SCIENTISTS REPORT CALIFORNIA GROUNDWATER DEPLETION MAY INCREASE EARTHQUAKE RISK

FROM:  NATIONAL SCIENCE FOUNDATION 

California Central Valley groundwater depletion slowly raises Sierra Nevada mountains

Changes may trigger small earthquakes, scientists find

Winter rains and summer groundwater pumping in California's Central Valley make the Sierra Nevada and Coast Mountain Ranges sink and rise by a few millimeters each year, creating stress on the state's faults that could increase the risk of an earthquake.

Gradual depletion of the Central Valley aquifer, because of groundwater pumping, also raises these mountain ranges by a similar amount each year--about the thickness of a dime--with a cumulative rise over the past 150 years of up to 15 centimeters (6 inches), according to calculations by a team of geophysicists.

The scientists report their results in this week's issue of the journal Nature.

While the seasonal changes in the Central Valley aquifer have not yet been firmly associated with any earthquakes, studies have shown that similar levels of periodic stress, such as that caused by the motions of the moon and sun, increase the number of microquakes on the San Andreas Fault.

If these subtle seasonal load changes are capable of influencing the occurrence of microquakes, it's possible that they can sometimes also trigger a larger event, said Roland Bürgmann, a geoscientist at the University of California, Berkeley and co-author of the Nature paper.

"The stress is very small, much less than you need to build up stress on a fault leading to an earthquake, but in some circumstances such small stress changes can be the straw that breaks the camel's back," Bürgmann said. "It could just give that extra push to get a fault to fail."

The study, based on GPS measurements from California and Nevada between 2007 and 2010, was led by scientists Colin Amos at Western Washington University and Pascal Audet of the University of Ottawa.

The detailed GPS analyses were performed by William Hammond and Geoffrey Blewitt of the University of Nevada, Reno, as part of a National Science Foundation (NSF) grant. Hammond and Blewitt, along with Amos and Audet, are also co-authors of this week's paper.

"Other studies have shown that the San Andreas Fault is sensitive to small-scale changes in stress," said Amos.

"These appear to control the timing of small earthquakes on portions of the fault, leading to more small earthquakes during drier periods of the year. Previously, such changes were thought to be driven by rainfall and other hydrologic causes."

This work ties overuse of groundwater by humans in the San Joaquin Valley to increases in the height of nearby mountain ranges and possible increases in the number of earthquakes on the San Andreas Fault, said Maggie Benoit, program director in NSF's Division of Earth Sciences, which funded the research.

"When humans deplete groundwater," said Benoit, "the amount of mass or material in Earth's crust is reduced. That disrupts Earth's force balances, causing uplift of nearby mountains and reducing a force that helps keep the San Andreas fault from slipping."

Draining of the Central Valley

Water has been pumped from California's Central Valley for more than 150 years, changing what used to be a marsh and extensive lake, Tulare Lake, into fertile agricultural fields.

In that time, about 160 cubic kilometers (40 cubic miles) of water was removed--the capacity of Lake Tahoe--dropping the water table in some areas more than 120 meters (400 feet) and the ground surface 5 meters (16 feet) or more.

The weight of water removed allowed the underlying crust or lithosphere to rise by so-called isostatic rebound, which may have raised the Sierra as much as half a foot since about 1860.

The same rebound happens as a result of the state's seasonal rains.

Torrential winter storms drop water and snow across the state, which eventually flow into Central Valley streams, reservoirs and underground aquifers, pushing down the crust and lowering the Sierra 1-3 millimeters.

In the summer, water flow into the Pacific Ocean, evaporation and ground water pumping for irrigation, which has accelerated because of drought, allows the crust and surrounding mountains to rise again.

Bürgmann said that the flexing of Earth's crust downward in winter would clamp the San Andreas fault tighter, lowering the risk of quakes, while in summer the upward flexure would relieve this clamping and perhaps increase the risk.

"The hazard is ever so slightly higher in the summer than in the wintertime," he said. "This suggests that climate and tectonics interact, and that water changes ultimately affect the deeper Earth."

High-resolution mapping with continuous GPS

Millimeter-precision measurements of elevation have been possible only in the last few years. Improved continuous GPS networks--part of the NSF EarthScope Plate Boundary Observatory, which operates 1,100 stations around the western United States--and satellite-based interferometric synthetic aperture radar have provided the data.

The measurements revealed a steady yearly rise of the Sierra of 1-2 millimeters per year, which was initially ascribed to tectonic activity deep underground, even though the rate was unusually high.

The new study provides an alternative and more reasonable explanation for the rise of the Sierra in historic times.

"The Coast Range is doing the same thing as the Sierra Nevada, which is part of the evidence that this can't be explained by tectonics," Bürgmann said.

"Both ranges have uplifted over the last few years and both exhibit the same seasonal up and down movement in phase. This tells us that something has to be driving the system at a seasonal and long-term sense, and that has to be groundwater recharging and depletion."

In response to the current drought, about 30 cubic kilometers (7.5 cubic miles) of water has been removed from Central Valley aquifers between 2003 and 2010, causing a rise of about 10 millimeters (2/5 inch) in the Sierra over that time.

-NSF-



Media Contacts
Cheryl Dybas, NSF

HOW ROCKS AND TREES COMMUNICATE IN SIERRA NEVADA

FROM:  NATIONAL SCIENCE FOUNDATION 
Granite bedrock and sequoia forests 'communicate' in the Sierra Nevada
Research reveals the coevolution of life and landscapes

If a tree falls in the forest and no one is around to hear it, does it make a sound? If it lands on granite bedrock, it does. But beyond the crash of timber onto rock, scientists have found that bedrock and the trees that grow from its weathered soils are, in a sense, communicating.

Bedrock influences forests--and the landscapes of which they are a part--more than was thought, according to researchers funded through the National Science Foundation (NSF) Critical Zone Observatories (CZO) network.

The scientists investigated the factors that influence forest cover in California's Sierra Nevada. Bedrock may be as important as temperature and moisture, they found, in regulating the distribution of trees and other vegetation across mountain slopes.

Geoscientists Cliff Riebe, Jesse Hahm, Claire Lukens and Sayaka Araki of the University of Wyoming recently published results of their study in the journal Proceedings of the National Academy of Sciences (PNAS).

Bedrock and trees in the critical zone

The research took place at the Southern Sierra CZO, one of ten NSF CZOs funded to unearth the secrets of Earth's critical zone.

Critical zone research looks at how water, life, rock and air interact from the base of the soil to the top of the vegetation canopy.

"The CZOs are providing scientists with new knowledge of the critical zone and its response to climate and land-use change," says Enriqueta Barrera, a program director in NSF's Division of Earth Sciences, which funds the CZO network.

"They're the first systems-based observatories dedicated to understanding how Earth's surface processes are coupled," says Barrera. "The results will help us predict how the critical zone affects the ecosystem services on which society depends."

The water cycle, the breakdown of rocks and eventual formation of soil, the evolution of rivers and valleys, patterns of plant growth and landforms that people see all result from processes that take place in the critical zone.

CZO scientists are investigating the integration and coupling of Earth surface processes, and how they are affected by the presence of fresh water.

The researchers are using field and analytical methods, space-based remote sensing and theoretical techniques.

The CZOs add to the environmental sensor networks in place and planned by NSF, including EarthScope, the National Ecological Observatory Network and the Ocean Observatories Network.

Scientists have known that the critical zone is a complex system in which different components interact at various space and time scales, and in which the rates of processes depend on the nature of those interactions.

Until now, however, researchers have looked at the components individually, especially in the field. The CZOs allow for investigation of the critical zone as a holistic system, rather than as isolated parts.

NSF CZOs are located in watersheds in the Southern Sierra Nevada; Boulder Creek in the Colorado Rockies; Susquehanna Shale Hills in Pennsylvania; Christina River Basin on the border of Delaware and Pennsylvania; Luquillo riparian zone in Puerto Rico; Jemez River and Santa Catalina Mountains in New Mexico and Arizona; Piedmont region of South Carolina; Reynolds Creek in Southwest Idaho; Eel River in Northern California; and linked Illinois, Iowa and Minnesota watersheds.

Composition of bedrock limits plant growth

The Southern Sierra CZO is home to extensive forests and huge exposures of granite bedrock.

"We were puzzled by the patchiness of vegetation on mountain slopes," Hahm says. "Densely forested areas are right next to places with little or no trees and soil.

"Strikingly, these bare areas sometimes occur side-by-side with groves of the largest trees on Earth, giant sequoias."

The researchers determined that bedrock composition acts to limit plant growth.

"Unexpectedly, we found that differences in bedrock composition are just as important in this ecosystem as climate," Riebe says. "That's hard to see without spatial analysis tools and integrated datasets on how vegetation and bedrock change across the landscape."

Plants get some of their nutrients from weathering of minerals as bedrock breaks down into soil. Granite rock, it turns out, contains plant-essential nutrients such as phosphorus.

"The results are important because they demonstrate that bedrock geochemistry is on par with climate as a regulator of vegetation in the Sierra Nevada--and likely in other granite mountain ranges around the world," Riebe says.

Geology of 100 million years ago linked with biology of today

Subtle differences in the cooling history of granite 100 million years ago are likely fueling the biogeochemical interactions that produce today's forest patterns.

Understanding these links is at the heart of critical zone science, says Riebe.

The findings also show that variations in forest cover correspond with differences in erosion rates. They appear to affect the pace at which the Sierra Nevada is wearing down due to the action of water, wind and biological processes.

The results will help efforts to learn how mountain forests are responding to climate-linked changes in temperature and precipitation.

"Most studies point to a shift in vegetation toward higher, cooler elevations," Riebe says. "But changes in climate may be just part of the story.

"Any changes in tree distribution will occur only with the consent of the underlying bedrock."

In the Sierra Nevada, rock meets life meets rock. Or life meets rock meets life.

-- Cheryl Dybas, NSF (703) 292-7734 cdybas@nsf.gov
Investigators
Jan Hopmans
Roger Bales
Martha Conklin
Christina Tague
Michael Goulden
Related Institutions/Organizations
University of California - Merced