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Lost and Found: The 1906 Earthquake Rupture in Portola Valley

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Geologic maps look as solid as the ground itself, with their crisp lines and firmly colored bedrock units. But geologists face the same bewildering world as the rest of us. Although they can see and visualize the bones of the land better than we can, mapping geology is as much a creative, interpretive act as an observational one. A paper in the current Bulletin of the Seismological Society of America brings that home with a fresh look at a hundred years of geologic mapping in a high-stakes neighborhood: the leafy suburban town of Portola Valley, where the San Andreas fault tore the land apart in 1906.

The great earthquake of April 18, 1906 was intensively studied by Bay Area geologists who were present in large numbers at UC Berkeley and Stanford University. Once the rubble at Stanford was under control, Professor John C. Branner and his students fanned out into the nearby foothills to document the fresh fault ruptures there. Branner compiled the results on a map and submitted it to Professor Andrew Lawson at UC Berkeley, who was preparing a master report funded by the Carnegie Commission. The work went on, the Stanford people went back to their lives and studies and Lawson’s “Carnegie Report” was issued in 1908.

Branner's 1906 map

J. C. Branner’s original master map of the 1906 fault rupture in Portola Valley, now at the Bancroft Library. Images from BSSA paper by Wrucke et al.

The Carnegie Report has stood for more than a century as a monument in seismology. It was the first and last word on the fault for many years. In fact, geologists did not return to the fault in Portola Valley for another fifty years. When they did, things began to get fuzzy. Roads had been rebuilt, buildings replaced, earth moved and trees planted as the open farmlands turned to wooded suburbs. With the 1906 rupture long smoothed over, the new geologic mappers relied on the landscape as well as the Carnegie Report to reconstruct the fault as best they could. Subtle features, perhaps thousands of years old, were added to the fault—sometimes as older or secondary fault traces, sometimes as the active trace. A body of research, much of it unpublished, began to grow. New maps modified old ones, and each new mapper made fresh modifications.

Alpine Road 1906

Alpine Road in 1906, above, and the same view today, below.

Alpine Road 2013

Photo by Andrew Alden

Along with the science, the laws grew up around the fault. The 1972 Alquist-Priolo Act required all active faults in the state to be mapped and construction-free zones set up around them. With that, the exact location of an active fault trace became a crucial matter in real estate. Trenching studies were done for new construction projects, some of which found the fault and some of which didn’t. Discrepancies and interpretations continued to multiply, and the fault turned into a tangle of lines on geologic maps.

By the turn of this century, it was clear that someone needed to take the whole thing again from the top, reanalyzing the original materials and assessing all the literature. How was the fault lost? Where did it really rupture in 1906? The job would take time, persistence and the judgment of a seasoned researcher. That’s what retired geologists are good for, and Chet Wrucke, emeritus scientist at the U.S. Geological Survey, happens to live in Portola Valley. He had access to the 1906 archives plus a new lidar map of the area showing the ground stripped bare.

Wrucke found that errors began with the Carnegie Report itself: Branner’s map was used in two different published maps. The first one was accurate but looked preliminary while the second was inaccurate but looked finished.

1908 fault maps

Map 4 (left) used a topographic base with no other features while map 22 (right) put the fault about 80 meters west. Later mappers relied on the fancy-looking map.

As he followed the literature he found more misinterpretations. Branner’s own notes were confusing, and some photographs from 1906 were later published reversed. Wrucke demonstrated this in one example by showing that a man’s suit had the buttons on the wrong side.

Once the photos were put in their correct places, the fault trace was easy to find, even on today’s landscape, with the lidar images. (I showed you another example in nearby Los Trancos last year.) It must have been especially satisfying for Wrucke to unveil Coal Mine Ridge, which is thickly carpeted with brush and poison oak, and see the 1906 trace running clearly up the hill.

Lidar image

The hummocky landslide surface shows that the fault trace crossing it (features marked “B”) must be very recent.

It’s unfortunate that it took a century to make things right. But lidar surveys were used to great effect after the 2010 Baja California earthquake, and the tool will be ready when the San Andreas lets loose again.

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Category: Geology

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About the Author ()

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.