AI Uncovers Hidden Earthquakes And Faults Beneath Italy’s Campi Flegrei Volcano

Like adjusting a camera lens to make a blurry image clear, the new approach enables researchers to identify earthquakes that previous tools could not distinguish from massive sets of seismic monitoring data.

The research, a collaboration between Stanford University, Italy's National Institute of Geophysics and Volcanology (INGV) - Osservatorio Vesuviano, and the University of Naples Federico II, reveals four times as many earthquakes as earlier tools had detected and pinpoints previously unknown faults.

Knowing the location and length of a fault, the space between two blocks of rock that move and cause earthquakes, can help researchers determine the range of magnitudes of future quakes. This information is critical for informing residents and city planners of potential risks and mitigation options.

The study, published in Science on September 4, utilizes an AI model developed at Stanford to provide precise earthquake location and magnitude information in near real-time. According to the researchers, the promising results in Campi Flegrei suggest the system could be adapted to improve understanding of other areas with seismic monitoring systems, such as Santorini, Greece, which experienced a prolonged earthquake swarm at the beginning of the year. Rapidly pinpointing an earthquake's source during sudden, intense seismic activity is critical for an effective emergency response.

"Seismicity could change at any time, and that may be the most important thing about this study: this capability of getting a clear view is now operational," said study co-author Greg Beroza, a geophysics professor in the Stanford Doerr School of Sustainability. "INGV is now running the tool by themselves as needed, so it should be helpful for scientific response and ultimately public response if something changes."

A history of unrest

Campi Flegrei is an active volcanic area located within the densely populated Neapolitan region. This volcanic region, which is home to more than 500,000 people, has experienced episodes of unrest dating back to the late 1950s.

The last period of unrest began in 2005, with a significant increase in seismicity in 2018, including five earthquakes above magnitude 4 in the first eight months of 2025. The new research expands the seismicity recorded by monitoring stations from 2022 to 2025, increasing the number of earthquakes from approximately 12,000 to more than 54,000.

The data revealed two faults converging under the town of Pozzuoli, west of Naples, which has been continuously monitored since the early 1980s. During this period, unrest caused the land to rise by more than 6 feet, and over 16,000 earthquakes prompted the evacuation of 40,000 residents.

"These long faults suggest that an earthquake in the magnitude 5 range is not out of the question," said study co-author Bill Ellsworth, who co-directs the Stanford Center for Induced and Triggered Seismicity. "We've known that this is a risky place for a long time, since the '80s when part of the city was evacuated, and now we're seeing for the first time the geologic structures that are responsible."

The stakes are high for understanding the complex natural system of Campi Flegrei, which, over the past 40,000 years, has produced two of the largest eruptions in Europe. However, because of the potential to endanger people and damage buildings and infrastructure, "one of the biggest concerns in the short term in Campi Flegrei is not an eruption, but a moderate earthquake at shallow depth," Beroza said.

Under pressure

Campi Flegrei is an 8-mile-wide caldera, a massive depression formed by major volcanic eruptions about 39,000 and 15,000 years ago. In addition to eruptions, the caldera experiences uplift and subsidence, known as bradyseism, which involves the rising and sinking of the land.

"Previously, the structure of seismicity in the caldera was indistinct, and now we've seen a very thin and well-marked ring fault that is consistent with the surface features, especially offshore, and also with the area that's being uplifted," Beroza said.

"Our Italian colleagues were surprised to see the ring so clearly," added lead study author Xing Tan, a geophysics PhD student in Beroza's lab. "They expected to see something in the south where previous data had revealed scattered seismicity, but in the north, they'd never seen it so clearly."

The research suggests that overall inflation of the caldera is driving earthquake activity through pressure. The study authors did not observe any evidence for the upward migration of magma, which reduces concern over the short term that the area will experience a magmatic eruption, according to the study.

This study was supported by the Dipartimental Project LOVE-CF, the Pianeta Dinamico project Nemesis, a Stanford University Doerr School of Sustainability Discovery Grant, the RETURN Extended Partnership, and the European Union Next-GenerationEU.