Groundwater irrigation enables farmers to grow lush crops in California’s Central Valley, but the underground water resource is dwindling. A NASA study offers a new tool for managing groundwater. Credits: California Department of Water Resources/Dale Kolke
Researchers have untangled puzzling patterns of sinking and rising land to
pin down the underground locations where water is being pumped for irrigation.
Scientists have produced a new method that holds the promise of improving
groundwater management – critical to both life and agriculture in dry regions.
The method sorts out how much underground water loss comes from aquifers
confined in clay, which can be drained so dry that they will not recover, and
how much comes from soil that’s not confined in an aquifer, which can be
replenished by a few years of normal rains.
The research team studied California’s Tulare Basin, part of the Central
Valley. The team found that the key to distinguishing between these underground
sources of water relates to patterns of sinking and rising ground levels in
this heavily irrigated agricultural region.
The Central Valley makes up only 1% of U.S. farmland, yet it grows an amazing
40% of the nation’s table fruits, vegetables, and nuts annually. Productivity
like that is only possible because farmers augment the valley’s 5 to 10 inches
(12 to 25 centimeters) of annual rainfall with extensive groundwater pumping.
In drought years, more than 80% of irrigation water comes from underground.
After decades of pumping, underground water resources are dwindling. Wells
in the Tulare Basin now must be drilled as much as 3,500 feet (over 1,000
meters) deep to find adequate water. There’s no way to measure exactly how much
water remains underground, but managers need to make the wisest use of whatever
there is. That involves monitoring whether water is being drawn from aquifers
or from loose soil, known as the water table. In this large region with tens of
thousands of unmetered wells, the only practical way to do that is by using
satellite data.
This map shows changes
in the mass of water, both above ground and underground, in California from
2003 to 2013, as measured by NASA’s GRACE satellite. The darkest red indicates
the greatest water loss. The Central Valley is outlined in yellow; the Tulare
Basin covers about the southern third. Extreme groundwater depletion has
continued to the present. Credits: NASA/GSFC/SVS
A research team from NASA’s Jet Propulsion Laboratory in Southern
California and the U.S. Department of Energy’s Lawrence Berkeley Laboratory in
Northern California set out to create a method that would do exactly that. They
attacked the problem by combining data on water loss from NASA’s Gravity Recovery and
Climate Experiment (GRACE) and GRACE Follow-On satellites with
data on ground-level changes from a ESA (European Space Agency) Sentinel-1
satellite. Ground-level changes in this region are often related to water loss
because when ground is drained of water, it eventually slumps together and
sinks into the spaces where water used to be – a process called subsidence.
The Tulare Basin is subsiding drastically: The current rate is about one
foot (0.3 meters) of sinkage per year. But from one month to the next, the
ground may drop, rise or stay the same. What’s more, these changes don’t always
line up with expected causes. For example, after a heavy rainfall, the water
table rises. It seems obvious that this would cause the ground level to rise,
too, but it sometimes sinks instead.
The researchers thought these mysterious short-term variations might hold
the key to determining the sources of pumped water. “The main question was, how
do we interpret the change that’s happening on these shorter time scales: Is it
just a blip, or is it important?” said Kyra Kim, a postdoctoral fellow at JPL
and coauthor of the paper, which appeared in
Scientific Reports.
Clay vs. Sand
Kim and her colleagues believed the changes were related to the different
kinds of soils in the basin. Aquifers are confined by layers of stiff,
impermeable clay, whereas unconfined soil is looser. When water is pumped from
an aquifer, the clay takes a while to compress in response to the weight of
land mass pressing down from above. Unconfined soil, on the other hand, rises
or falls more quickly in response to rain or pumping.
The researchers created a simple numerical model of these two layers of
soils in the Tulare Basin. By removing the long-term subsidence trend from the
ground-level-change data, they produced a dataset of only the month-to-month
variations. Their model revealed that on this time scale, virtually all of the
ground-level change can be explained by changes in aquifers, not in the water
table.
For example, in spring, there’s little rainfall in the Central Valley, so
the water table is usually sinking. But runoff from snow in the Sierra Nevada is
recharging the aquifers, and that causes the ground level to rise. When
rainfall is causing the water table to rise, if the aquifers are compressing at
the same time from being pumped during the preceding dry season, the ground
level will fall. The model correctly reproduced the effects of weather events
like heavy rainfalls in the winter of 2016-17. It also matched the small amount
of available data from wells and GPS.
Kim
pointed out that the new model can be repurposed to represent other
agricultural regions where groundwater use needs to be better monitored. With a
planned launch in 2023, the NASA-ISRO (Indian Space Research Organisation)
Synthetic Aperture Radar (NISAR) mission will measure
changes in ground level at even higher resolution than Sentinel-1. Researchers
will be able to combine NISAR’s dataset with data from GRACE Follow-On in this
model for the benefit of agriculture around the globe. “We’re heading toward a
really beautiful marriage between remote sensing and numerical models to bring
everything together,” Kim said.
Jane J. Lee / Andrew Wang
Jet Propulsion Laboratory, Pasadena, Calif.
Written by Carol Rasmussen
Source: NASA Finds New Way to Monitor Underground Water Loss | NASA
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