Great Shot! #lightning

WOW! Great chapter!

“He likes this side of her, a side he’s never seen, the soft, vulnerable, slightly clingy Kate. It’s such a stark contrast to who he sees on a daily basis, different even from the glimpses of vulnerability she’s allowed him to see, and he really likes it.” A post-2x18 AU.

Rated: M

Beautiful! :)

Iceland Photographed by Steve Lansdell

js

Love this one! #lightning

So exciting!!  GOES-R scheduled for launch today (11/19) at 542 PM EST.  Great new technology, improved imagery, MORE imagery, NEW total lightning detection, and much more.  Learn more about GOES-R by visiting                  www.goes-r.gov . 

You can watch the launch on NASA TV.  Check your local cable/satellite provider or you can watch online through USTREAM or via nasa.gov ‘s NASA TV website.  Enjoy! 

READY FOR LAUNCH: CU BOULDER INSTRUMENT SUITE TO ASSESS SPACE WEATHER

A multimillion dollar University of Colorado Boulder instrument package expected to help scientists better understand potentially damaging space weather is now slated to launch aboard a National Oceanic and Atmospheric Administration satellite on Saturday, Nov. 19.

Designed and built by CU Boulder’s Laboratory for Atmospheric and Space Physics (LASP), the instrument suite known as the Extreme Ultraviolet and X-ray Irradiance Sensors (EXIS) is the first of four identical packages that will fly on four NOAA weather satellites in the coming decade. EXIS will measure energy output from the Sun that can affect satellite operations, telecommunications, GPS navigation and power grids on Earth as part of NOAA’s next-generation Geostationary Operational Environmental Satellites-R Series (GOES-R).

“We are ready for launch and are looking forward to a successful mission,” said LASP Senior Research Scientist Frank Eparvier, principal investigator on the EXIS project. “These extremely sensitive instruments will help scientists better understand solar events and help to mitigate the effects of space weather on Earth.”

NASA’s contract with CU Boulder on behalf of NOAA to design, build, test, deliver and scientifically support the four instrument packages is for roughly $105 million. The GOES-R satellite was built by Lockheed Martin Space Systems Co. in Littleton, Colorado and will be launched on an Atlas V rocket built by United Launch Alliance, headquartered in Centennial, Colorado.

EXIS consists of two LASP instruments, including XRS, an X-ray sensor that can determine the strength of solar flares and provide rapid alerts to scientists, said Eparvier. Large solar flares, equivalent to the explosion of millions of atomic bombs, can trigger “proton events” that send charged atomic particles flying off the Sun and into Earth’s atmosphere in just minutes. They can damage satellites, trigger radio blackouts and even threaten the health of astronauts by penetrating spacecraft shielding, he said.

“The XRS gives the first alert that a solar flare is occurring, providing NOAA with details on its timing, magnitude and direction within seconds,” said Eparvier.

The second EXIS instrument, EUVS, will monitor solar output in the extreme ultraviolet portion of the electromagnetic spectrum, which is completely absorbed by Earth’s upper atmosphere, said Eparvier. When the extreme UV light wavelengths penetrate the upper atmosphere during active periods on the Sun, they can break apart, ionize and change the properties of the atmosphere through which satellites fly and radio waves propagate.

Fluctuations in extreme UV wavelengths from the Sun ionize the upper atmosphere and interfere with communications like cell phones and GPS signals, said Eparvier. In addition, such fluctuations can create satellite drag, causing spacecraft to slowly fall out of orbit and burn up months or years before such events are anticipated.

“Modern technology has made us vulnerable to extreme variations in space weather that can have significant effects on Earth communications,” Eparvier said. “Extreme solar activity can cause problems for power companies all around the world, for example, in part because they all are interconnected.”

NOAA’s GOES satellites are a series of weather satellites that help scientists make timely and accurate weather forecasts. Two GOES satellites are now in geostationary orbit at a height of about 22,000 miles, with one focusing on the east part of the Americas overlapping with another focusing on the west. Satellites in geostationary orbits complete one revolution in the same amount of time it takes for the Earth to rotate once on its polar axis, allowing them to “stare” at a portion of Earth, said Eparvier.

LASP also built key solar instruments for NASA’s Van Allen Probes mission launched in 2012 to study Earth’s radiation belts, and designed and built a $32 million instrument package for NASA’s Solar Dynamics Observatory that launched in 2010.

More than 100 LASP personnel ranging from scientists and engineers to technicians, programmers and students have worked on the EXIS program since 2006. CU Boulder’s LASP will support EXIS on the four NOAA GOES satellite missions through spacecraft integration, testing, launch and commissioning, said Eparvier.

Each instrument package, roughly the size of a large microwave oven and weighing 66 pounds, is three times heavier than normal due to extra shielding that protects them from high-energy particle penetration. LASP’s Mike Anfinson is the EXIS project manager.

Launch was delayed. Tentatively scheduled for Thursday 12/15 at 826 AM EST.  Lots more information available through www.nasa.gov/cygnss . More great satellite info upcoming!  

Eight Small Satellites Will Give Us a New Look Inside Hurricanes

The same GPS technology that helps people get where they’re going in a car will soon be used in space in an effort to improve hurricane forecasting. The technology is a key capability in a NASA mission called the Cyclone Global Navigation Satellite System (CYGNSS).

The CYGNSS mission, led by the University of Michigan, will use eight micro-satellite observatories to measure wind speeds over Earth’s oceans, increasing the ability of scientists to understand and predict hurricanes. Each microsatellite observatory will make observations based on the signals from four GPS satellites.

The CYGNSS microsatellite observatories will only receive signals broadcast directly to them from GPS satellites already orbiting the Earth and the reflection of the same satellite’s signal reflected from the Earth’s surface. The CYGNSS satellites themselves will not broadcast.

The use of eight microsatellite observatories will decrease the revisit time as compared with current individual weather satellites. The spacecraft will be deployed separately around the planet, with successive satellites passing over the same region every 12 minutes.

This will be the first time that satellites can peer through heavy tropical rainfall into the middle of hurricanes and predict how intense they are before and during landfall.

As the CYGNSS and GPS constellations orbit around the Earth, the interaction of the two systems will result in a new image of wind speed over the entire tropics every few hours, compared to every few days for a single satellite.

Another advantage of CYGNSS is that its orbit is designed to measure only in the tropics…where hurricanes develop and are most often located. The focus on tropical activity means that the instruments will be able to gather much more useful data on weather systems exclusively found in the tropics. This data will ultimately be used to help forecasters and emergency managers make lifesaving decisions.

Watch Launch!

Launch of CYGNSS is scheduled for 8:24 a.m. EST on Monday, Dec. 12 from our Kennedy Space Center in Florida. CYGNSS will launch aboard an Orbital ATK Pegasus XL rocket, which will be deployed from Orbital’s “Stargazer” L-1011 carrier aircraft. 

Pegasus is a winged, three-stage solid propellant rocket that can launch a satellite into low Earth orbit. How does it work? Great question! 

After takeoff, the aircraft (which looks like a commercial airplane..but with some special quirks) flies to about 39,000 feet over the ocean and releases the rocket. 

After a five-second free fall in a horizontal position, the Pegasus first stage ignites. The aerodynamic lift, generated by the rocket’s triangle-shaped wing, delivers the payload into orbit in about 10 minutes. 

Pegasus is used to deploy small satellites weighing up to 1,000 pounds into low Earth orbit. 

Watch live coverage HERE. 

Make sure to follow us on Tumblr for your regular dose of space: http://nasa.tumblr.com

Enjoying life, and loving #Castle, plus other stuff...

Will always love #Castle, even in its end, living on through FanFiction. Also love weather (my career, too!), my hub and our lovely cats.  Southern New England USA. 

More #aurora shots! Gorgeous!!!😊

Kirkjufell, Iceland

Lovely #lightning shot!!! #weather #sky

tropical sky by Alexandr Popovsky

So sad. RIP Bill.

Rest in peace Bill Paxton, “The Extreme” Actor behind iconic roles in Twister, Titanic, and Apollo 13, has passed away at 61 years old.

Gorgeous CB!!!