From Stanford University: “Volcanoes, archaeology and the secrets of Roman concrete”

Stanford University Name
From Stanford University

February 26, 2019
Josie Garthwaite

Geophysical processes have shaped Pozzuoli, Italy, like few other places in the world. Stanford students applied modern tools to understand those links and what it means to live with natural hazards as both threat and inspiration.

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Students gather atop Mount Vesuvius in southern Italy and listen as geophysicist Tiziana Vanorio discusses how volcanic activity has shaped the surrounding region. (Image credit: Kurt Hickman)

High above Italy’s Tyrrhenian Sea, off the north coast of Sicily, 13 students sit atop Stromboli Volcano as it erupts. Ash falls on their shoulders and ping-ping-pings their helmets. The ground beneath their feet trembles.

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The Island of Stromboli, Shot 2004 Sep 28 by Steven W. Dengler.

“It’s one thing to read and talk about seismic and volcanic hazard; it’s another thing to experience it,” said geophysicist Tiziana Vanorio, an assistant professor in Stanford’s School of Earth, Energy & Environmental Sciences (Stanford Earth). “I wanted to share this with them.”

The journey to Stromboli had begun the day before in Vanorio’s hometown, Pozzuoli, a colorful port city founded by the Greeks and later occupied by the Romans, at the center of a volcanic caldera, or depression, known as Campi Flegrei. Vanorio, the 13 students and two teaching associates boarded a hydrofoil in Naples and sailed south across the deep blue water of the Tyrrhenian for nearly four quiet hours before catching sight of smoke, steam and gases puffing from Stromboli’s cone.

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During their two-week trip, students visited two volcanoes in Italy and local towns shaped by their proximity. (Image credit: Yvonne Tang)

Reaching the top would prove more arduous – a five-hour climb up steep slopes of ash and rock. Sedimentologist Nora Nieminski, a postdoctoral researcher at Stanford Earth and a guest instructor on the trip, sprinted ahead to shoot drone footage that she would later help the students manipulate to create 3D models of the volcano. But the rest of the group walked without hurry. Halfway to the top, they stopped to rest near a dark scar on the volcano’s northern flank known as the Sciara del Fuoco, where the volcano has collapsed on itself.

Dionne Thomas, ’20, a student on the trip who is majoring in chemical engineering, remembers smelling dirt and ash, seeing the Tyrrhenian Sea reflecting the sky’s late-afternoon wash of orange and blue, and counting down the minutes between small bursts of lava from a caldera upslope. While she noticed the weight of exhaustion from the long climb, she said, “I felt really strong.”

Thomas and the 12 other students on the trip visited Stromboli as part of a three-week seminar in southern Italy focused on volcanoes, archaeology and the science of Roman concrete – an exceptionally durable material that may hold insights for future materials that are more sustainable or even suitable for building habitats on Mars.

Offered through Stanford’s Bing Overseas Studies Program, the seminar is an opportunity to draw visceral connections between science and history, and to gain a better understanding of Earth along the way.

Nature’s laboratory

The Neapolitan Province in southern Italy is an ideal place to dive into the science of natural hazards and how they have played into daily life and innovation over thousands of years. Densely populated and peppered with dozens of volcanoes, the region ranks as one of the most hazardous on Earth. The ruins of a Roman harbor and an emperor’s villa can be found offshore, sunken like Atlantis as a result of unrest in Earth’s crust. “Not many places on Earth experience this kind of seismicity and volcanism, while being an ancient town and functioning as a modern society,” Vanorio said. “That’s the beauty of the place.”

Underlying the seminar’s excursions and daily lessons in geophysics, the properties of Roman concrete and 3D modeling from drone images was a larger exercise in finding connections between different fields of study. It’s no accident that students chosen to participate in the seminar represented a wide range of majors, including computer science, physics, classics, chemical engineering and political science.

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The ancient Italian city of Pozzuoli was shaped by volcanic activity. (Image credit: Kurt Hickman)

“There are still scientific questions that we don’t know how to answer,” said Vanorio, who discovered natural processes deep in the subsurface of Campi Flegrei that mirror those in Roman concrete, and has used historical texts to shed light on strengths and the characteristics of both volcanic and engineered materials. “The more we leverage knowledge across different disciplines, the more we can address and solve those problems.”

For Amara McCune, BS ’18, who joined a previous seminar in the region led by Vanorio in 2016, the intermingling of geophysics with dives into the region’s culture proved a powerful mix. “The unique combination of learning about Pompeii, volcanic uplift and Rome while being on-site, hearing from local guides and having archaeological and geological experts point out features of a location made for an incredibly rich learning experience,” she said.

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Materials inspired by nature
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Romans used concrete made with volcanic ash to build long-lasting structures like the amphitheater in Pozzuoli, Italy. (Image credit: Nora Nieminski)

Nearly all concrete today is based on a recipe developed in the early 1800s, which requires a process that’s heavily carbon-intensive. But ancient Romans invented a different recipe for concrete structures that have survived for millennia. Research now suggests this ancient material and the volcanoes that made its key components may hold clues for more sustainable building materials.
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Now pursuing a PhD in physics, McCune said the seminar in southern Italy helped to broaden her thinking about how she might apply her degree. “It made me more open to different fields and eager to learn the history and intricacies of the natural world around us,” she said.

During the most recent trip, darkness fell as the group, giddy in anticipation of the volcano’s powerful eruptions, settled in around Stromboli’s rim. “It explodes violently and without warning – these big, loud bang explosions followed by incandescent ash flying into the air,” explained Dulcie Head, a teaching assistant on the trip and a PhD student in geophysics.

By this time, the students could see the ash swirling around them as more than volcanic dirt. They knew that similar ash had been a key ingredient in construction of the amphitheater, harbor and ancient marketplace in Pozzuoli, and even the Pantheon in Rome, with its massive, unreinforced dome – the largest in the ancient world.

“Pozzuoli is possibly the place where Romans, by looking at nature, were inspired to make an iconic material,” Vanorio said. They developed a recipe for concrete that lasts for thousands of years using volcanic ash, lime, tiny volcanic rocks and water, while modern concrete often crumbles within 50 years.

Atop Stromboli, which scientists carefully monitor for safety, the students also had enough Earth science churning through their heads to see the volcano itself as a natural laboratory. “This volcano is literally producing new rocks as we’re sitting here. It’s throwing them at us,” Head explained. “It’s exciting to see such an active process, where a natural event also produces new materials.”

The group bounced and slid down a path on the volcano’s slopes wearing gas masks to protect their lungs from ash and sand kicked up by their feet. Back at their hotel at the foot of the island, they peeled off their masks and washed away Stromboli’s detritus. Later, the group learned how to calculate the trajectory and velocity of the volcano’s arcing ash projectiles with particle-tracking software.

“This was one way for us to use time-lapse images,” Vanorio said. “I wanted students from Earth science, from the classics, and engineers to learn how to use this tool because we are finding ourselves using these kinds of images more and more – often captured by drone – whether it’s to analyze inaccessible outcrops of rocks or map vast ancient sites or a building.”

What could have seemed like abstract calculations took on greater resonance in light of the group’s up-close encounter with the eruption. “I’ll never forget the bright sparks of the eruption against the dark night,” said Sylvia Choo, ’20, who is majoring in classics and biology. “It was incredible to experience the great force of nature.”

Ancient city

Some 150 miles across the cool Tyrrhenian, within the Campi Flegrei or “Burning Fields” caldera, lies downtown Pozzuoli. In this city best known to many Italians as the birthplace of Sophia Loren, the ruins of a Roman marketplace are a hub for cross-disciplinary connections.

Pozzuoli sits on a restless, Manhattan-sized swath of coast where the rotten-egg smell of sulfur laces the air. Solfatara crater, home of Vulcan, the Roman god of fire, gurgles on the edge of town. And just offshore, sculptures, thermal baths, a villa, bright tiled mosaics and other archaeological ruins rest more than 30 feet below sea level, victims of the caldera’s subsidence.

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Parts of Pozzuoli’s ancient architecture contain records of long-term subsidence and brief periods of uplift. Rapid uplift during the 1980s left the town’s harbor too shallow for docking. (Image credit: Kurt Hickman)

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Students swam through a sunken Roman resort town in the underwater archaeological park of Baiae off the coast of Pozzuoli. (Image credit: Kurt Hickman)

Near Pozzuoli’s modern-day waterfront, three columns stand amid the ruins of the old marketplace, or Macellum. The students knew from their studies on campus in the spring that the marble trio held a 2000-year record of long-term subsidence and brief periods of uplift. So as the columns came into view when the group first walked down from their villa residence, several students exclaimed, “Oh, there they are!”

Gathering close to the columns for a lecture from Vanorio while Nieminski’s drone buzzed overhead, they could see bands of tiny holes bored by so-called “stone-eater” mussels – marine mollusks that drilled up and down the columns as the rise and fall of the caldera changed how much of the structures extended above the waterline. “They literally made a mark on history,” Choo said.

Using skills developed in on-campus seminars led by Nieminski, the students were able to analyze history at the Macellum and other sites with a lighter touch. They built 3D models of the marketplace from Nieminski’s drone imagery and manipulated them with software to take measurements and answer scientific questions of their own devising.

Thomas, for example, examined the different materials in the columns to understand how weathering and water pressure from below played out over time. The project, she said, allowed her to weave together knowledge from chemical engineering, physics and math, as well as the geophysics lessons from the seminar. “After this seminar, I am even more convinced that many fields can overlap,” she said.

Restless Earth

Ups and downs are part of the fabric of life in Pozzuoli. In the early 1980s, the ground rose more than 6 feet in just two years, an alarming rate of uplift that reshaped the town, leaving the harbor too shallow for docking and forcing the relocation of schools and shops.

The rising seabed also triggered enough earthquakes to prompt evacuation of nearly 40,000 people – including Vanorio, then a teenager – for two years beginning in 1982. “Everyone was worried,” she said. “People were expecting an eruption, and we were really concerned about the seismic hazard. The houses were not retrofitted seismically.”

But as seminar students learned through lectures and readings this summer, the episode tipped off Stanford scientists to an unusual toughness in the rock here. Other volcanic calderas, like Yellowstone or the Long Valley, located east of Yosemite National Park, tend to release the energy accumulated from uplift fairly soon through earthquakes. “Those calderas experience uplift and then almost immediately, seismic activity starts,” Vanorio explained. “The rocks deform and then they fracture.”

In Pozzuoli, earthquakes didn’t begin until the Campi Flegrei caldera had deformed by nearly 3 feet. “The question from a rock physics point of view has been, what kind of rocks in the subsurface are able to accommodate such large strain without immediately cracking?” The rock capping this caldera, it turns out, contains fibrous minerals mirroring those in Roman concrete that allow it to stretch and bend before failing under stress.

At the marketplace, Vanorio also pointed out that the durability of Roman concrete can be seen in sections of the ancient walls where the bricks made of tuff – a kind of volcanic rock – eroded away long ago, but the mortar made with volcanic ash and lime still remains. “At the end of the day, these ancient sites are made of Earth materials that degrade and change over time,” Vanorio said. “We can use rock physics to understand those materials and learn to preserve them better.”

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