NASA Launches Satellite to Get the Dirt on Earth's Dirt

A United Launch Alliance Delta II rocket launches NASA's Soil Moisture Active Passive observatory into space from California's Vandenberg Air Force Base on Saturday, Jan. 31, 2015.
A United Launch Alliance Delta II rocket launches NASA's Soil Moisture Active Passive observatory into space from California's Vandenberg Air Force Base on Saturday, Jan. 31, 2015. (Image credit: NASA/Bill Ingalls)

NASA launched its newest Earth-observing mission Saturday (Jan. 31), sending a satellite to the ultimate height to study the dirt below our feet.

The space agency's new Soil Moisture Active Passive satellite (SMAP) satellite successfully launched to space atop an unmanned United Launch Alliance Delta II rocket from Vandenberg Air Force base in California at 9:22 a.m. EST (1422 GMT). SMAP is designed to map the moisture levels in topsoil around the world to help scientist better predict droughts, floods and other weather factors. The spacecraft soared into space and deployed its solar arrays after a flawless launch, NASA officials said.

"It was spectacular," NASA launch director Tim Dunn said after the spacecraft reached orbit. "We're in contact with SMAP and everything looks great. We couldn't be happier." [See photos from NASA's SMAP satellite launch]

A United Launch Alliance Delta II rocket launches NASA's Soil Moisture Active Passive observatory into space from California's Vandenberg Air Force Base on Saturday, Jan. 31, 2015. (Image credit: NASA/Bill Ingalls)

NASA's SMAP, or the Soil Moisture Active Passive satellite, will measure groundwater content and frozen/thawed state, all over the world every three days. See how the SMAP dirt-tracking satellite works in this infographic. (Image credit: By Karl Tate, Infographics Artist)

The SMAP satellite measures moisture in the top 2 inches (5 centimeters) of soil on Earth by using two instruments designed to gather more accurate data about Earth's soil than ever before, officials have said. The mission was initially scheduled to launch on Thursday (Jan. 29), but was delayed 24 hours due to unacceptable winds. The need for a minor rocket repair on Friday pushed the launch back another day.

Once deployed, SMAP's giant antenna will help create a global map of topsoil moisture levels every three days through the mission's initial three-year lifespan, NASA officials have said. The huge, rotating antenna — which measures close to 20 feet (6 meters) in diameter — is the largest of its kind ever flown in space, according to NASA. The satellite should beam back information about soil moisture with unprecedented accuracy.

"SMAP, or the Soil Moisture Active Passive mission, this morning is going to be incredibly important because it will be the first space-borne asset that allows us to look at freeze/thaw cycles; to determine the difference between areas of Earth that are frozen and those that are with normal moisture; and it helps in understanding the carbon dioxide cycle also, which we believe contributes to the planet's change," NASA administrator Charles Bolden said during a webcast before launch.

Scientists want to learn more about soil moisture for a variety of reasons. For one, it will give them a more detailed idea of where and when droughts could happen. And on the flip side of that, SMAP data is also designed to help researchers get a better sense of where floods might occur based on soil moisture data.

NASA's Soil Moisture Active Passive satellite (center in distance) deploys its solar arrays after separating from its Delta II rocket following a flawless launch into space from California's Vandenberg Air Force Base on Jan. 31, 2015. This image was captured by a camera on the Delta II rocket upper stage. (Image credit: NASA TV)

"SMAP is in a unique position because its measurements impact two distinct domains," Dara Entekhabi, SMAP science team leader, said during a news conference Tuesday (Jan. 27). "One, of course, as a science mission it impacts how we fundamentally understand how the environment works and peer into the metabolism of the environment. And second, it impacts some of the applications that touch our everyday lives."

Scientists will use the global soil moisture data to more fully understand the interconnected nature of three of Earth's major cycles — the carbon, water and energy cycles — in order to create more accurate weather maps and predictions. Researchers need an instrument like SMAP because there are too few ground-based sensors to create a highly accurate global map of soil moisture right now, Entekhabi added.

The $916 million mission joins the 19 other Earth-gazing satellites currently monitoring the planet from space today. SMAP will be in an orbit that takes it about 426 miles (685 kilometers) above Earth's surface.

SMAP is one of five Earth-monitoring satellites originally scheduled for launch in 2014. NASA's Orbiting Carbon Observatory-2 satellite, Global Precipitation Measurement Core Observatory and ISS-RapidScat all went to space last year, with the fourth — the agency's Cloud-Aerosol Transport mission — launching earlier in 2015. SMAP is the last of those Earth science missions to fly.

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Miriam Kramer
Staff Writer

Miriam Kramer joined Space.com as a Staff Writer in December 2012. Since then, she has floated in weightlessness on a zero-gravity flight, felt the pull of 4-Gs in a trainer aircraft and watched rockets soar into space from Florida and Virginia. She also served as Space.com's lead space entertainment reporter, and enjoys all aspects of space news, astronomy and commercial spaceflight.  Miriam has also presented space stories during live interviews with Fox News and other TV and radio outlets. She originally hails from Knoxville, Tennessee where she and her family would take trips to dark spots on the outskirts of town to watch meteor showers every year. She loves to travel and one day hopes to see the northern lights in person. Miriam is currently a space reporter with Axios, writing the Axios Space newsletter. You can follow Miriam on Twitter.