Volcano Watch — Volcano Alarms: Keeping HVO Virtually Vigilant 24/7

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Ping! It's 2:12 a.m., and I (a USGS Hawaiian Volcano Observatory scientist) am still groggy as I read an automated text from HVO's computer system.

Volcano Alarms: Keeping HVO Virtually Vigilant 24/7...

This thermal image of the Pu‘u ‘Ō‘ō crater, sent by text on May 7, 2015, to USGS Hawaiian Volcano Observatory geologists, is an example of the thermal camera alarm system developed at HVO. In this case, the alarm was triggered by the appearance of new lava on the floor of Pu‘u ‘Ō‘ō, seen here as the brightly colored (hot) region in the image. The temperature scale at right is in degrees Celsius. USGS webcam image.

(Public domain.)

A series of earthquakes has just occurred at Kīlauea's summit, but I can tell that it's routine activity and not a ramp-up towards an eruption. HVO's seismologist will have also been alerted, and I'm confident that he'll call if it's something serious. So, it's back to sleep.

Volcanoes don't keep time as we humans do. "Regular" work hours and our need for sleep don't figure into when they begin to rock and roll.

Despite dedicated staff at HVO and overnight checks by colleagues at the USGS National Earthquake Information Center in Golden, Colorado, there are times when no human is actually watching the flood of data streaming in from multiple seismometers, GPS receivers, tiltmeters, web cameras, and other monitoring instruments scattered strategically across Hawaii's volcanoes. Nevertheless, the volcanoes are still monitored around the clock. How is this possible? In a word, alarms. For volcanoes that are quiet most of the time, alarms are an efficient way to utilize limited human resources.

Alarms have been around for decades, but automated phone calls, pages and ringing bells have been replaced by texts and emails. Think of it as a digital tap on the shoulder from a never-sleeping computer algorithm. When that "tap" happens, the HVO scientist on duty immediately and carefully examines the data and decides if further action is needed.

For example, HVO's Swarm Alarm counts earthquakes occurring in a certain region of the volcano—say, Kīlauea's summit area—within the past hour. The system automatically notifies our monitoring group if the number surpasses the threshold set by HVO's seismologist. This is because an unusual cluster of earthquakes could signal a change in the volcanic system that may lead to a new outbreak of lava.

Another alarm system monitors the slope of the ground using electronic tiltmeters. Slow changes in tilt are not unusual as the volcano adjusts in response to magma shifts within shallow reservoirs. However, if more rapid changes are detected, a computer program sends texts to notify us that it's time to take a closer look at what else is happening.

HVO deploys thermal cameras that look into the Pu‘u ‘Ō‘ō crater. These cameras take fresh pictures every two minutes, and, if a hot spot fills more than five percent of the images, send us a text message with an embedded image. Upon receiving such a message, we check other data (including more recent webcam images) to see if lava is filling or overflowing the crater.

HVO also uses Geostationary Operational Environmental Satellite (GOES) thermal imagery to look for elevated ground temperatures in areas other than at Kīlauea's summit and on the Pu‘u ‘Ō‘ō lava flow field. If elevated temperatures are found, a computer program sends a text message with an embedded image to HVO geologists so that the situation can be further investigated.

Alarms have long been used at HVO, but they have certainly evolved from their low-tech origins. During the early episodes of Kīlauea's ongoing East Rift Zone eruption, HVO scientists wanted to know exactly when lava began spilling out of the Pu‘u ‘Ō‘ō crater, which usually indicated the onset of lava fountains. This was in 1983, years before the advent of webcams! So, HVO staff had to lug a heavy and ungainly spool of copper cable over rugged lava flows and across the spillway where lava would first flow down the side of Pu‘u ‘Ō‘ō. Using this cable, a steady voltage was radioed back to HVO, and when readings from this electronic tripwire were suddenly interrupted, we knew lava had broken the circuit.

We now have far more sophisticated ways to trigger alarms when the status of Hawaii's active volcanoes changes. As instrumentation and computer technology advance, even better techniques for triggering and evaluating volcano alarms will no doubt evolve.

In addition, we will continue to fine-tune algorithms specifically for each volcano and each type of data stream to minimize false alarms. Perhaps someday an expert program will synthesize all the different datasets to present a preliminary interpretation. Until then, human intervention is essential to evaluate and validate the information. Even in the middle of the night. Ping!


Volcano Activity Update

Kīlauea's summit lava lake level fluctuated in response to summit inflation and deflation during the past week, with measurements ranging between 51 m (167 ft) and 41 m (135 ft) below the vent rim.

Kīlauea's East Rift Zone lava flow continues to feed widespread breakouts northeast of Pu‘u ‘Ō‘ō. Active flows are slowly covering and widening the flow field, but remain within about 8 km (5 mi) of Pu‘u ‘Ō‘ō.

There were no earthquakes reported felt on the Island of Hawai‘i during the past week.