Tag Archives: seismic

Scientists induce Yellowstone seismic activity to analyze the volcano’s depth

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Researchers from the University of Utah and the University of New Mexico used artificial “earthquakes” to investigate the magma beneath Yellowstone, a closely monitored hypervolcano. The team deployed truck-mounted bibroseis, large mechanical vibrators, to generate seismic waves throughout the national park. By recording these waves with 650 ground sensors, scientists were able to examine the underground volcanic structures.

Dr. Jamie Farrell, a geologist at the University of Utah and study co-author, explained, “In a way, we’re causing our own earthquakes and recording all that data on seismometers. With so many sensors, we can obtain a clear image of what’s happening below the surface.” This investigation revealed that the top of the magma chamber is approximately 3.8 km below the surface, with 86% consisting of solid rock and 14% containing molten rock, gas, and liquid pockets.

Scientists deployed a portable seismometer called Geophone to measure vibrations from artificial earthquakes – Credit: Jamie Farrell, University of Utah

Professor Bill McGuire, an expert in Geophysical and Climate Hazards, noted that using artificial seismic waves to study underground geology is not new but has not been applied in Yellowstone for determining magma depth before. Despite the proximity of the magma to the surface, the study confirmed that an eruption is not imminent.

Mike Poland, the chief scientist at the US Geological Survey and Yellowstone Volcano Observatory, remarked, “Yellowstone provides valuable insights into volcano behavior worldwide. While another super eruption is possible elsewhere, Yellowstone is not currently at risk.”

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About our experts:

Professor Bill McGuire: Professor Emeritus of Geophysics and Climate Hazards at University College, London. McGuire is a science writer and broadcaster with a forthcoming book on how past events shape our future.

Source: www.sciencefocus.com

Solar heat may impact seismic activity on Earth

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According to new research by scientists at Tsukuba University and the Japan National Institute of Advanced Industrial Science and Technology, heat from our sun promotes changes in the atmosphere temperature on Earth and changes in the atmosphere temperature on Earth.

The sun is seen by solar orbiter in extreme ultraviolet rays from a distance of approximately 75 million km. This image is a mosaic of 25 individual images taken on March 7, 2022 by the high-resolution telescope of an extreme ultraviolet imager (EUI) instrument. The image, taken at a wavelength of 17 nanometers in the extreme ultraviolet region of the electromagnetic spectrum, reveals the corona, the upper atmosphere of the sun, with a temperature of about 1 million degrees Celsius. Image credits: ESA/NASA/SOLAR ORBITER/EUI Team/E. Kraaikamp, ​​Rob.

Seismic studies have revealed many of the fundamentals of earthquakes: the tectonic plates move, strain energy accumulates, and that energy is ultimately released in the form of an earthquake.

However, when it comes to predicting them, there is still much to learn to evacuate cities before a catastrophe like the 2011 magnitude 9.0 Tōhoku earthquake

In recent years, research has focused on possible correlations between the sun or moon and seismic activity on Earth, with several studies pointing to tidal or electromagnetic effects that interact with the Earth's crust, core, and mantle.

In a new study, Matheus Henrique Junqueira Saldanha and his colleagues explored the possibility that solar-induced climate could play a role.

“Solar heat can promote changes in atmospheric temperature, which can affect rock properties and groundwater movements, among other things,” said Dr. Junqueira Saldanha.

“Such variations can make rocks more brittle and more prone to breaking, for example. And changes in rainfall and snow thaw can change the pressure on the boundaries of the tectonic plate.”

“Those factors may not be the main factors that cause earthquakes, but they may still play a useful role in predicting seismic activity.”

Using mathematical and computational methods, researchers analyzed seismic data along with solar activity records and surface temperatures on Earth.

Among other findings, they observed that when the surface temperature of the earth was included in the model, predictions of particularly shallow earthquakes are more accurate.

“That makes sense because heat and water mostly affect the upper layers of the Earth's crust,” said Junqueira Saldanha.

The findings suggest that solar heat transfer to the Earth's surface affects seismic activity, but this is only a small measure, and incorporating predictions of solar activity into a detailed earth temperature model could help issue seismic predictions.

“It's an exciting direction and I hope our research will shed some light on the larger picture of what causes earthquakes,” said Dr. Junqueira Saldanha.

study Today I'll be appearing in the journal chaos.

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Matheus Henrique Junqueira Saldanha et al. The role of solar heat in seismic activity. chaos 35, 033107; doi:10.1063/5.0243721

Source: www.sci.news

Study reveals signs of recent seismic activity on far side of the moon.

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A recent study by the Smithsonian Institution and the University of Maryland suggests that the rugged terrain of the moon may still be active in areas of current interest for future missions.

The small ridge on the other side of the moon (yellow) reveals evidence that the moon may not be as dormant as before. Image Credit: Smithsonian facility, Tomwattors

For decades, scientists have been studying the moon’s surface to better understand its complex geological and evolutionary history.

Evidence from the moon’s Maria, the dark and flat areas filled with solid lava, suggests that the moon underwent significant compression in its distant past.

Researchers initially believed that a large ridge near the moon was formed by shrinkage billions of years ago, leading to the conclusion that the moon’s Maria had been dormant since then.

However, new research indicates that there may be more dynamic activity beneath the moon’s surface.

Jaclyn Clark and her colleagues, researchers at the University of Maryland, discovered that the small ridge on the other side of the moon is significantly younger than previously studied ridges.

“Many scientists had previously thought that most of the moon’s geological activity occurred over two to three billion years ago,” Clark stated. “But it appears that these structural features have been active within the past billion years and may still be active today.”

“These small ridges formed within the last 200 million years, a relatively recent timeframe in lunar terms,” she added.

Using advanced mapping and modeling techniques, researchers uncovered a previously unknown small ridge on the far side of the moon.

The ridge consists of 10-40 volcanic groups likely formed 3.2 to 3.6 billion years ago in narrow areas with fundamental weaknesses on the moon’s surface.

To determine the age of these small ridges, researchers employed a crater count method and found them to be younger than surrounding features.

“The more craters present, the older the surface,” Dr. Clark explained. “Based on the number of craters, we estimate that these features have been structurally active within the last 160 million years.”

Scientists noted that the structure of the distant ridge resembles that seen near the moon, suggesting they were formed by similar forces.

A few decades ago, NASA’s Apollo Mission detected shallow moonquakes. Recent findings suggest that these small ridges may be related to similar seismic activity.

“I hope that future moon missions will include tools like terrestrial penetration radar to better understand the subsurface structure of the moon,” Clark expressed. “Knowing that the moon is still geologically active is crucial for planning human missions and infrastructure development on the lunar surface.”

The team’s paper was published this month in the Planetary Science Journal.

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Ca Nypaver et al. 2025. Moon Distant Ridges and Antartica – Recent Structural Deformation of an Incongruous Basin. Planet. Sci. J 6, 16; DOI: 10.3847/PSJ/AD9EAA

Source: www.sci.news

There is a bizarre phenomenon occurring with Earth’s seismic activity: Here’s why

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In the realm of earthquakes, one should always anticipate the unexpected. This is the message conveyed by seismologists Professor Eric Curry from Ecole Normale Supérieure (ENS) in Paris, and Jean François Ritz, the Director of CNRS Laboratoire Géosciences in Montpellier.

At the core of their counsel lies the fact that earthquakes can occur in unexpected places. These enigmatic occurrences, known as intraplate earthquakes, manifest in geologically tranquil locations, distant from the active boundaries of tectonic plates.

The French scientists are dedicated to comprehending and elucidating these phenomena.

Unpredictable and Destructive

The blocks of rock forming the fragile outer shell of our planet move gradually across the Earth’s surface, at a pace akin to the growth rate of a human fingernail.

While the majority of geological activity of note transpires where plates converge, intraplate earthquakes diverge from this norm, occurring within plates, far from their peripheries.

Curry and Ritz have a compelling motive to shine a light on this topic, given that intraplate earthquakes are infrequent, with a limited number of notable occurrences compared to earthquakes at plate boundaries. Professor Curry noted that only around 20 earthquakes measuring 6 or more in magnitude have been recorded since 1974. This amounts to less than half the percentage of similar-sized earthquakes observed at plate edges during the same timeframe. Their scarcity and protracted duration render them challenging to forecast, yet they have the potential to inflict considerable devastation on unprepared urban centers that have never viewed earthquakes as a pressing concern.

Intraplate earthquakes can transpire wherever geological faults exist within the Earth’s crust. Over the past centuries, they have been documented in locations as diverse as Basel, Switzerland, New York, Boston in the United States, and the St. Lawrence River in Canada.

More recently, they wrought havoc in the Australian city of Newcastle, as well as in Botswana and Puebla, Mexico in 2017, resulting in nearly 400 fatalities in the latter.

The Magnitude of the Problem

Curry and Ritz garnered attention for a magnitude 5 earthquake near the Rhone Valley village of Le Teil in 2019, while a magnitude 5.2 earthquake shook the Lincolnshire town of Market Larsen in England in 2008. Termed the “Larsen Earthquake” by local newspapers, it caused one injury and incurred damages estimated at around £20 million. The seismic events in the UK and France tend to be minor, contrasting with occurrences in other global regions.

The most devastating intraplate earthquake of modern times took place in 2001, with a magnitude of 7.6, striking Bhuj, Gujarat, India. This catastrophic event razed an estimated 300,000 edifices and claimed the lives of up to 20,000 individuals. Looking back to 1886, a around magnitude 7 earthquake hit Charleston on the US east coast, resulting in 60 casualties and widespread devastation. A few years later, the New Madrid, Missouri area endured three potent intraplate earthquakes measuring up to magnitude 7.5, inducing violent tremors across the vicinity.

The rarity of these seismic episodes, combined with their potential for extensive destruction, underscores the urgency for a deeper understanding of intraplate earthquakes.

Increasing Tension

Both intraplate and plate margin earthquakes share a common operational mechanism. Essentially, strain builds up over time on geological faults within the Earth’s crust until it reaches a critical threshold, leading to fault rupture or slippage, thereby generating earthquakes. The release of this built-up energy in the form of seismic waves alleviates the strain. However, the process begins anew as strain accumulates again. Although the process mirrors itself in both types of earthquakes, the triggers that prompt rupture likely differ.

Curry and Ritz propose that while fault rupture at plate margins is predominantly instigated by plate movements, intraplate earthquakes within the plate’s interior are spurred by discrete triggers that occur rapidly on geological time scales. Such triggers could encompass various phenomena such as unloading due to ice sheet melting, surface erosion, rain infiltration, or fluid displacement from the Earth’s mantle.

Intraplate Complexity

It’s worth noting that a fault primed for rupture can be triggered by an equivalent pressure to a handshake. Consequently, even though millions of years may have been necessary for strain to accumulate on ancient intraplate faults, their activation could unfold swiftly over a brief period. Curry and Ritz explored the Le Teil earthquake of 2019 and concluded that it was probably triggered by the shedding of the upper crust following the region’s glacier recession post the Ice Age, possibly triggered by a nearby quarry.

The unloading and deformation of the Earth’s crust post the rapid melting of colossal ice sheets about 20,000 to 10,000 years before the present epoch is presumed to have catalyzed numerous intraplate earthquakes, including those at New Madrid, Charleston, and Basel. At the decline of the Ice Age, Norway and Sweden witnessed a surge in seismic events as the 3 km thick Scandinavian ice sheet melted rapidly, unburdening intraplate faults underneath it, and releasing accumulated strain over thousands of years.

This period witnessed several sizable earthquakes with one heaving about 8,200 years ago, instigating a massive underwater landslide off Norway’s coast, engendering a North Atlantic Ocean tsunami with crest heights reaching 20 meters across the Shetland Islands and 6 meters along Scotland’s eastern coastline.

Prediction Problems

The intricacies of predicting intraplate earthquakes pose a formidable challenge, as Curry highlights, stating, “For these peculiar earthquakes, calculating future risk is highly intricate, particularly given their sporadic nature in specific locales. Objective indicators for evaluating future intraplate seismicity are lacking.”

Despite the convolutions associated with predicting intraplate earthquakes, research concerning the peril posed by these events in historically affected regions is critical. The burgeoning urbanization in areas with past intraplate earthquake history is cause for concern.

Currently, more than half of the global populace resides in urban centers, with cities in regions susceptible to intraplate earthquakes witnessing substantial expansion. Basel, Switzerland, for instance, the nation’s second-largest urban conurbation with a populace of approximately 500,000, serves as a key hub for banking and the chemical sector. In the event of an earthquake akin to the one in 1356, the outcomes would be significantly more severe, portending thousands of casualties and severe property damages.

Similarly, Charleston in the United States, with a population exceeding 550,000, now finds itself at the heart of a bustling city characterized by stone and concrete edifices, rendering it vulnerable to calamitous consequences if struck by an earthquake akin to the 1886 event.

Looking towards the future, the specter of global warming looms large, with the potential to increase intraplate seismic activity as glacial and ice sheet melts diminish the underlying crust’s load, sparking fault ruptures and strain release accumulated over millennia.

The ramifications of such seismic events reverberate across a broad cross-section of society, driving home the importance of preparedness and vigilance in regions prone to intraplate earthquakes.

Source: www.sciencefocus.com