NASA SDO: Sun Monitoring Satellite captures 100 millionth image

The Atmospheric Imaging Assembly on NASA's Solar Dynamics Observatory captured its 100 millionth image of the sun on Jan. 19, 2015. 

The dark areas at the bottom and the top of the image are coronal holes, areas of less dense gas, where solar material has flowed away from the sun. 

Credit: NASA/SDO/AIA/LMSAL

On Jan. 19, 2015, at 12:49 p.m. EST, an instrument on NASA's Solar Dynamics Observatory captured its 100 millionth image of the sun.

The instrument is the Atmospheric Imaging Assembly (AIA), which uses four telescopes working parallel to gather eight images of the sun, cycling through 10 different wavelengths -- every 12 seconds.

The Atmospheric Imaging Assembly (AIA) images the solar atmosphere in multiple wavelengths to link changes in the surface to interior changes. 

Data includes images of the Sun in 10 wavelengths every 10 seconds. 

Credit: NASA SDO, Lockheed Martin Solar Astrophysics Laboratory

The Helioseismic and Magnetic Imager extends the capabilities of the SOHO/MDI instrument with continual full-disk coverage at higher spatial resolution and new vector magnetogram capabilities.

Credit: NASA SDO, Lockheed Martin Solar Astrophysics Laboratory

Between the AIA and two other instruments on board, the Helioseismic Magnetic Imager (HMI) and the Extreme Ultraviolet Variability Experiment (EVE), SDO sends down a whopping 1.5 terabytes of data a day.

The Extreme Ultraviolet Variability Experiment measures the solar extreme-ultraviolet (EUV) irradiance with unprecedented spectral resolution, temporal cadence, and precision. 

EVE measures the solar extreme ultraviolet (EUV) spectral irradiance to understand variations on the timescales which influence Earth's climate and near-Earth space.

Credit: NASA SDO, Lockheed Martin Solar Astrophysics Laboratory

AIA is responsible for about half of that. Every day it provides 57,600 detailed images of the sun that show the dance of how solar material sways and sometimes erupts in the solar atmosphere, the corona.

In the almost five years since its launch on Feb. 11, 2010, SDO has provided images of the sun to help scientists better understand how the roiling corona gets to temperatures some 1000 times hotter than the sun's surface, what causes giant eruptions such as solar flares, and why the sun's magnetic fields are constantly on the move.

ESA ATV-5, Georges Lemaître, Fully Loaded and Hatch Closed

ESA’s fifth Automated Transfer Vehicle, Georges Lemaître, is now scheduled for launch to the International Space Station at 23:44 GMT on 29 July (01:44 CEST 30 July) on an Ariane 5 rocket from Europe’s Spaceport in Kourou, French Guiana.

ATV-5 will deliver more than six tonnes of cargo to the Station, again breaking the record for the heaviest spacecraft launched on Ariane.

Everything has been loaded and the ferry is now sealed until it reaches the orbital outpost.

ESA astronaut Alexander Gerst, currently on board the ISS, will be the first to open the hatch of ATV-5, Georges Lemaître, in space when he takes responsibility for the cargo as ‘loadmaster’.

Alexander will manage the unloading of 6.6 tonnes of experiments, spare parts, clothing, food, fuel, air, oxygen and water for the six astronauts living in the 'weightless' (Zero Gravity) laboratory.

ATV-5, Georges Lemaître showing the closed hatch after completion of cargo loading.

NASA COSmIC Simulator Recreates Space Dust

Scanning Electron Microscope image of a large (approximately 1.5 micrometer diameter) aggregate of nanograins produced in the Cosmic Simulation Chamber (COSmIC) at NASA's Ames Research Center, using a 95 percent Ar - 5% C2H2 gas mixture. 

The nanograins and aggregates are deposited onto ultra-high vacuum aluminum foil. 

Image courtesy NASA/Ames/Farid Salama.

A team of scientists at NASA's Ames Research Center in Moffett Field, Calif., has successfully reproduced, right here on Earth, the processes that occur in the atmosphere of a red giant star and lead to the formation of planet-forming interstellar dust.

Using a specialist facility, called the Cosmic Simulation Chamber (COSmIC) designed and built at Ames, scientists now are able to recreate and study in the laboratory dust grains similar to the grains that form in the outer layers of dying stars.

Scientists plan to use the dust to gather clues to better understand the composition and the evolution of the universe.

Dust grains that form around dying stars and are ejected into the interstellar medium lead, after a life cycle spanning millions of years, to the formation of planets and are a key component of the universe's evolution.

Scientists have found the materials that make up the building blocks of the universe are much more complicated than originally anticipated.

"The harsh conditions of space are extremely difficult to reproduce in the laboratory, and have long hindered efforts to interpret and analyze observations from space," said Farid Salama, project leader and a space science researcher at Ames.

"Using the COSmIC simulator we can now discover clues to questions about the composition and the evolution of the universe, both major objectives of NASA's space research program."

In the past, the inability to simulate space conditions in the gaseous state prevented scientists from identifying unknown matter.

Because conditions in space are vastly different from conditions on Earth, it is challenging to identify extraterrestrial materials.

Thanks to COSmIC, researchers can successfully simulate gas-phase environments similar to interstellar clouds, stellar envelopes or planetary atmospheres environments by expanding gases using a cold jet spray of argon gas seeded with hydrocarbons that cools down the molecules to temperatures representative of these environments.

COSmIC integrates a variety of state-of-the-art instruments to allow scientists to recreate space conditions in the laboratory to form, process and monitor simulated planetary and interstellar materials.

The chamber is the heart of the system. It recreates the extreme conditions that reign in space where interstellar molecules and ions float in a vacuum at densities that are billionths of Earth's atmosphere, average temperatures can be less than -270 degrees Fahrenheit (about 100 degrees Kelvin), and the environment is bathed in ultraviolet and visible radiation emanating from nearby stars.

"By using COSmIC and building up on the work we recently published in the Astrophysical Journal August 29, 2013, we now can for the first time truly recreate and visualize in the laboratory the formation of carbon grains in the envelope of stars and learn about the formation, structure and size distribution of stellar dust grains," said Cesar Contreras of the Bay Area Environmental Research (BAER) Institute and a research fellow at Ames.

"This type of new research truly pushes the frontiers of science toward new horizons, and illustrates NASA's important contribution to science."

The team started with small hydrocarbon molecules that it expanded in the cold jet spray in COSmIC and exposed to high energy in an electric discharge.

They detected and characterized the large molecules that are formed in the gas phase from these precursor molecules with highly sensitive detectors, then collected the individual solid grains formed from these complex molecules and imaged them using the Ames Scanning Electron Microscope (SEM) (Hitachi S4800 Field Emission SEM).

"During COSmIC experiments, we are able to form and detect nanoparticles on the order of 10 nm size, grains ranging from 100-500 nanometers and aggregates of grains up to 1.5 micrometers in diameter, about a tenth the width of a human hair, and observe their structure with SEM, thus sampling a large size distribution of the grains produced," said Ella Sciamma-O'Brien, of the BAER Institute and a research fellow at Ames.

These results have important implications and ramifications not only for interstellar astrophysics, but also for planetary science.

For example, they can provide new clues on the type of grains present in the dust around stars.

That in turn, will help us understand the formation of planets, including Earth-like planets.

They also will help interpret astronomical data from the ESA Herschel Space Observatory, the Stratospheric Observatory for Infrared Astronomy (SOFIA) and ESO's ALMA, the ground-based Atacama Large Millimeter/submillimeter Array (ALMA) observatory in Chile.

"Today we are celebrating a major milestone in our understanding of the formation and the nature of cosmic dust grains that bears important implications in this new era of exoplanets discoveries," concluded Salama.

NASA's Space Communications and Navigation (SCaN) test bed has begun its experiments

NASA's Space Communications and Navigation (SCaN) test bed has begun its experiments after completing its checkout on the International Space Station.

The SCaN test bed is an advanced, integrated communications laboratory facility that uses a new generation of software-defined radio (SDR) technology to allow researchers to develop, test and demonstrate advanced communications, networking and navigation technologies in space.

This radio communication technology is based on a new standard that enables radio characteristics and functionality to be changed simply by altering the software. It can be transferred to any radio built to the standard.

The cost savings and efficiency of this new technology will improve NASA's data communications in the future.

Michael Suffredini

"The space station serves as a dynamic test bed for the technologies needed for future human and robotic exploration," said International Space Station Program Manager Michael Suffredini.

"SCaN is an example of the technologies that are being matured in low-Earth orbit and used to increase science return of many different types of spacecraft."

Checkout activities completed in February established the status and health of the payload, including the antenna systems and software on each of three SDRs.

The test bed will help technology developers and mission planners understand how they will be used in future missions.

"With the development and deployment of this test bed, NASA has enabled significant future advancements by gaining knowledge and understanding of SDR development," said John Rush, technology and standards director for SCaN at NASA Headquarters in Washington.

"That has created expertise across the agency that will define and develop the next generation of SDRs for future missions."

Initial experiments under way include advancing in S-band and Ka-band SDR technology and enhancing the capabilities of the existing communications paths, especially in the Ka-band. Researchers expect the test bed to operate aboard the space station for as long as six years.

"The SCaN Test bed represents a significant advancement in SDRs and its applications for NASA," said David Irimies, project manager for the SCaN test bed at NASA's Glenn Research Center in Cleveland.

Credit: John Rush, technology and standards director for SCaN at NASA.
An experiment with NASA's latest Tracking and Data Relay Satellite (TDRS)-K will be the first in-orbit test and demonstration of a TDRS spacecraft acquiring and successfully auto-tracking a Ka-band user in low-Earth orbit.

This reconfigurable in-orbit laboratory provides broad participation to NASA, industry, academia and other government agencies.

These experiments will contribute data to the Space Telecommunications Radio Standard Compliant repository and will enable future hardware platforms to use common, reusable software modules to reduce development time and costs.

Oldest EVA Spacewalker: Russian cosmonaut Pavel Vinogradov (59)

Russian cosmonaut Pavel Vinogradov floats outside the International Space Station near the end of a 6.5-hour spacewalk on April 19, 2013. 

Vinogradov, 59, became the world's oldest spacewalker during a spacewalk that was only marred by the last-minute loss of an experiment. 

CREDIT: NASA TV

Pavel Vinogradov, a veteran cosmonaut, took his seventh cosmic excursion in 16 years during Friday's spacewalk.

He donned a bulky Russian Orlan-MK spacesuit and left the confines of the International Space Station just after 10 a.m. EDT (1400 GMT) to upgrade the orbiting lab with new experiments.

Vinogradov paired up with 41-year-old fellow cosmonaut Roman Romanenko, a first-time spacewalker but second-generation cosmonaut.

Romanenko's father, former cosmonaut Yuri Romanenko, logged more than 10 spacewalking hours in his career, including long stay durations in the Soyuz MIR Spacestation, a predecessor of the ISS.

The spacewalkers were at times lighthearted during the more-than-six-hour job.

"Nobody took a photo of me," Romanenko jokingly protested after heaing they used a camera to take pictures outside the lab. "How can it be like that? Please take a photo of me, Pavel."

In the last task of the spacewalk, Vinogradov was attempting to retrieve a panel from the Russian materials exposure experiment called Vinoslivost, but the panel flew out of his grasp before he had a chance to tether it. The cosmonauts were unable to recover the piece.

Flight controllers do not believe the 6.5-pound (3-kg) panel, which measured 18 inches by 12 inches (45 cm by 30 cm), hit any part of the space station.

NASA announcers noted that there is another Vinoslivost panel still attached to the space station that will be retrieved in a future spacewalk, so all is not lost from the experiment.

Vinogradov and Romanenko's primary objective was to install a new Russian experiment called Obstanovka, which will measure charged particles interact with a variety of materials kept outside of the space station.

Obstanovka could offer scientists new insights about how space weather affects the ionosphere, an active region of the Earth's atmosphere, NASA officials explained in a spacewalk description.

The pair also successfully retrieved a Biorisk canister, an experiment that measures the effects of bacteria and fungus on spacecraft materials, and prepared the outpost for the arrival of a robotic cargo ship later this year.

The spacewalkers are two members of the six-man Expedition 35 crew currently living aboard the International Space Station.

The others are Canadian astronaut Chris Hadfield, Russian cosmonaut Alexander Misurkin, and NASA astronauts Thomas Marshburn and Chris Cassidy.

This was the 167th spacewalk dedicated to the construction and upkeep of the International Space Station, which was built by five different space agencies representing 15 countries.

Russian Plans Launch of Lunar Probe, Luna-Glob

An artist's illustration of Russia's Luna-Glob spacecraft. 

CREDIT: NASA

Russia will launch an unmanned spacecraft to the moon in 2015, the first step in a new push toward establishing a fully robotic lunar station, according to press reports.

The new moon orbiter, called Luna-Glob, should be ready for launch in two years and is expected to be the first of four missions to establish a lunar base, Russia’s RIA Novosti reported today (Jan. 15).

The spacecraft will carry scientific instruments used for measuring dust and cosmic rays as well as tools that will be used for astrophysics experiments as part of the unmanned mission to the moon. Eventually, the probe should traffic samples of lunar dust and rock back to Earth.

Russia's goal to set up this lunar station dates back to the late 1990's, and was originally marked for completion last year.

However, due to a few budgetary setbacks, the Russian Federal Space Program had to postpone the launch, but it appears to be back on track.

The space agency is also planning on developing better strategies for manned moon exploration. The Federal Space Program recently received 10 million rubles (US $330,000) to create a new rocket that could launch their cosmonauts to the moon.

That project is set for completion at the end of May of this year.

ESA ATV-s, Edoardo Amaldi: Unloading the Automated Transfer Vehicle, ATV3

Unloading the Automated Transfer Vehicle, ATV3. in near Zero Gravity.

Worms in Space to Study Microgravity

A still from a video filmed at the mission
landing site which shows worm movement

A transparent roundworm could reveal the biological effects of microgravity and space radiation, and perhaps provide clues on how to protect future human astronauts headed for the moon, Mars and beyond.

The C. elegans worm's biological responses proved eerily similar to those of humans during a series of experiments aboard the International Space Station in 2004. Now researchers have published a review of their findings in the journal Advances in Space Research.