How Oil and Gas Production Triggers Earthquakes in California

The Tejon Oil Field, at the southernmost end of the Great Valley, was the site of an earthquake swarm apparently triggered by wastewater injection in September 2005. (Wayne Hsieh/Flickr)

California has already lost its distinction as the nation’s seismic hotspot.

Recently Oklahoma unseated the Golden State as Earthquake Central — but it won on a technicality. Oklahoma, a place where natural quakes are rare, is plagued by artificial earthquakes caused by oilfield activities.

Now research suggests that California, once thought to be free of this kind of “frackquake,” has been having them for years.

Oklahoma literally has hundreds of earthquakes each year, large enough to feel, triggered by pumping oilfield wastewater into deep disposal wells. Last week a damaging magnitude 5.1 shaker near Fairview was the third-largest earthquake in Oklahoma’s history. Everyone assumes it was a triggered quake, and state regulators have ordered disposal well operators to cut back.

California is a huge oil-producing state with as many deep disposal wells as Oklahoma. Why aren’t we having the same problems? UC Santa Cruz researcher Thomas Goebel suggests that, in fact, we do have induced earthquakes here. His latest paper, in the journal Geophysical Research Letters, is a detailed study of an earthquake swarm that occurred beneath the Tejon Oil Field south of Bakersfield on September 22, 2005.

Deep injection of oilfield wastewater into rock known as the Arbuckle formation has triggered multiple earthquakes in Oklahoma.
Deep injection of oilfield wastewater into a layer known as the Arbuckle formation has triggered multiple earthquakes in Oklahoma. (Steven Than/Stanford University)

Disposal wells pump waste fluids — salty water from oil reservoirs, mostly — into deeply buried beds of rock that have lots of pore space. Most of these thousands of wells cause no problems.

Think of a group of people boarding a train car that’s already full of passengers — they cause a “pressure wave” that pushes people back down the aisles until everyone has a place. If there’s a pile of luggage in the way, tempers might start to flare.

Likewise, the high-pressure wastewater spreading out from the well can sometimes lubricate ancient faults, allowing them to relieve some of their old pent-up stress as “induced earthquakes.” (Hence the term, “frackquake” is a bit of a misnomer, as it’s not the fracking process itself but re-injection of drilling wastewater that causes tremors.)

We know all this because Oklahoma is in a part of the country that historically has been pretty quiet, seismically speaking, so quake data is less likely to be muddled by natural events. Evidence from its booming oil industry, involving thousands of earthquakes and about 10,000 disposal wells, has shown scientists how induced earthquakes work.

Maricopa pumpjacks
Pumpjacks south of Maricopa are in the Sunset Oil Field. Petroleum basins in the San Joaquin Valley and the Los Angeles region may be prone to occasional “frackquakes” from wastewater disposal wells. (Andrew Alden/KQED)

In quake-rich California nobody pays much attention to an extra shock or two. But last year, when Goebel ran some statistical tests on the earthquake record here, he found several earthquake clusters that coincided with high-volume wastewater pumping. The odds that these coincidences were random were less than 1 in 25.

Goebel zeroed in on the so-called Mettler earthquake cluster of September 2005, which produced three shocks larger than magnitude 4. The cluster was very close to the White Wolf fault, which was responsible for one of California’s largest earthquakes on July 21, 1952. Five months earlier, a big new disposal well had opened up in the Tejon Oil Field about five miles away.

Gathering more evidence from newly refined earthquake catalogs and well injection data kept by the state, Goebel traced the effect of the new well in the months before the swarm. During that time a trail of small quakes led from the well toward the White Wolf fault, along the trace of another small fault named the Tejon fault.

When the quake activity reached the White Wolf fault, the Mettler cluster occurred, including three shocks between magnitude 4.3 and 4.6. After the swarm, Goebel saw seismic activity continue on the Tejon fault as more pumping went on.

Goebel’s next step was to gather the best information he could find on the rock layers in the area, then run a computer simulation of how wastewater injection would behave in them. The results were a decent match to the record: the pumping would raise the underground pressure by about 1.5 pounds per square inch, enough to push a fault to failure, and the timing was right too.

This was cutting-edge scientific work that relied on excellent seismic records, an area with well-known geology, and earthquakes of appreciable size. Goebel concludes that earthquakes caused by wastewater injection probably have a “marginal” effect in California.

“However, considering the numerous active faults in California,” he adds, “the seismogenic consequences of even a few induced cases can be devastating.”

Author

Andrew Alden

Andrew Alden earned his geology degree at the University of New Hampshire and moved back to the Bay Area to work at the U.S. Geological Survey for six years. He has written on geology for About.com since its founding in 1997. In 2007, he started the Oakland Geology blog, which won recognition as "Best of the East Bay" from the East Bay Express in 2010. In writing about geology in the Bay Area and surroundings, he hopes to share some of the useful and pleasurable insights that geologists give us—not just facts about the deep past, but an attitude that might be called the deep present.

Read his previous contributions to QUEST, a project dedicated to exploring the Science of Sustainability.

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