Scientists Offer Sharper Insight into Pluto’s Bladed Terrain

NASA - New Horizons Mission logo.

Jan. 4, 2017

Using a model similar to what meteorologists use to forecast weather and a computer simulation of the physics of evaporating ices, scientists have found evidence of snow and ice features on Pluto that, until now, had only been seen on Earth.

Image above: The bladed terrain of Pluto’s informally named Tartarus Dorsa region, imaged by NASA’s New Horizons spacecraft in July 2015. Image Credits: NASA/JHUAPL/SwRI.

Formed by erosion, the features, known as “penitentes,” are bowl-shaped depressions with blade-like spires around the edge that rise several hundreds of feet.

The research, led by John Moores of York University, Toronto, and done in collaboration with scientists at the Johns Hopkins University Applied Physics Laboratory and NASA Goddard Space Flight Center, indicates that these icy features may also exist on other planets where environmental conditions are similar.

The identification of these ridges in Pluto’s informally named Tartarus Dorsa area suggests that the presence of an atmosphere is necessary for the formation of penitentes – which Moores says would explain why they have not previously been seen on other airless icy satellites or dwarf planets. “But exotic differences in the environment give rise to features with very different scales,” he adds. “This test of our terrestrial models for penitentes suggests that we may find these features elsewhere in the solar system, and in other solar systems, where the conditions are right."

The research team, which also includes York’s Christina Smith, Anthony Toigo of APL and Scott Guzewich of Goddard Space Flight Center, compared its model to ridges on Pluto imaged by NASA’s New Horizons spacecraft in 2015. Pluto’s ridges are much larger – more than 1,600 feet (about 500 meters) tall and separated by two to three miles (about three to five kilometers) – than their Earthly counterparts.

“This gargantuan size is predicted by the same theory that explains the formation of these features on Earth,” says Moores. “In fact, we were able to match the size and separation, the direction of the ridges, as well as their age: three pieces of evidence that support our identification of these ridges as penitentes.”

Image above: Artist's conception of the New Horizons spacecraft at Pluto. Image Credits: NASA/JHUAPL.

Moores says though Pluto's environment is very different from Earth’s -- it is much colder, the air much thinner, the sun much dimmer and the snow and ice on the surface are made from methane and nitrogen instead of water -- the same laws of nature apply.  He adds that both NASA and APL were instrumental in the collaboration that led to this new finding; both provided background information on Pluto's atmosphere using a model similar to what meteorologists use to forecast weather on Earth. This was one of the key ingredients in Moores’ own models of the penitentes, without which this discovery would not have been made.   

The findings appear this week in the journal Nature.

New Horizons: http://www.nasa.gov/mission_pages/newhorizons/main/index.html

Images (mentioned), Text, Credits: NASA/Tricia Talbert.

Greetings, Orbiter.ch

Hues in a Crater Slope

NASA - Mars Reconnaissance Orbiter (MRO) logo.

Jan. 4, 2017

Impact craters expose the subsurface materials on the steep slopes of Mars. However, these slopes often experience rockfalls and debris avalanches that keep the surface clean of dust, revealing a variety of hues, like in this enhanced-color image from NASA's Mars Reconnaissance Orbiter, representing different rock types. The bright reddish material at the top of the crater rim is from a coating of the Martian dust.

The long streamers of material are from downslope movements. Also revealed in this slope are a variety of bedrock textures, with a mix of layered and jumbled deposits. This sample is typical of the Martian highlands, with lava flows and water-lain materials depositing layers, then broken up and jumbled by many impact events.

This image was acquired by the High Resolution Imaging Science Experiment (HiRISE) camera on Feb. 28, 2011 at 15:24 local Mars time. It is a stereo pair with image ESP_021454_1550.

The University of Arizona, Tucson, operates HiRISE, which was built by Ball Aerospace & Technologies Corp., Boulder, Colo. NASA's Jet Propulsion Laboratory, a division of Caltech in Pasadena, California, manages the Mars Reconnaissance Orbiter Project for NASA's Science Mission Directorate, Washington.

Additional image products: HiRISE, University of Arizona: http://www.uahirise.org/ESP_021520_1550

Mars Reconnaissance Orbiter (MRO): http://www.nasa.gov/mission_pages/MRO/main/index.html

Image, Text, Credits: NASA/JPL/Sarah Loff/University of Arizona/Caption: Alfred McEwen.

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TIMED Marches On: Watching the Upper Atmosphere for 15 Years and Counting

NASA - TIMED Mission patch.

Jan. 4, 2017

NASA’s TIMED mission — short for Thermosphere, Ionosphere, Mesosphere Energetics and Dynamics — yielded a batch of new discoveries to end its 15th year in orbit. From a more precise categorization of the upper atmosphere’s response to solar storms, to pinpointing the signatures of a fundamental behavior of carbon dioxide, TIMED’s unique position and instruments, along with its decade-plus data record, continue to give scientists an unparalleled look at Earth’s upper atmosphere, our interface to space. Indeed, the very length of the data set has provided unprecedented opportunities to analyze near-Earth space.

Launched Dec. 7, 2001, NASA’s TIMED spacecraft observes the chemistry and dynamics of the upper regions of Earth’s atmosphere — composed of the mesosphere, thermosphere and ionosphere. The critical region that TIMED studies spans altitudes of about 40 to 110 miles above Earth’s surface. Here, the atmosphere is just a tenuous wash of particles that reacts both to energy inputs from above — from changes in the space environment largely due to the sun — and forcing from below, including terrestrial winds.

TIMED’s 15 years of data provides scientists an unrivaled perspective on changes in the upper atmosphere. The long lifespan allows scientists to track the upper atmosphere’s response to both quick-changing conditions — like individual solar storms — throughout the sun’s 11-year activity cycle, as well as longer-term trends, such as those related to climate change.

“By being a longer-term research mission, TIMED naturally became a brand-new mission,” said Diego Janches, TIMED project scientist at NASA’s Goddard Space Flight Center in Greenbelt, Maryland. “Now we can address completely new science that we couldn’t with observations performed over shorter periods of time.”

Image above: Shown in this artist’s concept, NASA’s TIMED spacecraft — short for Thermosphere, Ionosphere, Mesosphere Energetics and Dynamics — has been observing Earth’s upper atmosphere for 15 years, leading to new understandings of how this region interacts with the lower atmosphere below and space above. Image Credits: NASA/JHUAPL.

For example, a 2015 study based on TIMED data revealed that carbon dioxide was increasing unexpectedly fast in the upper atmosphere, a trend that had persisted over TIMED’s long data record. 

All of TIMED’s instruments are still producing data, enabling continuing studies of the upper atmosphere. Recently, researchers from the University of Colorado at Boulder used TIMED measurements to evaluate the presence of a trace chemical called nitric oxide in the upper atmosphere. Produced by the changing chemistry triggered by different types of space weather, such as solar flares and geomagnetic storms, nitric oxide can actually counteract some of the effects of space weather. 

When energy is transferred into Earth’s atmosphere during a geomagnetic storm, some of that energy manifests as heat — and that heat causes the upper atmosphere to swell, as individual molecules fight for more room.

“This swelling means there’s more stuff at higher altitudes than we would otherwise expect,” said Delores Knipp, a space scientist at the University of Colorado at Boulder. “That extra stuff can drag on satellites, disrupting their orbits and making them harder to track.”

This is called satellite drag. The most intuitive understanding of the upper atmosphere’s response would have the most powerful eruptions from the sun ultimately creating the largest amount of swelling, and therefore, more powerful satellite drag. 

However, something counteracts that swelling: nitric oxide. During some geomagnetic storms, the energy input triggers a chemical reaction that produces larger amounts of this nitric oxide. Nitric oxide acts as a cooling agent at very high altitudes, radiating energy to space, so a significant increase in this compound sometimes causes something called overcooling.

“Overcooling causes the atmosphere to quickly shed energy from the geomagnetic storm much quicker than anticipated,” said Knipp. “It’s like the thermostat for the upper atmosphere got stuck on the ‘cool’ setting.”

That quick energy loss counteracts the previous expansion, causing the upper atmosphere to collapse back down — sometimes to an even smaller state than it started in, leaving satellites to orbit through lower-density regions than anticipated.

Animation above: Data from TIMED let scientists pinpoint the types of solar and geomagnetic storms that lead to a phenomenon called overcooling, when Earth’s upper atmosphere quickly contracts after swelling as a result of space weather. Image Credits: NASA’s Goddard Space Flight Center.

One of TIMED’s instruments tracks the quantity of nitric oxide in the upper atmosphere. Researchers compared this TIMED data with data on geomagnetic storms to pin down what types of coronal mass ejections, or CMEs — giant clouds of ejected solar material — lead to an overproduction of nitric oxide and rapid collapse of the upper atmosphere.

“Overcooling is most likely to happen when very fast and magnetically-organized ejecta from the sun rattle Earth’s magnetic field,” said Knipp. 

This means that, counterintuitively, the most energetic CMEs are likely to trigger the geomagnetic storms that provide a net cooling and shrinking effect on the upper atmosphere, rather than heating and expanding it as had been previously understood.

TIMED data has also been key to understanding some of the fundamental physics of the upper atmosphere — including those that govern atmospheric loss, a phenomenon that shapes the habitability of planets. For example, Mars’ ongoing loss of hydrogen atoms from its upper atmosphere may be partially responsible for the planet’s lack of water.

In another TIMED study, published in Nature Communications on Dec. 6, 2016, TIMED data indicated the presence of a significant population of hot hydrogen atoms at altitudes as low as 170 miles, much lower than previously expected.

“This result suggests that current atmospheric models are missing some key physics that impacts many different studies, ranging from atmospheric escape to the thermal structure of the upper atmosphere,” said Lara Waldrop, a space scientist at the University of Illinois at Urbana-Champaign and co-author on the study.

A comprehensive analysis of the TIMED data showed that the temperature of this atomic hydrogen rises when solar activity falls, counter to the behavior of most other neutral molecules in the atmosphere. 

“The hydrogen density distribution is critical to the investigation of our atmospheric system as well as its response to space weather,” said Jianqi Qin, a space scientist at the University of Illinois at Urbana-Champaign and lead author on the study.

Another recent work by researchers at NASA Goddard; George Mason University, Fairfax, Virginia; and SRI International, Arlington, Virginia, has helped scientists clarify a fundamental behavior of carbon dioxide molecules. The new understanding of the complex chemical reactions in the upper atmosphere allows researchers to better track this critical compound in the 15 years of measurements TIMED gathered while flying over Earth’s night side. 

“This new finding is particularly key for the polar night regions, where the long-lasting lack of solar radiation is supposed to significantly influence the chemistry and dynamics,” said Peter Panka, a doctoral student at George Mason University and lead author on the study. 

At night, a recently discovered energy transfer mechanism for carbon dioxide leads to the observed infrared light emission. Now that scientists understand this phenomenon, they can better track the densities of carbon dioxide in the upper and middle atmosphere at night.

NASA Goddard manages the TIMED mission for the Heliophysics Division within the Science Mission Directorate at NASA Headquarters in Washington. The Johns Hopkins University Applied Physics Laboratory in Laurel, Maryland, built and operates the spacecraft for NASA.

For more information about TIMED visit: http://www.timed.jhuapl.edu/WWW/index.php

Image (mentioned), Animation (mentioned), Text, Credits: NASA’s Goddard Space Flight Center, by Sarah Frazier/Rob Garner.

Greetings, Orbiter.ch

Hidden Secrets of Orion’s Clouds

ESO - European Southern Observatory logo.

4 January 2017

VISTA survey gives most detailed view of Orion A molecular cloud in the near-infrared

The Orion A molecular cloud from VISTA

This spectacular new image is one of the largest near-infrared high-resolution mosaics of the Orion A molecular cloud, the nearest known massive star factory, lying about 1350 light-years from Earth. It was taken using the VISTA infrared survey telescope at ESO’s Paranal Observatory in northern Chile and reveals many young stars and other objects normally buried deep inside the dusty clouds.

The new image from the VISION survey (VIenna Survey In Orion) is a montage of images taken in the near-infrared part of the spectrum [1] by the VISTA survey telescope at ESO’s Paranal Observatory in Chile. It covers the whole of the Orion A molecular cloud, one of the two giant molecular clouds in the Orion molecular cloud complex (OMC). Orion A extends for approximately eight degrees to the south of the familiar part of Orion known as the sword [2].

VISTA is the world’s largest dedicated survey telescope, and has a large field of view imaged with very sensitive infrared detectors, characteristics that made it ideal for obtaining the deep, high-quality infrared images required by this ambitious survey.

Highlights from VISTA image of Orion A

The VISION survey has resulted in a catalogue containing almost 800 000 individually identified stars, young stellar objects and distant galaxies, This represents better depth and coverage than any other survey of this region to date [3].

VISTA can see light that the human eye cannot, allowing astronomers to identify many otherwise hidden objects in the stellar nursery. Very young stars that cannot be seen in visible-light images are revealed when observed at longer infrared wavelengths, where the dust that shrouds them is more transparent.

Visible/infrared comparison of views of the Orion A molecular cloud 

The new image represents a step towards a complete picture of the star formation processes in Orion A, for both low and high mass stars. The most spectacular object is the glorious Orion Nebula, also called Messier 42 [4] seen towards the left of the image. This region forms part of the sword of the famous bright constellation of Orion (The Hunter). The VISTA catalogue covers both familiar objects and new discoveries. These include five new young stellar object candidates and ten candidate galaxy clusters.

Zooming in on a new VISTA image of the Orion A molecular cloud

Elsewhere in the image, we can look into Orion A’s dark molecular clouds and spot many hidden treasures, including discs of material that could give birth to new stars (pre-stellar discs), nebulosity associated with newly-born stars (Herbig-Haro objects), smaller star clusters and even galaxy clusters lying far beyond the Milky Way. The VISION survey allows the earliest evolutionary phases of young stars within nearby molecular clouds to be systematically studied.

Slider comparison of visible and infrared views of the Orion A molecular cloud

This impressively detailed image of Orion A establishes a new observational foundation for further studies of star and cluster formation and once again highlights the power of the VISTA telescope to image wide areas of sky quickly and deeply in the near-infrared part of the spectrum [5].

Notes:

[1] The VISION survey covers approximately 18.3 square degrees at a scale of about one-third of an arcsecond per pixel.

[2] The other giant molecular cloud in the Orion Molecular Cloud is Orion B, which lies east of Orion’s Belt.

[3] The complete VISION survey includes an even larger region than is shown in this picture, which covers 39 578 x 23 069 pixels.

[4] The Orion nebula was first described in the early seventeenth century although the identity of the discoverer is uncertain. The French comet-hunter Messier made an accurate sketch of its main features in the mid-eighteenth century and gave it the number 42 in his famous catalogue. He also allocated the number 43 to the smaller detached region just north of the main part of the nebula. Later William Herschel speculated that the nebula might be “the chaotic material of future suns” and astronomers have since discovered that the mist is indeed gas glowing in the fierce ultraviolet light from young hot stars that have recently formed there.

[5] The successful VISION survey of Orion will be followed by a new, bigger public survey of other star-forming regions with VISTA, called VISIONS, which will start in April 2017.

More information:

This research is presented in a paper entitled “VISION - Vienna survey in Orion I. VISTA Orion A Survey”, by S. Meingast et al., published in the journal Astronomy & Astrophysics.

The team is composed of: Stefan Meingast (University of Vienna, Vienna, Austria), João Alves (University of Vienna, Vienna, Austria), Diego Mardones (Universidad de Chile, Santiago, Chile) , Paula Teixeira (University of Vienna, Vienna, Austria), Marco Lombardi (University of Milan, Milan, Italy), Josefa Großschedl (University of Vienna, Vienna, Austria), Joana Ascenso (CENTRA, Universidade de Lisboa, Lisbon, Portugal; Universidade do Porto, Porto, Portugal), Herve Bouy (Centro de Astrobiología, Madrid, Spain), Jan Forbrich (University of Vienna, Vienna, Austria), Alyssa Goodman (Harvard-Smithsonian Center for Astrophysics, Cambridge MA, USA), Alvaro Hacar (University of Vienna, Vienna, Austria), Birgit Hasenberger (University of Vienna, Vienna, Austria), Jouni Kainulainen (Max-Planck-Institute for Astronomy, Heidelberg, Germany), Karolina Kubiak (University of Vienna, Vienna, Austria), Charles Lada (Harvard-Smithsonian Center for Astrophysics, Cambridge, USA), Elizabeth Lada (University of Florida, Gainesville, USA), André Moitinho (SIM/CENTRA, Universidade de Lisboa, Lisbon, Portugal), Monika Petr-Gotzens (ESO, Garching, Germany), Lara Rodrigues (Universidad de Chile, Santiago, Chile) and Carlos G. Román-Zúñiga (UNAM, Ensenada, Baja California, Mexico).

ESO is the foremost intergovernmental astronomy organisation in Europe and the world’s most productive ground-based astronomical observatory by far. It is supported by 16 countries: Austria, Belgium, Brazil, the Czech Republic, Denmark, France, Finland, Germany, Italy, the Netherlands, Poland, Portugal, Spain, Sweden, Switzerland and the United Kingdom, along with the host state of Chile. ESO carries out an ambitious programme focused on the design, construction and operation of powerful ground-based observing facilities enabling astronomers to make important scientific discoveries. ESO also plays a leading role in promoting and organising cooperation in astronomical research. ESO operates three unique world-class observing sites in Chile: La Silla, Paranal and Chajnantor. At Paranal, ESO operates the Very Large Telescope, the world’s most advanced visible-light astronomical observatory and two survey telescopes. VISTA works in the infrared and is the world’s largest survey telescope and the VLT Survey Telescope is the largest telescope designed to exclusively survey the skies in visible light. ESO is a major partner in ALMA, the largest astronomical project in existence. And on Cerro Armazones, close to Paranal, ESO is building the 39-metre European Extremely Large Telescope, the E-ELT, which will become “the world’s biggest eye on the sky”.

Links:

Research paper: http://www.eso.org/public/archives/releases/sciencepapers/eso1701/eso1701a.pdf

Photos of VISTA: http://www.eso.org/public/images/archive/category/surveytelescopes/

ESOcast 90 Light – Orion’s Cloudy Secrets 4K UHD: http://www.eso.org/public/videos/eso1701a/

VISION survey (VIenna Survey In Orion): http://homepage.univie.ac.at/stefan.meingast/vision.html

VISTA survey telescope: http://www.eso.org/public/teles-instr/surveytelescopes/vista/

ESO’s Paranal Observatory: http://www.eso.org/paranal/

Images, Text, Credits: ESO/VISION survey/Videos: ESO/VISION survey/Digitized Sky Survey 2/N. Risinger (skysurvey.org)/Music: Johan B. Monell.

Best regards, Orbiter.ch

Robotics Work Starts Station Power Upgrade Before Spacewalks

ISS - Expedition 50 Mission patch.

Jan. 3, 2017

ISS - International Space Station. Animation Credit: NASA

In a remarkable demonstration of robotic prowess, ground controllers used the Canadian-built “Dextre” Special Purpose Dexterous Manipulator over the weekend to install three new lithium-ion batteries in the International Space Station’s 3A power channel Integrated Electronics Assembly (IEA) pallet on the starboard 4 truss. Dextre also removed four old nickel-hydrogen batteries from the IEA, three of which were stowed on the Japanese H-II Transfer Vehicle’s external pallet to wrap up the first act of a complex procedure to upgrade the station’s power system. A fourth old battery was temporarily stowed on a platform on Dextre.

This clears the way for the first of two spacewalks Friday in which Expedition 50 Commander Shane Kimbrough and Flight Engineer Peggy Whitson of NASA will install three adapter plates in slots on the IEA to which three of the old nickel-hydrogen batteries will be mounted to remain on the ISS but will be dormant. In all, nine nickel-hydrogen batteries will be stowed on the external pallet for disposal when the HTV is deorbited to burn up in the Earth’s atmosphere late this month.

Image above: Japan’s H-II Transfer Vehicle is seen with the Earth behind it. image Credit: NASA.

Three additional new lithium-ion batteries flown to the ISS aboard the HTV will be robotically installed in the starboard truss’ 1A power channel Integrated Electronics Assembly between Friday’s spacewalk and a second spacewalk scheduled Jan. 13 for Kimbrough and Flight Engineer Thomas Pesquet of the European Space Agency. Five additional nickel-hydrogen batteries will be removed robotically from the IEA prior to the second spacewalk.

A briefing to preview the two spacewalks and to review all of the robotics work will be broadcast on NASA Television on Wednesday, Jan. 4 at 2 p.m. Eastern time.

Related article:

NASA Preps for Space Station Power Upgrade Spacewalks; Live NASA TV Coverage
http://orbiterchspacenews.blogspot.ch/2016/12/nasa-preps-for-space-station-power.html

Space Station Research and Technology: https://www.nasa.gov/mission_pages/station/research/index.html

International Space Station (ISS): https://www.nasa.gov/mission_pages/station/main/index.html

Image (mentioned), Animation (mentioned), Text, Credits: NASA/Mark Garcia.

Best regards, Orbiter.ch

Mission Awards Secure Commercial Crew Transportation for Coming Years

NASA logo.

Jan. 3, 2017

Commercial Crew Program. Image Credit: NASA

NASA took another big step to ensure reliable crew transportation to the International Space Station into the next decade. The agency’s Commercial Crew Program has awarded an additional four crew rotation missions each to commercial partners, Boeing and SpaceX, to carry astronauts to and from the International Space Station.

The four additional missions will fly following NASA certification. They fall under the current Commercial Crew Transportation Capability contracts, and bring the total number of missions awarded to each provider to six.

The additional flights will allow the commercial partners to plan for all aspects of these missions while fulfilling space station transportation needs. The awards do not include payments at this time.

Image above: Boeing and United Launch Alliance have added a tower and access arm to Space Launch Complex 41 for launches of Starliner spacecraft carrying astronauts aboard Atlas V rockets. Image Credit: NASA.

"Awarding these missions now will provide greater stability for the future space station crew rotation schedule, as well as reduce schedule and financial uncertainty for our providers," said Phil McAlister, director, NASA’s Commercial Spaceflight Development Division. “The ability to turn on missions as needed to meet the needs of the space station program is an important aspect of the Commercial Crew Program.”

The two commercial spacecraft also will provide a lifeboat capability to allow the astronauts aboard the station to return safely to Earth in an emergency, if necessary.

Returning human launch capabilities to U.S. soil underscores NASA’s commitment to the station and the research that the orbiting laboratory makes possible including the advancement of scientific knowledge off the Earth, for the benefit of those on the Earth and to prepare for future deep space exploration.

The Commercial Crew Program will help NASA get full operational use from the national laboratory for scientific research by increasing the number of astronauts on the space station, and allowing the crew members to dedicate more time to research.

The commercial crew vehicles will transport up to four astronauts for NASA missions, along with about 220 pounds of critical cargo to the space station.

Image above: SpaceX has been modifying Launch Complex 39A for launches of Falcon 9 rockets carrying Crew Dragon spacecraft and astronauts. Image Credit: SpaceX.

More time dedicated for research allows NASA to better understand the challenges of long-duration human spaceflight without leaving low-Earth orbit. As NASA develops the Orion spacecraft and the Space Launch System rocket for deep space missions, including the journey to Mars, NASA is turning over low-Earth orbit crew and cargo transportation to commercial companies. This two-pronged approach is critical to achieve the agency’s exploration goals.

Boeing’s uncrewed flight test, known as an Orbital Flight Test, is currently scheduled for June 2018 and its crewed flight test currently is planned for August 2018. SpaceX’s uncrewed flight test, or Demonstration Mission 1, is currently scheduled for November 2017, followed by its first crew flight test in May 2018.  Once the flight tests are complete and NASA certifies the providers for flight, the post-certification missions to the space station can begin.

Boeing and SpaceX are developing two unique human space transportation systems. They also are upgrading necessary infrastructure, including launch pads, processing facilities, control centers and firing rooms.
Boeing is developing the CST-100 Starliner that will launch on a United Launch Alliance Atlas V rocket from Space Launch Complex 41 at Cape Canaveral Air Force Station. SpaceX is developing the Crew Dragon to launch on the company’s Falcon 9 rocket from Launch Pad 39A at the agency’s Kennedy Space Center. Both are located on Florida’s Space Coast.

Related links:

Commercial Crew: https://www.nasa.gov/exploration/commercial/crew/index.html

Commercial Space: http://www.nasa.gov/exploration/commercial/index.html

Images (mentioned), Text, Credits: NASA/Steven Siceloff.

Greetings, Orbiter.ch

NASA Adds up Heavy Rainfall from Southeastern US Severe Weather

NASA & JAXA - Global Precipitation Measurement (GPM) logo.

Jan. 3, 2017

Severe thunderstorms spawned tornadoes and generated flooding rainfall over the Southeast on Monday evening, Jan. 2, 2017. Using satellite data, NASA analyzed the rainfall from the outbreak and found up to a foot of rain had fallen over a five-day period.

At least 12 tornadoes were reported with twisters spotted in Mississippi, Alabama and Georgia. Four deaths in Alabama and one in Florida have been blamed on this violent weather.

Image above: NASA's IMERG estimated total rainfall from Dec. 30, 2016, through early Jan. 3, 2017, at more than 12 inches (305 mm) over the southeastern United States. Red symbols show the locations where some of the numerous tornadoes were reported. Image Credits: NASA/JAXA, Hal Pierce.

The Global Precipitation Measurement mission, or GPM, core satellite measures rainfall from space. It is also part of a constellation of satellites that provides data for NASA's IMERG or Integrated Multi-satellite Retrievals for GPM (IMERG) program which creates a merged precipitation product from the GPM constellation of satellites. GPM is a joint mission between NASA and the Japan Aerospace Exploration Agency (JAXA).

IMERG estimated total rainfall from Dec. 30, 2016, through early Jan. 3, 2017. This analysis of rainfall over the Southeast indicates that more than 12 inches (305 mm) of rain fell over the southeastern United States during this stormy period.

Rainfall Total Estimates for Southeastern US Storms

Image above: IMERG estimated total rainfall from Dec. 30, 2016, through early Jan. 3, 2017. This analysis of rainfall over the Southeast indicates that more than 12 inches (305 mm) of rain fell over the southeastern United States during this stormy period. Red symbols show the locations where some of the numerous tornadoes were reported. Image Credits: NASA/JAXA, Hal Pierce.

The IMERG data are produced using data from satellites in the GPM Constellation and then calibrated with measurements from the GPM Core Observatory as well as rain gauge networks around the world. The calculations were done at NASA's Goddard Space Flight Center in Greenbelt, Maryland.

For more information about GPM, visit: https://www.nasa.gov/gpm
For more information about IMERG and other precipitation products, visit: https://pmm.nasa.gov

GPM (Global Precipitation Measurement): http://www.nasa.gov/mission_pages/GPM/main/index.html and http://global.jaxa.jp/projects/sat/gpm/

Image (mentioned), Video (mentioned), Text, Credits: NASA's Goddard Space Flight Center, by Hal Pierce and Rob Gutro/Rob Garner.

Best regards, Orbiter.ch