From temblor: “How bad will a Hayward Fault earthquake actually be, and what you can do to protect yourself”
April 25, 2018
David Jacobson
This figure from the HayWired report shows the distribution of shaking caused by a Hayward Fault earthquake. What is evident in this figure is how the entire region is exposed to varying levels of shaking. Because of this, damage is estimated to far exceed $100 billion.
Last week the USGS released the second volume of the HayWired report, a scenario M=7.0 earthquake along the Hayward Fault. This volume focused on the impacts of the earthquake, which includes the estimated losses. Within this volume, two losses stood out, an estimated $82 billion in property and direct business losses, and up to $30 billion in fire damage. While $112 billion in losses sounds extreme, it pales in comparison to the $170 billion in direct damage the company CoreLogic projects.
There is no question that a large Hayward Fault earthquake will be devastating for the region. As it snakes through the East Bay, it cuts under properties, utility lines, and other important infrastructure. Because of this, some scientists describe it as a “tectonic time bomb.” However, until it happens we don’t know exactly how bad it will be. Therefore, having multiple estimates allows us to get a greater overall picture of what we should be prepared for, and also where we may be lacking in protection.
USGS and CoreLogic fire costs differ by a factor of 15
Under close examination of the loss estimates from both the USGS and CoreLogic, there are several differences that illustrate both the uncertainty of what could happen, and how a Hayward Fault earthquake could be much worse than what was outlined in HayWired. For example, the USGS states that the HayWired mainshock will trigger over 400 fires, leading to $30 billion in losses. CoreLogic on the other hand only gives $2 billion in fire losses. While it is true that fires wreaked havoc following the 1906 San Francisco Earthquake, CoreLogic states that large fires following earthquakes are rare and that commercial construction tends to be made of fire-resistant materials. Because of this, they chose to go with an average fire-following loss estimate.
Following the 1906 San Francisco earthquake fires ripped through the city. In calculating estimates for how much fire damage would be caused by a Hayward Fault earthquake, the USGS and CoreLogic used differing interpretations of this event to forecast what will likely happen in a future Bay Area earthquake.
In contrast, the USGS, used the 1906 fire as a reason why there are likely to be significant fire losses after a Hayward Fault earthquake. Additionally, they cite past fires in the Bay Area, and attribute hight winds to the potential rapid spread throughout the region. While both sides have their own methodologies for determining these losses, what is emphasized is that there is great error associated with these scientific models. Having said that, regardless of how damage is caused, a Hayward Fault earthquake will impact the region for decades.
This figure from the HayWired report shows the estimated losses from fires following a Hayward Fault earthquake. While the USGS estimates that there could be as much as $30 billion in fire losses, CoreLogic only estimates $2 billion.
USGS and CoreLogic damage costs differ by a factor of 3
Another startling number is that while the USGS estimates that the HayWired mainshock will produce $56 billion in direct building and contents damage, CoreLogic says there will be $140 billion in direct damage. Couple this with an additional $30 billion in losses from aftershocks, fires, and sprinkler leakage, and you get $170 billion in total losses, 20% of the regional GDP. Such a large discrepancy highlights how vulnerable the region could be following a large earthquake. For comparison, in the devastating earthquakes in Christchurch, New Zealand, which began on September 4, 2010 and lasted through December 2011, damage accounted for 25% of the regional GDP. More than seven years on, much of the city is still in repair, and it will likely never be the same.
However, in Christchurch, things were different, the majority of residents had help. In New Zealand, 90% of homeowners have earthquake insurance. While it is a tiered system, this meant that almost everyone received some financial help. In a HayWired earthquake, this will not be the case, as CoreLogic estimates that less than 8% of residential losses will be insured. This means that most Bay Area residents will be forced to cover their losses completely out of pocket. Such glaring numbers highlights the need for people to protect themselves from natural disasters. Whether this is through retrofitting or insurance is up to the individual, but what is extremely evident from these numbers is that a Hayward Fault earthquake may be much worse than what was outlined. However, this should not be seen as a doom and gloom scenario. Just like the HayWired report emphasized that losses are not set in stone, neither are these numbers. With proper preparedness, potential losses can be brought down and the region can recover faster following a large earthquake.
References
Detweiler, S.T., and Wein, A.M., eds., 2018, The HayWired earthquake scenario—Engineering implications: U.S. Geological Survey Scientific Investigations Report 2017–5013–I–Q, 429 p., https://doi.org/10.3133/sir20175013v2.
Charles Scawthorn, Fire following the HayWired scenario mainshock, in Detweiler, S.T., and Wein, A.M., eds., 2018, The HayWired earthquake scenario—Engineering implications: U.S. Geological Survey Scientific Investigations Report 2017–5013–I–Q, pp. 367-400.
Financial Implications of the HayWired Scenario, CoreLogic, April 2018 – Link
See the full article here .
Please help promote STEM in your local schools.
Earthquake Network project
Earthquake Network is a research project which aims at developing and maintaining a crowdsourced smartphone-based earthquake warning system at a global level. Smartphones made available by the population are used to detect the earthquake waves using the on-board accelerometers. When an earthquake is detected, an earthquake warning is issued in order to alert the population not yet reached by the damaging waves of the earthquake.
The project started on January 1, 2013 with the release of the homonymous Android application Earthquake Network. The author of the research project and developer of the smartphone application is Francesco Finazzi of the University of Bergamo, Italy.
Get the app in the Google Play store.
Smartphone network spatial distribution (green and red dots) on December 4, 2015
Meet The Quake-Catcher Network
The Quake-Catcher Network is a collaborative initiative for developing the world’s largest, low-cost strong-motion seismic network by utilizing sensors in and attached to internet-connected computers. With your help, the Quake-Catcher Network can provide better understanding of earthquakes, give early warning to schools, emergency response systems, and others. The Quake-Catcher Network also provides educational software designed to help teach about earthquakes and earthquake hazards.
After almost eight years at Stanford, and a year at CalTech, the QCN project is moving to the University of Southern California Dept. of Earth Sciences. QCN will be sponsored by the Incorporated Research Institutions for Seismology (IRIS) and the Southern California Earthquake Center (SCEC).
The Quake-Catcher Network is a distributed computing network that links volunteer hosted computers into a real-time motion sensing network. QCN is one of many scientific computing projects that runs on the world-renowned distributed computing platform Berkeley Open Infrastructure for Network Computing (BOINC).
The volunteer computers monitor vibrational sensors called MEMS accelerometers, and digitally transmit “triggers” to QCN’s servers whenever strong new motions are observed. QCN’s servers sift through these signals, and determine which ones represent earthquakes, and which ones represent cultural noise (like doors slamming, or trucks driving by).
There are two categories of sensors used by QCN: 1) internal mobile device sensors, and 2) external USB sensors.
Mobile Devices: MEMS sensors are often included in laptops, games, cell phones, and other electronic devices for hardware protection, navigation, and game control. When these devices are still and connected to QCN, QCN software monitors the internal accelerometer for strong new shaking. Unfortunately, these devices are rarely secured to the floor, so they may bounce around when a large earthquake occurs. While this is less than ideal for characterizing the regional ground shaking, many such sensors can still provide useful information about earthquake locations and magnitudes.
USB Sensors: MEMS sensors can be mounted to the floor and connected to a desktop computer via a USB cable. These sensors have several advantages over mobile device sensors. 1) By mounting them to the floor, they measure more reliable shaking than mobile devices. 2) These sensors typically have lower noise and better resolution of 3D motion. 3) Desktops are often left on and do not move. 4) The USB sensor is physically removed from the game, phone, or laptop, so human interaction with the device doesn’t reduce the sensors’ performance. 5) USB sensors can be aligned to North, so we know what direction the horizontal “X” and “Y” axes correspond to.
If you are a science teacher at a K-12 school, please apply for a free USB sensor and accompanying QCN software. QCN has been able to purchase sensors to donate to schools in need. If you are interested in donating to the program or requesting a sensor, click here.
BOINC is a leader in the field(s) of Distributed Computing, Grid Computing and Citizen Cyberscience.BOINC is more properly the Berkeley Open Infrastructure for Network Computing, developed at UC Berkeley.
Earthquake safety is a responsibility shared by billions worldwide. The Quake-Catcher Network (QCN) provides software so that individuals can join together to improve earthquake monitoring, earthquake awareness, and the science of earthquakes. The Quake-Catcher Network (QCN) links existing networked laptops and desktops in hopes to form the worlds largest strong-motion seismic network.
Below, the QCN Quake Catcher Network map
ShakeAlert: An Earthquake Early Warning System for the West Coast of the United States
The U. S. Geological Survey (USGS) along with a coalition of State and university partners is developing and testing an earthquake early warning (EEW) system called ShakeAlert for the west coast of the United States. Long term funding must be secured before the system can begin sending general public notifications, however, some limited pilot projects are active and more are being developed. The USGS has set the goal of beginning limited public notifications in 2018.
Watch a video describing how ShakeAlert works in English or Spanish.
The primary project partners include:
United States Geological Survey
California Governor’s Office of Emergency Services (CalOES)
California Geological Survey
California Institute of Technology
University of California Berkeley
University of Washington
University of Oregon
Gordon and Betty Moore Foundation
The Earthquake Threat
Earthquakes pose a national challenge because more than 143 million Americans live in areas of significant seismic risk across 39 states. Most of our Nation’s earthquake risk is concentrated on the West Coast of the United States. The Federal Emergency Management Agency (FEMA) has estimated the average annualized loss from earthquakes, nationwide, to be $5.3 billion, with 77 percent of that figure ($4.1 billion) coming from California, Washington, and Oregon, and 66 percent ($3.5 billion) from California alone. In the next 30 years, California has a 99.7 percent chance of a magnitude 6.7 or larger earthquake and the Pacific Northwest has a 10 percent chance of a magnitude 8 to 9 megathrust earthquake on the Cascadia subduction zone.
Part of the Solution
Today, the technology exists to detect earthquakes, so quickly, that an alert can reach some areas before strong shaking arrives. The purpose of the ShakeAlert system is to identify and characterize an earthquake a few seconds after it begins, calculate the likely intensity of ground shaking that will result, and deliver warnings to people and infrastructure in harm’s way. This can be done by detecting the first energy to radiate from an earthquake, the P-wave energy, which rarely causes damage. Using P-wave information, we first estimate the location and the magnitude of the earthquake. Then, the anticipated ground shaking across the region to be affected is estimated and a warning is provided to local populations. The method can provide warning before the S-wave arrives, bringing the strong shaking that usually causes most of the damage.
Studies of earthquake early warning methods in California have shown that the warning time would range from a few seconds to a few tens of seconds. ShakeAlert can give enough time to slow trains and taxiing planes, to prevent cars from entering bridges and tunnels, to move away from dangerous machines or chemicals in work environments and to take cover under a desk, or to automatically shut down and isolate industrial systems. Taking such actions before shaking starts can reduce damage and casualties during an earthquake. It can also prevent cascading failures in the aftermath of an event. For example, isolating utilities before shaking starts can reduce the number of fire initiations.
System Goal
The USGS will issue public warnings of potentially damaging earthquakes and provide warning parameter data to government agencies and private users on a region-by-region basis, as soon as the ShakeAlert system, its products, and its parametric data meet minimum quality and reliability standards in those geographic regions. The USGS has set the goal of beginning limited public notifications in 2018. Product availability will expand geographically via ANSS regional seismic networks, such that ShakeAlert products and warnings become available for all regions with dense seismic instrumentation.
Current Status
The West Coast ShakeAlert system is being developed by expanding and upgrading the infrastructure of regional seismic networks that are part of the Advanced National Seismic System (ANSS); the California Integrated Seismic Network (CISN) is made up of the Southern California Seismic Network, SCSN) and the Northern California Seismic System, NCSS and the Pacific Northwest Seismic Network (PNSN). This enables the USGS and ANSS to leverage their substantial investment in sensor networks, data telemetry systems, data processing centers, and software for earthquake monitoring activities residing in these network centers. The ShakeAlert system has been sending live alerts to “beta” users in California since January of 2012 and in the Pacific Northwest since February of 2015.
In February of 2016 the USGS, along with its partners, rolled-out the next-generation ShakeAlert early warning test system in California joined by Oregon and Washington in April 2017. This West Coast-wide “production prototype” has been designed for redundant, reliable operations. The system includes geographically distributed servers, and allows for automatic fail-over if connection is lost.
This next-generation system will not yet support public warnings but does allow selected early adopters to develop and deploy pilot implementations that take protective actions triggered by the ShakeAlert notifications in areas with sufficient sensor coverage.
Authorities
The USGS will develop and operate the ShakeAlert system, and issue public notifications under collaborative authorities with FEMA, as part of the National Earthquake Hazard Reduction Program, as enacted by the Earthquake Hazards Reduction Act of 1977, 42 U.S.C. §§ 7704 SEC. 2.
For More Information
Robert de Groot, ShakeAlert National Coordinator for Communication, Education, and Outreach
rdegroot@usgs.gov
626-583-7225
ShakeAlert Implementation Plan
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