Release Date: JUNE 11, 2018
Sluggishly-moving earthflows can help us learn what controls the starting and stopping of landslides.
Not all landslides occur as catastrophic events. Some creep along at a snail’s pace, stopping and starting, and not advancing more than 1 meter per year, and many of these are called earthflows. Earthflows are extremely common all over the world, in fact, they’re much more common than the fast-moving, deadly landslides. Since earthflows rarely cause loss of life, they are rarely in the news like their deadly counterparts, but they do cause a great deal of damage worldwide. Despite the fact that earthflows are so common, scientists still haven’t completely nailed down the reasons why they are so sluggish and sometimes move in fits and starts. USGS scientist Bill Schulz and engineer Joel Smith, and several colleagues from other institutions studied one of the thousands of earthflows in Northern California by the name of Two Towers to see if they could learn more about what controls its behavior.
The Two Towers earthflow is about 250m long, about 40m wide, and 7m deep and moves under 1m per year. It’s typical of many of the other earthflows in the area near Zenia, CA, and it was chosen for this study because it moves slowly, has a simple shape, and is small enough to accommodate the small number of instruments the researchers had available to dedicate to a multi-year study. Such a slow-moving landslide requires a long time and a lot of patience to collect adequate data for a study, and the team collected data for roughly 2-1/2 years from 2014 to 2017.
During this time, they collected hourly measurements of rainfall, landslide movement, landslide thickness changes, groundwater pressure, and swell pressure (the pressure exerted when the soil in the landslide expands, usually due to the presence of water). They also collected samples of the material (dirt) from the landslide to analyze in a laboratory. From these samples, they learned about the water content, the density, shear strength (how well the material holds together under pressure), type of landslide materials and minerals (most importantly the percentage of clay minerals), the shrink-swell amount, and the swell pressure.
Previous studies concluded that pore water pressure, or the pressure of water in the open spaces between the dirt particles in the landslide material, controlled landslide movement. If that were the case, it follows that one would expect the landslide to start moving when it contained enough water, and to move the fastest when it contained the most water. However, the data in this study showed that the timing and speed of the earthflow movement did not correlate with the amount of water. Instead, the initiation of movement was several months after the water amount peaked, and the peak speed occurred when the amount of water was decreasing. The previously mentioned lab analyses of the samples from the earthflow were essential in illuminating the reasons for this behavior.
The earthflow material contained a large amount of expansive clay. Clay swells when it has more water and shrinks when there is less water. The scientists hypothesized, from the correlation of the swell pressures measured in the laboratory and field with the earthflow movement, that the presence and amount of clay in the earthflow were connected to the timing and speed of the movements. When there was a large volume of water present, the clay expanded and exerted high pressure on the sides of the landslide, restricting the movement of the earthflow like when brakes are applied to a wheel. Then when the water volume decreased, the clay shrunk, decreasing the swell pressure and allowing the earthflow to accelerate.
All steep slopes may look the same, but they don’t behave the same. Some steep slopes have the potential to fail suddenly and quickly and cause loss of life, and other steep slopes are more lethargic and pose a lower safety hazard. Many factors that cause earthflow acceleration also affect other types of landslides, including those that move rapidly, so the findings from this study may have wide applicability. The results will also help identify which slopes pose the highest hazards.
-written by Lisa Wald
The Scientist Behind the Science
William "Bill" Schulz is an engineering geologist by training with a primary focus on landslides, which he's studied professionally since 1996. He's particularly interested in understanding controls on their speed and timing. "In my free time, I enjoy spending time with my family, running (but I'm very slow), racing my car to make up for my slow running speed (but only on racetracks!), hiking, and being outdoors. In fact, I suppose I started studying landslides as a child when I spent most of my time along the bluffs of Lake Michigan; I always knew when the debris-flow deposits would be fresh, deep and great for playing in!"
Release Date: JUNE 11, 2018
Sluggishly-moving earthflows can help us learn what controls the starting and stopping of landslides.
Not all landslides occur as catastrophic events. Some creep along at a snail’s pace, stopping and starting, and not advancing more than 1 meter per year, and many of these are called earthflows. Earthflows are extremely common all over the world, in fact, they’re much more common than the fast-moving, deadly landslides. Since earthflows rarely cause loss of life, they are rarely in the news like their deadly counterparts, but they do cause a great deal of damage worldwide. Despite the fact that earthflows are so common, scientists still haven’t completely nailed down the reasons why they are so sluggish and sometimes move in fits and starts. USGS scientist Bill Schulz and engineer Joel Smith, and several colleagues from other institutions studied one of the thousands of earthflows in Northern California by the name of Two Towers to see if they could learn more about what controls its behavior.
The Two Towers earthflow is about 250m long, about 40m wide, and 7m deep and moves under 1m per year. It’s typical of many of the other earthflows in the area near Zenia, CA, and it was chosen for this study because it moves slowly, has a simple shape, and is small enough to accommodate the small number of instruments the researchers had available to dedicate to a multi-year study. Such a slow-moving landslide requires a long time and a lot of patience to collect adequate data for a study, and the team collected data for roughly 2-1/2 years from 2014 to 2017.
During this time, they collected hourly measurements of rainfall, landslide movement, landslide thickness changes, groundwater pressure, and swell pressure (the pressure exerted when the soil in the landslide expands, usually due to the presence of water). They also collected samples of the material (dirt) from the landslide to analyze in a laboratory. From these samples, they learned about the water content, the density, shear strength (how well the material holds together under pressure), type of landslide materials and minerals (most importantly the percentage of clay minerals), the shrink-swell amount, and the swell pressure.
Previous studies concluded that pore water pressure, or the pressure of water in the open spaces between the dirt particles in the landslide material, controlled landslide movement. If that were the case, it follows that one would expect the landslide to start moving when it contained enough water, and to move the fastest when it contained the most water. However, the data in this study showed that the timing and speed of the earthflow movement did not correlate with the amount of water. Instead, the initiation of movement was several months after the water amount peaked, and the peak speed occurred when the amount of water was decreasing. The previously mentioned lab analyses of the samples from the earthflow were essential in illuminating the reasons for this behavior.
The earthflow material contained a large amount of expansive clay. Clay swells when it has more water and shrinks when there is less water. The scientists hypothesized, from the correlation of the swell pressures measured in the laboratory and field with the earthflow movement, that the presence and amount of clay in the earthflow were connected to the timing and speed of the movements. When there was a large volume of water present, the clay expanded and exerted high pressure on the sides of the landslide, restricting the movement of the earthflow like when brakes are applied to a wheel. Then when the water volume decreased, the clay shrunk, decreasing the swell pressure and allowing the earthflow to accelerate.
All steep slopes may look the same, but they don’t behave the same. Some steep slopes have the potential to fail suddenly and quickly and cause loss of life, and other steep slopes are more lethargic and pose a lower safety hazard. Many factors that cause earthflow acceleration also affect other types of landslides, including those that move rapidly, so the findings from this study may have wide applicability. The results will also help identify which slopes pose the highest hazards.
-written by Lisa Wald
The Scientist Behind the Science
William "Bill" Schulz is an engineering geologist by training with a primary focus on landslides, which he's studied professionally since 1996. He's particularly interested in understanding controls on their speed and timing. "In my free time, I enjoy spending time with my family, running (but I'm very slow), racing my car to make up for my slow running speed (but only on racetracks!), hiking, and being outdoors. In fact, I suppose I started studying landslides as a child when I spent most of my time along the bluffs of Lake Michigan; I always knew when the debris-flow deposits would be fresh, deep and great for playing in!"