represent our first steps at turning the pinpoint of light Clyde saw in the telescopes at Lowell Observatory 85 years ago, into a planet before the eyes of the world this summer.”
The “eagle eyes” of New Horizons, LORRI is a panchromatic high-magnification imager, consisting of a telescope with an 8.2-inch (20.8-centimeter) aperture that focuses visible light onto a charge-coupled device. It’s essentially a digital camera with a large telephoto telescope – only fortified to operate in the cold, hostile environs near Pluto. Read more.
The new images, taken with New Horizons’ telescopic Long-Range Reconnaissance Imager (LORRI) on Jan. 25 and Jan. 27, were the first acquired during the spacecraft’s 2015 approach to the Pluto system, which culminates with a close flyby of Pluto and its system of moons on July 14. New Horizons was more than 126 million miles (203 million kilometers) away from Pluto when it began taking the photos, which show Pluto and largest moon, Charon.
“Pluto is finally becoming more than just a pinpoint of light,” said Hal Weaver, New Horizons project scientist at the Johns Hopkins University Applied Physics Laboratory (APL) in Laurel, Maryland. “LORRI has now resolved Pluto, and the dwarf planet will continue to grow larger and larger in the images as New Horizons spacecraft hurtles toward its targets. The new LORRI images also demonstrate that the camera’s performance is unchanged since it was launched more than nine years ago.”
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Six Months of Separation: A comparison of images of Pluto and its large moon Charon, taken in July 2014 and January 2015. Between takes, New Horizons had more than halved its distance to Pluto, from about 264 million miles (425 million kilometers) to 126 million miles (203 million kilometers).
Pluto and Charon are four times brighter than and twice as large as in July, and Charon clearly appears more separated from Pluto. These two images are displayed using the same intensity scales. In LORRI’s current view, Pluto and Charon subtend just 2 pixels and 1 pixel, respectively, compared to 1 pixel and 0.5 pixels last July. The images were magnified four times to make Pluto and Charon more visible.
Both images were rotated to show the celestial north pole at the top.
Image credit: NASA/Johns Hopkins University Applied Physics Laboratory/Southwest Research Institute.
Over the next few months, LORRI will take hundreds of pictures of Pluto against star fields to refine the team’s estimates of New Horizons’ distance to Pluto. As in these first images, the Pluto system will resemble little more than bright dots in the camera’s view until late spring, but mission navigators will use these images to design course-correcting engine maneuvers that precisely aim New Horizons on approach. The first such maneuver based on these “optical navigation” images, or “OpNavs,” is scheduled for March 10.
Closing in on Pluto at about 31,000 miles per hour, New Horizons has already covered more than 3 billion miles since launch on Jan. 19, 2006. Its epic journey has taken it past each planet’s orbit from Mars to Neptune in record time, and it is now in the first stage of an encounter with Pluto that includes long-distance imaging as well as dust, energetic particle and solar wind measurements to characterize the space environment near Pluto.
“My dad would be thrilled with New Horizons,” said Annette Tombaugh, Clyde Tombaugh’s daughter, of Las Cruces, New Mexico. “To actually see the planet that he had discovered and find out more about it, to get to see the moons of Pluto … he would have been astounded. I’m sure it would have meant so much to him if he were still alive today.”
APL manages the New Horizons mission for NASA’s Science Mission Directorate in Washington. Alan Stern, of the Southwest Research Institute (SwRI), headquartered in San Antonio, is the principal investigator and leads the mission. SwRI leads the science team, payload operations, and encounter science planning. New Horizons is part of the New Frontiers Program managed by NASA’s Marshall Space Flight Center in Huntsville, Alabama. APL designed, built and operates the spacecraft.
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A Long Distance Look from LORRI:Pluto and Charon, the largest of Pluto’s five known moons, seen Jan. 25 and 27, 2015, through the telescopic Long-Range Reconnaissance Imager (LORRI) on NASA’s New Horizons spacecraft. New Horizons was about 126 million miles (203 million kilometers) from Pluto when the frames to make the first image were taken; about 1.5 million miles (2.5 million kilometers) closer for the second set. These images are the first acquired during the spacecraft’s 2015 approach to the Pluto system, which culminates with a close flyby of Pluto and its moons on July 14.
Pluto and Charon subtended 2 pixels and 1 pixel, respectively, in LORRI’s field of view. The image was magnified four times to make Pluto and Charon more visible, though during the next several months, the apparent sizes of Pluto and Charon, as well as the separation between them, will continue to expand in the LORRI images.
The image exposure time was only a tenth of a second, which is too short to detect Pluto’s smaller moons. LORRI will also be taking images with longer exposure times (10 seconds) that should reveal both Nix and Hydra.
See the individual images from Jan. 25 and Jan. 27.
Image credit: NASA/Johns Hopkins University Applied Physics Laboratory/Southwest Research Institute.