For the first time, the world's oceans, lakes and rivers, basically all the water on Earth, will be comprehensively surveyed from space as a NASA-led international satellite mission gears up to begin a major Earth science project from orbit and is set for blastoff from Southern California.
Dubbed SWOT, short for Surface Water and Ocean Topography, the advanced radar satellite is designed to give scientists an unprecedented view of the life-giving fluid covering 70% of the planet, shedding new light on the mechanics and consequences of climate change.
A Falcon 9 rocket, owned and operated by billionaire Elon Musk's commercial launch company SpaceX, was set to liftoff this week from the Vandenberg U.S. Space Force Base, about 275 kilometers (170 miles) northwest of Los Angeles, to carry SWOT into orbit.
If all goes as planned, the SUV-sized satellite will produce research data within several months.
Nearly 20 years in development, SWOT incorporates advanced microwave radar technology that scientists say will collect height-surface measurements of oceans, lakes, reservoirs and rivers in high-definition detail over 90% of the globe.
The data, compiled from radar sweeps of the planet at least twice every 21 days, will enhance ocean-circulation models, bolster weather and climate forecasts, and aid in managing scarce freshwater supplies in drought-stricken regions, according to researchers.
The satellite was designed and built at NASA's Jet Propulsion Laboratory (JPL) near Los Angeles. Developed by the U.S. space agency in collaboration with its counterparts in France and Canada, SWOT was one of 15 missions the National Research Council listed as projects NASA should undertake in the coming decade.
"It's the first mission to observe nearly all water on the planet's surface," said JPL scientist Ben Hamlington, who also leads NASA's sea-level change team.
One major thrust of the mission is to explore how oceans absorb atmospheric heat and carbon dioxide in a natural process that moderates global temperatures and climate change.
Scanning the seas from orbit, SWOT is designed to precisely measure subtle differences in surface elevations around smaller currents and eddies, where much of the oceans' drawdown of heat and carbon is believed to occur. And SWOT can do so with ten times greater resolution than existing technologies, according to JPL.
Oceans are estimated to have absorbed more than 90% of the excess heat trapped in Earth's atmosphere by human-caused greenhouse gas emissions.
Studying the mechanism by which that happens will help climate scientists answer a crucial question: "What is the turning point at which oceans start releasing, rather than absorbing, huge amounts of heat back into the atmosphere and accelerate global warming, rather than limiting it," said Nadya Vinogradova Shiffer, SWOT's program scientist at NASA in Washington.
SWOT's ability to discern more minor surface features also be used to study the impact of rising ocean levels on coastlines.
More precise data along tidal zones would help predict how far storm-surge flooding may penetrate inland, and the extent of saltwater intrusion into estuaries, wetlands and underground aquifers.
Freshwater bodies are another key focus of SWOT, equipped to observe the entire length of nearly all rivers wider than 100 meters (330 feet), as well as more than 1 million lakes and reservoirs larger than 62,500 square meters (15 acres).
Taking inventory of Earth's water resources repeatedly over SWOT's three-year mission will enable researchers to better trace fluctuations in the planet's rivers and lakes during seasonal changes and significant weather events.
NASA's SWOT freshwater science lead, Tamlin Pavelsky, said collecting such data was akin to "taking the pulse of the world's water system, so we'll be able to see when it's racing and we'll be able to see when it's slow."
SWOT's radar instrument operates at the so-called Ka-band frequency of the microwave spectrum, allowing scans to penetrate cloud cover and darkness over vast swaths of the Earth. This enables scientists to accurately map their observations in two dimensions regardless of weather or time of day and to cover large geographic areas far more quickly than before.
By comparison, previous studies of water bodies relied on data taken at specific points, such as river or ocean gauges, or from satellites that can only track measurements along a one-dimensional line, requiring scientists to fill in data gaps through extrapolation.
"Rather than giving us a line of elevations, it's giving us a map of elevations, and that's just a total game changer," Pavelsky said.