The USGS warning system that knows when rumbling volcanoes will blow their mountain tops

More than 120 volcanic eruptions have occurred in the United States in the 42 years since Mount St. Helens erupted over Washington in 1980, killing 57 and inflicting over a billion dollars in property damage. While none have been nearly as destructive, their mere presence can impact human activities and even economies hundreds of miles away. Altogether the US Geological Survey (USGS) has identified 161 geologically active volcanoes in 14 states and territories, a third of which constitute “high” or “very high” threats to their surrounding communities, and another 58 volcanoes nationwide classified as being undermonitored. The agency operates five volcano monitoring stations along the west coast to keep an eye on all but the least dangerous as part of the Survey’s Volcano Hazards Program. On average, around 60 volcanoes erupt annually, as Hawaii’s Mauna Loa is doing right now.

Mauna Loa, which had stood dormant for the past 38 years, reawakened late Sunday night for the eighth time since 1843. “Lava flows are not threatening any downslope communities and all indications are that the eruption will remain in the Northeast Rift Zone,” reads Monday’s red alert update from the USGS Hawaiian Volcano Observatory (HVO). “Volcanic gas and possibly fine ash and Pele's Hair may be carried downwind. Residents at risk from Mauna Loa lava flows should review preparedness and refer to Hawai‘i County Civil Defense information for further guidance.” This week’s eruption is decidedly mild compared to 2018’s Kīlauea Volcano event that destroyed 700 homes and launched ash 3,000 meters into the atmosphere, where it disrupted air traffic patterns.

While lava receives a majority of the public attention, volcanoes have myriad methods for ruining your week with fire and (literal) brimstone. Volcanic ash can travel miles into the stratosphere before raining back down where it exacerbates chronic lung diseases like asthma and emphysema; carbon dioxide and hydrogen sulfide collect in low-lying areas to suffocate the unwary and seismic shifts resulting from the initial explosion can trigger landslides, tsunamis, floods, and large-scale power outages.

“Unlike many other natural disasters … volcanic eruptions can be predicted well in advance of their occurrence if adequate in-ground instrumentation is in place that allows earliest detection of unrest, providing the time needed to mitigate the worst of their effects,” David Applegate, USGS associate director for natural hazards, told a House subcommittee in 2017.

As Eos magazine points out, nobody died as a result of the 2018 Kīlauea eruption, in large part due to the efforts of monitors at the HVO. But, a 2018 threat assessment found that, out of the 18 volcanoes listed as “very high” threat, only three — Mauna Loa, St Helens and the Long Valley Caldera — were rated as “well monitored” when that eruption was happening.

On the same day that Kīlauea blew its top, the US Senate unanimously passed S.346, establishing the National Volcano Early Warning and Monitoring System (NVEWS). The following March, the House of Representatives passed its version, PL 116-9/S.47, dubbed the John D. Dingell Jr. Conservation, Management, and Recreation Act. Not unlike California’s new ShakeAlert early earthquake warning scheme, the NVEWS works to combine and standardize the existing hodgepodge of (often outdated) volcano monitoring hardware operated by both government agencies and academic organizations into a unified system, “to ensure that the most hazardous volcanoes will be properly monitored well in advance of the onset of activity.”

A clipart picture of a stylized voplcano surrounded by cameras, seismic, GOPS, tiltmeter and thermal imaging sensors
USGS

“Improvements to volcano monitoring networks allow the USGS to detect volcanic unrest at the earliest possible stage,” Tom Murray, USGS Volcano Science Center director, said in a 2018 USGS release. “This provides more time to issue forecasts and warnings of hazardous volcanic activity and gives at-risk communities more time to prepare.”

The NVEWS Act, which was sponsored by Senator Lisa Murkowski (R - AK), earmarks $55 million annually between 2019 and 2023 to provide more accurate and timely eruption forecasts by increasing partnerships with local governments and proactively sharing data with the volcano science community. It also seeks to increase staffing and systems — from broadband seismometers, infrasound arrays, and real-time continuous GPS receivers, to streaming webcams, satellite overwatch and volcanic gas sensors — for 24/7 volcano monitoring and establishes a grant system for furthering volcanology research.

lots of words and numbers
USGS

The USGS ranks volcanic threats based on the risk they pose to public health and property — essentially how potentially destructive the volcano itself is in relation to how many people and things might be impacted when it does erupt. The USGS assigns numerical values to the 24 various hazard and exposure factors for each volcano, then combined to calculate the overall threat score which is divided into five levels (like DEFCONs!). High and Very High get the most detailed monitoring coverage because duh, Moderate threat volcanoes still receive real-time monitoring but don’t have Tommy Lee Jones standing by to intercede, and Low (and Very Low) get checked on as needed. As of May 2022, when the USGS submitted its second annual NVEWS report to Congress, the USGS had spent just under half of the money appropriated for FY 2021 with the funds going to activities like installing a net-gen lahar detection system on Mount Rainier, upgrading the telemetry for more than two dozen observation posts throughout Alaska, Oregon, Washington, California and Hawaii.

The USGS warning system that knows when rumbling volcanoes will blow their mountain tops

More than 120 volcanic eruptions have occurred in the United States in the 42 years since Mount St. Helens erupted over Washington in 1980, killing 57 and inflicting over a billion dollars in property damage. While none have been nearly as destructive, their mere presence can impact human activities and even economies hundreds of miles away. Altogether the US Geological Survey (USGS) has identified 161 geologically active volcanoes in 14 states and territories, a third of which constitute “high” or “very high” threats to their surrounding communities, and another 58 volcanoes nationwide classified as being undermonitored. The agency operates five volcano monitoring stations along the west coast to keep an eye on all but the least dangerous as part of the Survey’s Volcano Hazards Program. On average, around 60 volcanoes erupt annually, as Hawaii’s Mauna Loa is doing right now.

Mauna Loa, which had stood dormant for the past 38 years, reawakened late Sunday night for the eighth time since 1843. “Lava flows are not threatening any downslope communities and all indications are that the eruption will remain in the Northeast Rift Zone,” reads Monday’s red alert update from the USGS Hawaiian Volcano Observatory (HVO). “Volcanic gas and possibly fine ash and Pele's Hair may be carried downwind. Residents at risk from Mauna Loa lava flows should review preparedness and refer to Hawai‘i County Civil Defense information for further guidance.” This week’s eruption is decidedly mild compared to 2018’s Kīlauea Volcano event that destroyed 700 homes and launched ash 3,000 meters into the atmosphere, where it disrupted air traffic patterns.

While lava receives a majority of the public attention, volcanoes have myriad methods for ruining your week with fire and (literal) brimstone. Volcanic ash can travel miles into the stratosphere before raining back down where it exacerbates chronic lung diseases like asthma and emphysema; carbon dioxide and hydrogen sulfide collect in low-lying areas to suffocate the unwary and seismic shifts resulting from the initial explosion can trigger landslides, tsunamis, floods, and large-scale power outages.

“Unlike many other natural disasters … volcanic eruptions can be predicted well in advance of their occurrence if adequate in-ground instrumentation is in place that allows earliest detection of unrest, providing the time needed to mitigate the worst of their effects,” David Applegate, USGS associate director for natural hazards, told a House subcommittee in 2017.

As Eos magazine points out, nobody died as a result of the 2018 Kīlauea eruption, in large part due to the efforts of monitors at the HVO. But, a 2018 threat assessment found that, out of the 18 volcanoes listed as “very high” threat, only three — Mauna Loa, St Helens and the Long Valley Caldera — were rated as “well monitored” when that eruption was happening.

On the same day that Kīlauea blew its top, the US Senate unanimously passed S.346, establishing the National Volcano Early Warning and Monitoring System (NVEWS). The following March, the House of Representatives passed its version, PL 116-9/S.47, dubbed the John D. Dingell Jr. Conservation, Management, and Recreation Act. Not unlike California’s new ShakeAlert early earthquake warning scheme, the NVEWS works to combine and standardize the existing hodgepodge of (often outdated) volcano monitoring hardware operated by both government agencies and academic organizations into a unified system, “to ensure that the most hazardous volcanoes will be properly monitored well in advance of the onset of activity.”

A clipart picture of a stylized voplcano surrounded by cameras, seismic, GOPS, tiltmeter and thermal imaging sensors
USGS

“Improvements to volcano monitoring networks allow the USGS to detect volcanic unrest at the earliest possible stage,” Tom Murray, USGS Volcano Science Center director, said in a 2018 USGS release. “This provides more time to issue forecasts and warnings of hazardous volcanic activity and gives at-risk communities more time to prepare.”

The NVEWS Act, which was sponsored by Senator Lisa Murkowski (R - AK), earmarks $55 million annually between 2019 and 2023 to provide more accurate and timely eruption forecasts by increasing partnerships with local governments and proactively sharing data with the volcano science community. It also seeks to increase staffing and systems — from broadband seismometers, infrasound arrays, and real-time continuous GPS receivers, to streaming webcams, satellite overwatch and volcanic gas sensors — for 24/7 volcano monitoring and establishes a grant system for furthering volcanology research.

lots of words and numbers
USGS

The USGS ranks volcanic threats based on the risk they pose to public health and property — essentially how potentially destructive the volcano itself is in relation to how many people and things might be impacted when it does erupt. The USGS assigns numerical values to the 24 various hazard and exposure factors for each volcano, then combined to calculate the overall threat score which is divided into five levels (like DEFCONs!). High and Very High get the most detailed monitoring coverage because duh, Moderate threat volcanoes still receive real-time monitoring but don’t have Tommy Lee Jones standing by to intercede, and Low (and Very Low) get checked on as needed. As of May 2022, when the USGS submitted its second annual NVEWS report to Congress, the USGS had spent just under half of the money appropriated for FY 2021 with the funds going to activities like installing a net-gen lahar detection system on Mount Rainier, upgrading the telemetry for more than two dozen observation posts throughout Alaska, Oregon, Washington, California and Hawaii.

Scientists used Mars’ ambient noise to map the planet’s subsurface layers

NASA's Mars InSight lander provided researchers with the data needed to give us our first detailed look at the red planet's crust, mantle and core. That map doesn't include any information on the structures nearer its surface, however, and we need that to be able to get a more complete picture of how the planet was formed. Now, a team of scientists was able to create the first detailed image of what lies right underneath the planet's surface, showing three billion years of its history, by listening to Martian winds.

More precisely, they analyzed the ambient noise (in the absence of marsquakes) collected by the seismometer that was installed by the InSight lander. On Earth, that kind of ambient seismic noise is generated by the ocean, human activity and winds, but only the last one is present on Mars. The Swiss Seismological Service (SED) and ETH Zurich have been regularly analyzing data collected by the seismometer as part of the Marsquake Service. Over the past years, SED was able to develop ways to analyze ambient noise data to define geological structures here on Earth, and those are the techniques they used on the data from InSight.

Based on the data the tool gathered, the top three meters of InSight's landing site is made of sand, while the next 20 meters are loose material, particularly volcanic rock fissured by meteorite impacts. Underneath that sand and rock lie lava flows divided by sediments that formed when the planet experienced cold and dry conditions. Researchers believe the uppermost lava flows were deposited around 1.7 billion years ago, while the deepest ones were deposited as far back as 3.6 billion years ago at a time when there was a lot more volcanic activity on the planet. 

The researchers recently published their study in Nature, and one of the things they emphasized is that it proves techniques to investigate our planet can also work on Mars. Other methods used to know more about Earth could also give us more information about the red planet, which may one day become humanity's second home. 

Scientists used Mars’ ambient noise to map the planet’s subsurface layers

NASA's Mars InSight lander provided researchers with the data needed to give us our first detailed look at the red planet's crust, mantle and core. That map doesn't include any information on the structures nearer its surface, however, and we need that to be able to get a more complete picture of how the planet was formed. Now, a team of scientists was able to create the first detailed image of what lies right underneath the planet's surface, showing three billion years of its history, by listening to Martian winds.

More precisely, they analyzed the ambient noise (in the absence of marsquakes) collected by the seismometer that was installed by the InSight lander. On Earth, that kind of ambient seismic noise is generated by the ocean, human activity and winds, but only the last one is present on Mars. The Swiss Seismological Service (SED) and ETH Zurich have been regularly analyzing data collected by the seismometer as part of the Marsquake Service. Over the past years, SED was able to develop ways to analyze ambient noise data to define geological structures here on Earth, and those are the techniques they used on the data from InSight.

Based on the data the tool gathered, the top three meters of InSight's landing site is made of sand, while the next 20 meters are loose material, particularly volcanic rock fissured by meteorite impacts. Underneath that sand and rock lie lava flows divided by sediments that formed when the planet experienced cold and dry conditions. Researchers believe the uppermost lava flows were deposited around 1.7 billion years ago, while the deepest ones were deposited as far back as 3.6 billion years ago at a time when there was a lot more volcanic activity on the planet. 

The researchers recently published their study in Nature, and one of the things they emphasized is that it proves techniques to investigate our planet can also work on Mars. Other methods used to know more about Earth could also give us more information about the red planet, which may one day become humanity's second home. 

USGS releases first complete geologic map of the Moon

Have you ever wanted to study the Moon’s surface in exacting detail? Now’s your chance. The USGS (with help from NASA and the Lunar Planetary Institute) has released the first complete geologic map of the Moon, providing a truly comprehensive look at...

Seismologist Suggests Using Crowdsourced Cat Data to Detect Earthquakes

Scientists will tell you that no human or animal can accurately predict an impending earthquake before it starts. However, certain animals are far more sensitive to seismic activities than humans. With that in mind, one seismologist has tossed out a wildly impractical but amusing idea for an early earthquake alert system – using cats.

PhD geophysics student Celeste Labedz posted her idea in a multi-part Twitter thread last week, and it’s well worth a read. She hypothesizes that since cats are more sensitive than humans to the weaker P-waves that happen when an earthquake is starting, that we could harness unusual cat behavior to create an early warning system. The same idea could theoretically work with dogs, but they have a tendency to be more active than cats, which could result in more false positive readings.

Labedz proposes the name PURRS (Pet-based Urban Rapid Response to Shaking) for her system. The idea is that millions of cats would be equipped with Fitbit-style Bluetooth sensors, which would detect when kitties are acting abnormally. A centralized system would take that sensor data and look for common patterns among multiple cats in the area, and should a certain threshold be reached, it could issue an alert that an earthquake is imminent. Such a network would provide many more data points and density than current early warning systems, and way more cats.

Celeste fully acknowledges that her idea would be incredibly difficult and costly to implement, but that’s why it’s merely a concept. I still love the idea of crowdsourcing pet-based data for something, since they do seem to be more sensitive to certain stimuli than humans.

Thanks to my rocket scientist friend Susan for tipping me off to this wonderfully entertaining thread.

Earth’s fast-moving magnetic north pole is messing with navigation

The Earth's magnetic north pole is constantly on the move, but it's now enough of a problem that it's having a significant effect on navigation technology. Scientists at the National Centers for Environmental Information have delivered an update to...