A groundbreaking tectonic model has emerged from the depths of East Antarctica’s frozen landscape, revealing a colossal rotational extension process that shaped a striking handheld-fan-shaped structural feature beneath the ice. This vast subglacial basin province, meticulously reconstructed by geoscientists, offers compelling evidence of continental-scale deformation that redefined East Antarctica’s crustal architecture. The implications of this discovery reverberate beyond geological curiosity, stirring fresh insights into the ancient tectonic forces that sculpted one of the planet’s most enigmatic continents and linking these subterranean transformations to the dynamics of Gondwana’s fragmentation.

At the heart of this tectonic revelation lies a single, continent-wide mechanism dominated by rotational extension—an earth-shaping process that not only dramatically reworked pre-existing structures but also set in motion subsequent geological phenomena of monumental scale. This model suggests that the rotational extension instigated a complex reconfiguration of East Antarctic lithosphere, fundamentally influencing the geological evolution of critical mountain ranges, including the Gamburtsev and Transantarctic Mountains. The resulting deformation and segmentation within these ranges underpin the formation of conjugate continental margins, which form a semi-circular pattern between Antarctica and Australia, illuminating previously obscure steps in the precursory tectonic stages leading up to the ultimate breakup of Gondwana.

One of the most intriguing aspects of this tectonic scenario concerns the spatial coincidence between the fan-shaped province’s pivot point and the Euler poles inferred for the extension between East and West Antarctica after approximately 34 million years ago. Although there remains uncertainty surrounding the precise location of these rotational poles, the close alignment raises provocative questions about the stability of deformation centers over geological time scales. This alignment further suggests a potential causal link bridging intraplate deformation mechanisms with the broader plate tectonic motions that characterized the region during late Cenozoic rifting and continental evolution.

Remarkably, this fan-like rotational deformation appears confined exclusively to the Antarctic lithosphere. Detailed analyses fail to identify any continuation of these features into the adjacent Australian continent, signaling a previously unrecognized intraplate deformation zone within East Antarctica. This discovery holds profound implications for reconciling longstanding inconsistencies in tectonic reconstructions, particularly in refining the fit between the Australian and Antarctic continental margins. Identifying this localized deformation zone may illuminate why some plate reconstructions have documented unusually broad crustal overlaps and difficult-to-explain mismatches across conjugate basement terranes and major fault systems.

Beyond its tectonic significance, this rotational extension model profoundly informs our understanding of the East Antarctic Ice Sheet’s origins and dynamic behaviour. Initiated approximately 34 million years ago, the ice sheet’s evolution intersects the geological fabric sculpted by the extensional forces operating beneath it. The subglacial basins forming the handheld-fan-like structure influence not only the basal topography but also the dynamic feedback mechanisms governing ice sheet retreat and advance. Due to ongoing subsidence and cooling of the crust following extension, many of these basin floors lie near or below modern mean sea level, engendering conditions that likely amplify the ice sheet’s sensitivity and vulnerability to climatic perturbations.

Topographically, the segmentation of major mountain ranges in East Antarctica via a network of east-west oriented circular shear belts has played a pivotal role in directing glacial pathways. Shear zones along these belts create structural weaknesses exploited by massive outlet glaciers such as Byrd, Beardmore, Nimrod, David, Priestley, and Tucker. These glaciers have incised profound troughs into the mountains, driving further isostatic uplift of the peaks and perpetuating a cycle of tectonic and glacial interaction. This dynamic interplay exemplifies how ancient tectonic architecture continues to govern present-day cryospheric and geomorphological processes in Antarctica’s interior.

Similarly, the prominent fan-shaped boundary system oriented roughly north-south within the East Antarctic subglacial basin province appears intimately linked to the positions of some of the continent’s most significant outlet glaciers on its coastal margins. Totten, Vanderford, Denman, Frost, and Amery glaciers align closely with major basin boundaries, suggesting that structural geology fundamentally controls glacial drainage patterns. This tectonic-ice sheet interface underscores the critical role geological processes dating back more than 150 million years play in determining the contemporary ice sheet’s behaviour and its response to environmental change.

From a broader geodynamic perspective, the existence of this rotational extension province challenges conventional interpretations of East Antarctica’s lithospheric rigidity. Instead of behaving as a monolithic block, the continent’s eastern sector underwent profound internal distortion and segmentation, contesting previous models that invoked more homogeneous deformation. This nuanced understanding demands re-evaluation of geodynamic models that couple onshore structural features with offshore fracture zone studies, highlighting the complementary roles of both deep and shallow earth processes in continent-scale reorganization.

Moreover, the timeframe of deformation pinned to the EAFBP coincides intriguingly with marked geological shifts at the Paleogene-Neogene boundary. This temporal intersection accentuates the role of tectonics in modulating the environmental context for large-scale ice sheet nucleation and persistence. The established relationship provides a unique opportunity to integrate tectonic forcing into climate and cryosphere models, potentially refining predictions of ice sheet behaviour within a warming world.

Delineating the rotational extension process also sheds light on the segmentation observed within the Transantarctic Mountains and the West Antarctic Rift System. These structural discontinuities reveal how the continent’s lithosphere accommodated strain over millions of years, via curved shear belts and fault zones demarcating discrete tectonic blocks. Such segmentation arguably fostered localized uplift and subsidence patterns, influencing sediment deposition regimes and geomorphological evolution throughout the continent’s interior.

Perhaps most strikingly, this in-depth investigation emphasizes the enduring influence of early Mesozoic tectonics on shaping Antarctica’s geological framework, long after the initial stages of Gondwana’s breakup. By identifying a singular large-scale rotational extension event as a formative agent, this model unites seemingly disparate observations—from subglacial basin geometry to mountain range uplift—into a cohesive tectonic narrative. This unified perspective provides a valuable blueprint for reinterpreting the continent’s evolutionary trajectory and contextualizing its role within global plate tectonics.

The pioneering interdisciplinary approach harnessed to unravel this subglacial province integrates geophysical imaging, structural geology, and tectonic reconstruction techniques. Detailed gravity anomaly mapping and seismic reflection profiles provide unprecedented subsurface illumination, enabling researchers to differentiate subtle deformation patterns beneath kilometers of ice. The resulting dataset affords unparalleled clarity into the three-dimensional architecture of East Antarctica’s crust, setting a benchmark for future Antarctic geoscience research.

In conclusion, this discovery of a fan-shaped rotational extension province unveils an overlooked GPS of tectonic activity underpinning the East Antarctic lithosphere. It highlights the dynamic and evolving nature of continental interiors, traditionally considered tectonically inert. As our understanding deepens, so too does the appreciation for how ancient geological forces continue to wield influence over ice dynamics, mountain formation, and continental fragmentation—processes that shape Earth both past and present.

The identification of this rotational extension province opens new avenues for refining plate reconstructions involving Antarctica and Australia. It simultaneously challenges simplifications inherent in previous models, advocating for nuanced treatments of intraplate deformation zones. This progression promises enhanced geological models capable of incorporating the intricate interplay of forces molding Earth’s least accessible continental frontier.

Ultimately, these insights carry profound ramifications for predicting Antarctica’s future amid climate change. Given the pivotal role tectonic features play in modulating ice sheet sensitivity and stability, understanding their genesis and evolution becomes crucial for anticipating responses to accelerating global warming. This research thus exemplifies the vital synergy between geological sciences and cryospheric studies essential for informed stewardship of polar environments.

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Subject of Research: The formation and tectonic evolution of a fan-shaped subglacial basin province in East Antarctica driven by rotational extension.

Article Title: A fan-shaped subglacial basin province in East Antarctica formed by rotational extension.

Article References:
Armadillo, E., Rizzello, D., Balbi, P. et al. A fan-shaped subglacial basin province in East Antarctica formed by rotational extension. Nat. Geosci. (2026). https://doi.org/10.1038/s41561-026-01991-6

Image Credits: AI Generated

DOI: https://doi.org/10.1038/s41561-026-01991-6

Keywords: East Antarctica, rotational extension, subglacial basins, tectonic deformation, Gondwana breakup, ice sheet dynamics, Transantarctic Mountains, Gamburtsev Mountains, intraplate deformation, East Antarctic Ice Sheet, plate reconstructions, lithospheric segmentation, continental rifting, conjugate margins

In the endless quest to unravel the mysteries of Mars, a landmark study has emerged proposing groundbreaking criteria to identify the elusive lower crust and mantle materials of the Red Planet. This pioneering research, spearheaded by Trowbridge, Horgan, Weiss, and colleagues, focuses on the geological aftermath of the colossal Isidis impact basin, a feature that has long intrigued planetary scientists due to its immense scale and unique compositional context. Published in Communications Earth & Environment, their work sets a new standard for interpreting Martian geology by delineating precise identification markers for the Martian subsurface layers that have been thrust upward by ancient impact processes.

The Isidis Planitia, a vast impact basin approximately 1500 kilometers in diameter, represents one of the youngest and most prominent geological structures on Mars. Formed around 3.9 billion years ago during the Late Heavy Bombardment, this crater provides a natural window into the planet’s interior through the excavation and exposure of its lower crust and potentially mantle materials. The research team capitalized on this unique feature, utilizing high-resolution spectral data, geophysical modeling, and comparative analysis to develop robust criteria for differentiating deep crustal and mantle rocks from more common surface deposits.

Central to the study is the integration of multispectral imaging from orbiters such as Mars Reconnaissance Orbiter’s CRISM instrument and detailed geochemical simulations. These tools enable the extraction of compositional signatures associated with varying mineral assemblages. For instance, the presence of olivine-dominated ultramafic rocks, distinct pyroxene compositions, and specific alteration minerals serve as key indicators for mantle-derived materials. By correlating these spectral indicators with geophysical anomalies detected in the region, the team crafted a comprehensive framework to pinpoint probable lower crust and mantle exposures.

One of the study’s remarkable achievements is the identification of an unexpected diversity in the mineralogical assemblage within the Isidis excavated materials. Contrary to previous models that predicted a relatively uniform lower crustal layer, the researchers found evidence suggesting significant heterogeneity. This includes variations in Mg/Fe ratios within olivine crystals and compositional differences in pyroxenes, which hint at complex magmatic differentiation and mantle metasomatism events that predate the impact. These findings challenge conventional wisdom and suggest that Mars’s deep interior retains a more dynamic and chemically intricate history than once thought.

The implications of correctly identifying lower crust and mantle materials extend far beyond academic interest. These rocks act as a geological archive, preserving records of early planetary differentiation, mantle convection patterns, and volcanic activity. Unlocking these secrets helps refine models of Mars’s thermal evolution and provides insights into its tectonic and volcanic history. Moreover, such knowledge is vital for astrobiological considerations; the geochemical environment of the lower crust and mantle potentially harbors clues about past habitability and subsurface water reservoirs.

The methodology outlined in this paper is also a leap forward in planetary remote sensing. Previous approaches often relied solely on surface morphologies or broad compositional classifications that were insufficiently discriminating to distinguish deep crustal from upper crustal materials. By employing an interdisciplinary strategy that includes spectral characterization, petrological modeling, and impact excavation dynamics, the authors have set a new benchmark for planetary geoscience research. This approach has wide applicability, opening pathways to reassess other Martian regions and potentially the crust-mantle interface of other terrestrial bodies like the Moon or Mercury.

Crucially, the authors address the complexity of impact processes themselves and their influence on exposing and altering the crust-mantle interface. The Isidis impact, due to its scale and the kinetic energy involved, likely caused widespread fracturing and melting, modifying the original signatures of deep-seated rocks. Disentangling these effects required sophisticated modeling of shock metamorphism and ejecta redistribution, ensuring that identified materials can be confidently traced back to their sources within the planetary interior rather than being artifacts of impact mixing.

This research also propels forward the discourse on Mars sample return missions. Identifying locations where lower crust and mantle materials are exposed at the surface highlights prime sampling sites for future missions. These samples could revolutionize our understanding of the Red Planet’s formation and development. The criteria provided by Trowbridge et al. serve as a guide to prioritize landing sites that maximize the scientific return by targeting the most geologically informative materials.

Furthermore, the study confronts challenges associated with remote geochemical analysis on Mars. Variability in dust cover, surface weathering, and the presence of secondary minerals have historically confounded interpretations. The authors mitigate these issues through a multi-layered approach combining spectral deconvolution, thermal inertia data, and comparative terrestrial analog studies. This layered methodology enhances confidence in the identification of primary crustal and mantle signatures amid surface contaminants, elevating the precision of remote geological investigations.

The impact on planetary geology education and public engagement cannot be overstated. The clarity and innovation demonstrated in this research provide a compelling narrative about Mars’s inner workings and cataclysmic past. Communicating such advances in an accessible yet scientifically rigorous manner enriches both academic discourse and public understanding, inspiring the next generation of planetary scientists and enthusiasts worldwide.

Looking ahead, the authors emphasize the need for corroborative in-situ investigations to validate their proposed identification framework. Landers and rovers equipped with advanced geochemical and mineralogical tools can directly test these hypotheses by sampling targeted outcrops within and around Isidis Planitia. Collaborative efforts between orbital reconnaissance and landed operations will be essential to fully unravel the formation processes and compositional diversity of Mars’s lower crust and mantle.

Another noteworthy dimension of the study is the potential influence of these deep Martian materials on surface volcanism and tectonics. By better characterizing the elemental and mineralogical makeup of the lower crust and mantle, scientists can improve models of mantle melting and magmatic ascent, which shape volcanic constructs observed across Mars. This understanding bridges the gap between subsurface processes and planetary surface evolution, providing a holistic view of Martian geodynamics.

In the broader context of comparative planetology, this work echoes studies of Earth’s lower crust and mantle, drawing parallels and contrasts that elucidate planetary formation mechanisms and divergence. Differences observed in Martian deep crustal rocks versus Earth’s geology underscore the unique pathways planetary interiors can take under varying thermal and compositional regimes. Such insights refine theoretical frameworks applicable across our Solar System’s terrestrial planets.

The study also invites re-examination of the isotopic and age data from Martian meteorites believed to originate from deep crustal or mantle sources. Integrating these data with the newly established identification criteria enhances confidence in meteorite provenance assignments and contributes to more nuanced timelines of Martian geological history.

In summation, the comprehensive criteria proposed for identifying the Martian lower crust and mantle excavated by the Isidis impact constitute a transformative leap in understanding the Red Planet’s subsurface architecture. This research lays the groundwork for future exploration, sample return, and comparative geological studies, propelling Mars science into a new era of detail and discovery. As humanity continues its exploration of Mars, such foundational work illuminates the path toward deciphering the planet’s complex past and its potential for harboring life.

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Subject of Research: Identification criteria for Martian lower crust and mantle materials excavated by the Isidis impact.

Article Title: Proposed identification criteria of the Martian lower crust and mantle excavated by the Isidis impact.

Article References:
Trowbridge, A.J., Horgan, B., Weiss, B.P. et al. Proposed identification criteria of the Martian lower crust and mantle excavated by the Isidis impact. Commun Earth Environ (2026). https://doi.org/10.1038/s43247-026-03617-6

Image Credits: AI Generated

The Euphrates River fueled the "cradle of civilization," and a new study reveals the waterway was born of two other ancient rivers around 3.6 million years ago.

Fingal's Cave is a hollow inside the Scottish island of Staffa that is characterized by massive, interlocking hexagonal columns of volcanic rock and astonishing acoustics.

The Euphrates River fueled the "cradle of civilization," and a new study reveals the waterway was born of two other ancient rivers around 3.6 million years ago.

The Euphrates River fueled the "cradle of civilization," and a new study reveals the waterway was born of two other ancient rivers around 3.6 million years ago.

Fingal's Cave is a hollow inside the Scottish island of Staffa that is characterized by massive, interlocking hexagonal columns of volcanic rock and astonishing acoustics.

Planet Earth has some pretty great qualities going for it. (Negative reviews mostly revolve around the staff and clientele.) Pretty high on the list of positives is a richly oxygenated atmosphere. But that’s something that evolved and built up over a couple billion years, only eventually resulting in a world conducive to animal life like us.

Scientists have many ideas about what could have caused oxygen to increase, and it seems that a number of them are probably correct. No one thing in isolation seems to explain it. Life is part of the story, with photosynthetic life pumping out oxygen. The chemistry of the solid Earth also had a role to play, both through supporting photosynthetic life and through reactions that can shuttle oxygen between the atmosphere and rocks deep inside the Earth.

A new study led by Wei Shi of the Chengdu University of Technology suggests that evidence of changes in the subduction of tectonic plates—the process by which they disappear down into Earth’s interior—lines up with the timing of jumps in oxygen levels.

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© AZemdega

Fingal's Cave is a hollow inside the Scottish island of Staffa that is characterized by massive, interlocking hexagonal columns of volcanic rock and astonishing acoustics.

Scientists drill off Cape Cod and uncover vast undersea aquifers that may reshape our water future.

About 400 million years ago, the population of plants with vein systems for transferring water and nutrients, called vascular land plants, exploded. Soon thereafter, rocks from some continental magmas showed notable shifts in their chemical compositions. Geologists have suggested that these magma changes happened worldwide, but some argue that the data might be biased because some geographic regions have more samples to analyze than others. A new research team recently tested whether these magmatic changes occurred on a global scale, versus in isolated mountain belts or volcanic islands. 

Geologists use the chemistry of rocks formed from magma to understand a magma’s history. In particular, a mineral called zircon that forms from cooling magma preserves chemical clues about where the magma came from and what it interacted with. To test whether magma changes were global or local, the authors needed data ranging from the equator to the poles. Continents have shifted over the past 400 million years, so scientists use the latitude a rock had when it formed, called its paleolatitude, to compare samples from different parts of ancient Earth. To understand magma histories worldwide, the team used publicly available chemical data from zircons in magmatic rocks that formed across a wide spread of paleolatitudes.

Chemical elements with the same number of protons but different numbers of neutrons are called isotopes with different masses. To discern how plants influenced magma, the researchers analyzed 2 different isotope signals preserved in the zircons. The first isotope signal comes from the ratio of the heavy to light oxygen isotopes, which increases when sediment mixes into magma. Scientists refer to this value as δ¹⁸O, pronounced “delta 18-O.” 

The second isotope signal comes from the element hafnium, denoted Hf. Geologists use hafnium to estimate how long ago magmas melted and separated from the mantle. Zircon contains 2 Hf isotopes, one of which is stable and one of which is produced by radioactive decay. Because this decay happens over billions of years, the ratio between the 2 Hf isotopes over time shifts only slightly. Geologists express these tiny differences using a shorthand called εHf, pronounced “epsilon hafnium,” which shows how much a magma’s Hf signature has changed from Earth’s original mantle. Lower εHf values indicate magmas that incorporated older crustal rock, while higher εHf values reflect mantle sources.

The researchers found that δ¹⁸O values increased as εHf values decreased in these zircons. They concluded that this trend indicates increasing amounts of land-derived sediment in magmas, corresponding with the evolution of land plants. They suggested that land plants altered the ancient landscape, changing how sediments weathered and moved over land. 

To explore this pattern in detail, the team focused on the Andes Mountains, a region that preserves a long history of magmatic activity across a long span of space and time. Using a database, they accessed isotope data from zircon samples collected in the Andes Mountains by dozens of other research groups. These samples covered 32 degrees of modern latitude and 520 million years of Earth’s history, offering a broad window into how magma chemistry changed during that time.

They found that zircons older than 450 million years had no relationship between their εHf and δ¹⁸O values. However, in zircons younger than 450 million years, δ¹⁸O increased as εHf decreased. The researchers saw this pattern in magmas that formed along the edge of the continent, where one tectonic plate sinks below the other, called a subduction zone. They also saw this pattern in magmas that formed inland, away from the subduction zone, around 200 million years ago during the breakup of the supercontinent Pangaea.

 They found similar results in published zircon isotope data from igneous rocks in China, the Caribbean, Antarctica, Madagascar, and Tasmania. Zircons from each region showed the same relationship as zircons in the Andes. Since paleolatitude can also reflect ancient climate, the researchers compared the ratio of εHf and δ¹⁸O, written as εHf/δ¹⁸O, with paleolatitude to test whether ancient climate zones influenced magma chemistry. They found no link between paleolatitude and εHf/δ¹⁸O. 

With these results in mind, the researchers concluded that the relationship between εHf and δ¹⁸O shifted worldwide after vascular land plants evolved. They argued that as plants spread across the continents, their roots accelerated the breakdown of rocks. This accelerated weathering produced large amounts of sediment that washed into ocean basins and was eventually subducted into the mantle, forever changing the chemistry of magma formed there. They suggested that this chain of events illustrates how life on Earth’s surface can drive changes deep within the planet. 

The post Plants changed the chemistry of magmas appeared first on Sciworthy.

Planet Earth has some pretty great qualities going for it. (Negative reviews mostly revolve around the staff and clientele.) Pretty high on the list of positives is a richly oxygenated atmosphere. But that’s something that evolved and built up over a couple billion years, only eventually resulting in a world conducive to animal life like us.

Scientists have many ideas about what could have caused oxygen to increase, and it seems that a number of them are probably correct. No one thing in isolation seems to explain it. Life is part of the story, with photosynthetic life pumping out oxygen. The chemistry of the solid Earth also had a role to play, both through supporting photosynthetic life and through reactions that can shuttle oxygen between the atmosphere and rocks deep inside the Earth.

A new study led by Wei Shi of the Chengdu University of Technology suggests that evidence of changes in the subduction of tectonic plates—the process by which they disappear down into Earth’s interior—lines up with the timing of jumps in oxygen levels.

Read full article

Comments

© AZemdega

The evolution of land plants about 450 million years ago altered many of Earth’s geologic processes, like weathering and erosion. Due to the lack of evidence for meandering rivers before then, past scientists hypothesized that plants could have caused straight rivers to meander. However, in recent decades, researchers have challenged this idea. They’ve suggested that plants could have changed rivers without causing them to meander.

To understand how vegetation changed rivers in the past, researchers recently studied 49 modern meandering rivers. They sorted these rivers into 3 categories – vegetated, unvegetated, and semi-vegetated – by analyzing color images taken of them from the air. They identified 18 vegetated rivers located in South America, 24 unvegetated rivers in the western United States, and 7 semi-vegetated rivers in China and the Eastern United States. 

To examine the impact of plants on these rivers, the researchers quantified how much each river channel curves, known as its sinuosity. They used opposite banks of each river bend to find its center point, then, using digital maps, drew a line along the river’s trajectory at an equal distance between the bend center points. They used this line to calculate the angle between the river’s curve and the center point. This angle, called the migration angle, shows how a river bend relates to the river’s downstream direction. By measuring it, researchers can tell whether a river is developing more vertically or horizontally, and how sharp its bends are, either of which could be influenced by plants. 

The researchers compared migration angles across each river system to determine how river bends varied between vegetated and unvegetated rivers. They found that vegetated rivers tend to deposit sediments in the river bend, leading to curvier bends that develop horizontally and widen over time. In contrast, unvegetated rivers deposit sediment downstream, which means the rivers bend less and have greater variability in bend width.

The question remained whether plants were the primary cause of these differences or whether other factors were at play. To resolve this, the researchers investigated 3 additional factors. The first was the natural fluctuations in water flow across a river system, called its flow variability. They found that during storms, flow variability caused river bends to move downstream in unvegetated rivers, but not in vegetated rivers. This result suggested that flow variability alone didn’t drive downstream migration, although it can directly impact vegetation. 

The second variable the researchers analyzed was the amount of sediment a river can carry, or its sediment flux. They found that rivers carrying more sediment can erode more banks, also shifting river bends. However, rivers with more sediment but the same level of plant coverage had statistically similar bend angles. Thus, the researchers concluded that sediment flux alone can’t drive bend development, and that the changes were instead dependent on vegetation cover. 

The third variable they analyzed was riverbank strength. The researchers observed rivers with strong banks, made of rock or compacted sediment, and weak banks, made of loose sediment. They observed no difference in river bends with the same vegetation cover but different bank strengths. The researchers concluded that bank strength is also not the primary driver of bend migration in vegetated or unvegetated rivers. 

Of the 4 variables the researchers examined – flow variability, sediment flux, bank strength, and vegetation cover – vegetation cover consistently had the greatest impact on the appearance of meandering rivers. They concluded that meandering rivers could have existed before plants, but would have looked different. Like modern unvegetated rivers, ancient meandering rivers likely had lower-angle bends. As plants evolved and grew on river banks, the bends would have developed differently, becoming curvier like modern vegetated rivers. They suggested that understanding this process provides insight into life on Earth before plants evolved 450 million years ago. 

The post How did land plants change rivers? appeared first on Sciworthy.

Most people think of Mars as a big red dustball, but researchers recently found Martian mineral deposits suggesting it was once warm and humid. The team used the Compact Reconnaissance Imaging Spectrometer aboard NASA’s Mars Reconnaissance Orbiter to analyze specific wavelengths of visible and near-infrared light from minerals on Mars’s surface to determine their chemical composition from afar.

Past researchers identified layered silicate minerals, called clays, across the Martian surface. Clays form when water interacts with rock, and record the amounts and chemical compositions of the waters that formed them. As water interacted with Martian surface rocks, it picked up more mobile elements like magnesium and iron and carried them to lower depths in the Martian soils, while less mobile elements like aluminum stayed in place. This process, called leaching, created 2 distinct layers of clays in the Martian rocks. 

Scientists have proposed 2 main hypotheses for how these layered clays formed on Mars. The first is that they formed through underwater leaching in pools or lakes sometime in Mars’ past. The second is that they formed across the Martian surface, where a widespread humid environment provided the moisture needed to leach them. 

To evaluate these hypotheses, a team led by researchers at Purdue University recently estimated the “true” thicknesses of Martian clay layers with a method scientists had previously only used on Earth. Rock layers containing clays can become tilted, making them appear thicker or thinner than they actually are. To address this discrepancy, the team used the High Resolution Imaging Science Experiment (HiRISE) tool on the Mars Reconnaissance Orbiter to create high-resolution elevation maps of the Martian surface. Then they combined these maps with surface composition data from the Compact Reconnaissance Imaging Spectrometer to create 3D composition maps. 

Using the 3D composition maps, the researchers found where each clay layer was exposed at the surface and traced it underground to estimate an angle of tilt. They then used trigonometry to calculate the true thicknesses of each clay layer. They analysed 46 regions across the Martian surface, and found that the combined thickness of both clay layers was around 20 to 680 feet (6 to 200 meters), with an average of about 190 feet (60 meters). That’s a maximum thickness as high as a 60-story building! 

Next, the researchers tested the extent of the clay deposits in a large ancient Martian valley known as the Mawrth Vallis Region. They focused on this region because it had large elevation changes, and scientists in the past had already collected high-resolution chemical composition and elevation data there. 

They explained that if the clay layers were restricted to the lowest parts of the valley where water once existed, and had changing thicknesses and boundaries between layers, this would provide strong evidence in favor of the “underwater leaching” hypothesis. In contrast, if the clay layers were more widespread, with consistent layer boundaries and thicknesses, this would provide strong evidence of a humid surface environment, in favor of the “surface leaching” hypothesis. 

The researchers found that the clay layers extended beyond the lowest parts of the valley and had consistent layer boundaries across more than half a mile (about a kilometer) of elevation change. Thus, they concluded that the clay layers formed by surface leaching in a humid environment. 

These findings conflict with climate models of early Mars, which generally suggest that the Martian surface rarely got above freezing temperatures. To address this discrepancy, the team proposed that these deposits could have formed over a long period of time rather than in a consistently warm and wet environment. If the surface was frozen most of the time, but got above freezing in short bursts, these clay deposits could still have formed, just over a much longer time period. In this case, the Mars climate models and the researchers’ findings would agree.

The researchers acknowledged that their study has some limitations, particularly regarding the sparse sample locations. Though they found strong evidence for a widespread humid environment on early Mars, more in-depth studies of locations like Mawrth Vallis could better constrain the specific surface environmental conditions under which these clays formed and potentially reconcile their data with Martian climate models.

The post Clay minerals suggest a warm, wet past for Mars appeared first on Sciworthy.

The dream of clean hydrogen has tantalized energy experts for years, but producing it has been tough. Many start-ups think the answer could lie beneath our feet.

Greenhouse gases trap heat within the atmosphere. One such gas that exists beneath the ocean floor is methane. Ice-like substances on the seafloor that contain methane, known as methane hydrates, can break apart or melt, releasing methane gas into the ocean, risking further global warming. Melting permafrost, active tectonics, daily tidal patterns, and changing sea levels can similarly trigger methane’s escape from sediments. However, scientists don’t understand how these triggers will respond to future climate change.

A team of researchers hypothesized that future global warming could actually accelerate methane’s escape into the ocean. To investigate this hypothesis, they focused on an ancient global warming event approximately 56 million years ago, called the Paleocene-Eocene Thermal Maximum or PETM. Arctic Ocean temperatures at times exceeded 20°C (68°F) during this event. These elevated temperatures serve as an analog for today’s rapidly warming conditions. 

Once methane enters seawater, its fate is largely determined by 2 sets of biological processes. Today, 90% of methane released into the ocean from the seafloor is consumed by tiny organisms called microbes via a process known as anaerobic methane oxidation. During this process, microbes consume methane alongside sulfate, producing a solid iron-sulfur mineral, pyrite. Anaerobic methane oxidation prevents methane from escaping into the atmosphere by trapping it in minerals. In this case, the ocean becomes a reservoir, or sink, for methane. 

Despite this, too much methane could overwhelm the sulfate-dependent cycle. If that occurs, a different set of microbes consumes methane alongside oxygen in a process known as aerobic methane oxidation. Aerobic methane oxidation produces carbon dioxide, a potent heat-trapping greenhouse gas that escapes from the ocean. Aerobic oxidation accounts for 10% of methane consumption in oceans today, though this could have been different in the past. 

To determine how much anaerobic versus aerobic methane oxidation occurred during the PETM, the team extracted data from sediments retrieved from the Arctic Ocean floor. As sediment piles up on the seafloor, it compacts. Scientists can drill deep into the seafloor to extract a cylindrical sample, or core, of this compacted sediment. 

The age of sediments in a core increases with depth. Therefore, younger sediments exist at the top of the core, and older sediments exist at the bottom. For this project, the team used a previously extracted core from the Arctic Ocean that contained sediments dating back 100 million years. They found 56-million-year-old sediments from the PETM at a depth of 386 meters, or 1,266 feet, in this core. 

The researchers explained that microbes leave behind unique carbon-based molecules called organic biomarkers when they decompose. These organic biomarkers accumulate in seafloor sediments. The 2 different types of methane-consuming microbes leave behind 2 different biomarkers, one for anaerobic methane oxidation and one for aerobic methane oxidation. This team measured the amount of each biomarker in the sediment core to determine which microbes were dominant during the PETM. 

The biomarker left behind from microbes performing aerobic methane oxidation is called hop(17)21-ene. The researchers noticed that the amount of hop(17)21-ene increased by a factor of 4 during the PETM. At the same time, the biomarker left behind from microbes performing anaerobic methane oxidation, called glycerol dialkyl tetraether, decreased to half. They interpreted these trends to reflect the rise of aerobic methane cycling and the shutdown of anaerobic methane cycling, respectively. They attributed this transition to the release of enough methane to overwhelm the sulfate-dependent methane cycle under warming conditions.

To estimate the amount of carbon dioxide produced by aerobic methane oxidation during the PETM, the researchers located another biomarker in the sediment core, called phytane. Phytane is produced by organisms that consume carbon dioxide during photosynthesis, and its structure preserves clues to the amount of carbon dioxide available at the time. The researchers found that during and well after the PETM, the concentration of carbon dioxide in the Arctic Ocean was 4 times greater than modern levels. They concluded that the Arctic Ocean became a prolonged source of carbon dioxide to the atmosphere, even after the PETM.

The team suggested that the uptick in aerobic methane oxidation during the PETM serves as an analog for the modern Arctic Ocean, which continues to warm rapidly in the face of modern climate change. Their results highlight how the transformation of methane into carbon dioxide poses a threat. More carbon dioxide in the atmosphere warms the air, which heats the oceans, causing more methane to escape from the seafloor and eventually be converted into additional carbon dioxide. When triggered, this feedback would continue to amplify and could become difficult to recover from.  

The post Does the Arctic Ocean regulate or amplify global warming? appeared first on Sciworthy.

The continent of Africa is splitting into 2 tectonic plates in the middle of Ethiopia. In the recent past, geophysicists have improved their understanding of how tectonic plates like these separate. They’ve shown that continents begin to split apart as the crust and upper mantle, known as the lithosphere, crack and shift. Later, magma from deep within the Earth travels upward through these cracks to Earth’s surface, forming volcanoes. Therefore, scientists know that volcanoes form in areas of continental rifting, but not how quickly they form, which complicates efforts to assess volcanic hazards in rift zones.

Researchers led by Kevin Wong sought to answer this question by examining a mineral formed when magma cools, called olivine. They focused on 72 olivine crystals ranging in size from 1 to 4 millimeters (0.04 to 0.16 inches) from rocks collected at the Boku and Ziway volcanic fields in the Main Ethiopian Rift (MER) zone in Africa. They explained that the lithosphere in this area is still about 35 to 40 kilometers (21 to 25 miles) thick. This thick lithosphere suggests that the MER represents an intermediate stage of continental separation and offers a rare opportunity to study how tectonic stretching transitions into magmatic rifting in the process.

Wong and his team analyzed olivine because it’s one of the first minerals to crystallize from magma, and it continues to grow as the magma rises and cools. As magma rises, its composition changes, producing sharp chemical “zones” within the growing crystals, analogous to growth rings in trees. Changing temperatures and magma compositions cause different elements, like magnesium and iron, to diffuse into and out of the crystals at various rates during the magma’s ascent. So scientists can model these chemical zones and their boundaries in olivine crystals to determine how quickly the magma ascended from the upper mantle to erupt in the rift.

Wong and colleagues examined the olivine crystals from the MER volcanic fields using high-magnification imaging and chemical analyses, with an instrument known as an electron microprobe. Within each crystal, the team mapped 10 to 15 points spaced approximately 5 to 15 microns apart (about 10% of the thickness of a human hair) along a transect from the inner core to the outer rim, spanning its growth zones. 

They found 2 different populations of olivine crystals. The first consisted of normal-zoned crystals with magnesium-rich inner cores, and the second consisted of reverse-zoned crystals with lower magnesium cores. They explained that recently-formed magmas in the deep Earth contain higher amounts of the element magnesium relative to iron. The magnesium-rich zone has a sharp boundary with the magnesium-poor zone, but this boundary can get blurred when elements diffuse across it. Diffusion progressively smooths these crystal boundaries over time at known rates, so researchers can use their “blurryness” to extract information on how quickly the crystals equilibrated with the surrounding magma.

The researchers used numerical models to estimate how quickly magnesium and iron would diffuse across these chemical boundaries at different temperatures and surrounding magma chemistries. They compared thousands of simulated diffusion profiles to their measured olivine diffusion profiles. They used this iterative process to estimate that the crystals diffused, on average, for 40 and 17 days in the surrounding magma while ascending from the deep Earth to erupt at Boku and Ziway, respectively. They further tested these estimates using a growth-diffusion model that better represented natural crystal behavior. That model produced ascent times of about 27 days on average and better reproduced the crystal zoning patterns they observed.

Based on these models, the researchers concluded that intermediate-stage rifting events happen on unexpectedly short timescales. Magmas travel up to 40 kilometers (25 miles) from the deep Earth to the surface within, on average, a single calendar month, which is closer to human timescales than geologic timescales. They suggested that this rapid ascent is likely due to highly developed magmatic plumbing systems in the lithosphere that form before much lithospheric thinning. However, they noted that their results still suggest a wider range in ascension timescales than optimal for disaster mitigation and prediction. 

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The years 2023 and 2024 were the warmest on record, coinciding with a powerful Pacific climate event known as El Niño. El Niño is the warm phase of a natural climate cycle in which surface waters in the eastern Pacific are unusually warm, bringing record-breaking heatwaves in the Amazon and heavy rainfall in the southern USA. Its counterpart, La Niña, is the cool phase that brings wetter conditions to the Northern USA. 

In a typical El Niño, warm water in the eastern Pacific weakens the winds blowing westward across the tropical Pacific, known as trade winds, allowing more warm water to flow eastward – a self-reinforcing cycle that amplifies the event. However, the 2023 El Niño differed because the ocean warmed intensely, but the trade winds remained strong. Researchers from the Scripps Institution of Oceanography, led by Qihua Peng and Shang-Ping Xie, recently investigated how and why this unusual event occurred.

First, the researchers tracked how air pressures changed across the Pacific during the event using a metric calculated by NOAA, known as the Southern Oscillation Index. When the eastern Pacific warms during an El Niño, the difference in air pressure across the Pacific typically decreases. In 2023, they found that temperatures in the eastern Pacific rose to more than 3°F (2°C) above normal, yet the drop in air pressure was only about 31% as strong as they expected. They also calculated that changes in wind speed and direction could only account for about 30% of the warming. So why was the 2023 El Niño so strong?

To answer this question, the research team then looked beyond the Pacific, analyzing sea surface temperatures from NOAA satellite data. They found that the North Atlantic and Indian Oceans also experienced record-breaking heat in 2023, with temperatures in the North Atlantic exceeding 2°F (1°C) above normal – the warmest in recent history. This suggested that El Niño events can develop in response to ocean conditions worldwide, not just those in the Pacific.

Next, the team used a computer program that simulates how the atmosphere responds to ocean temperatures, called the Community Atmosphere Model, to examine how heat from other oceans affects the Pacific. They found that heat in the North Atlantic and Indian Oceans generated large columns of hot air rising over those regions. This air cooled at high altitudes and then sank over the central Pacific, strengthening a large-scale loop of rising and sinking air that drives trade winds westward. Strengthening this circulation worked against El Niño by keeping trade winds blowing westward about 30% more strongly than Pacific warming alone would have. If the trade winds remained strong, why was the eastern Pacific so warm in 2023?  

To answer this question, the researchers studied 3 consecutive La Niña years between 2020 and 2023, analyzing ocean temperature and sea level data from NOAA’s Global Ocean Data System. During those years, strengthened trade winds transported heat into the western Pacific. As the seawater got warmer, it expanded, a process known as thermal expansion. Over those 3 years, thermal expansion and constant wind created a “pile” of warm water in the western Pacific, which reached its highest level of stored heat since 1982. When the trade winds eventually relaxed as La Niña faded, this piled-up warm water surged eastward, setting the stage for the El Niño event.

To test whether this stored heat alone could drive an El Niño, the team used a computer program that models oceanic and atmospheric interactions, called a coupled general circulation model. They input observed ocean temperatures from April 1, 2023, when La Niña ended, but removed all wind changes after that date. Their model successfully reproduced 87% of the warming observed between June and December 2023, which suggested that trade winds contributed just 13%. Stored heat was carried eastward by massive underwater waves traveling along the equator. As these waves reached the Eastern Pacific, they pushed cold water deeper, allowing surface water to warm. The researchers concluded that this oceanic process drove the 2023 El Niño to develop without the usual wind-driven feedback.

The team suggested that in a warming world, large heat reservoirs in the western Pacific will likely become more common, leading to more frequent strong El Niños. However, because their analysis focused on a single event, it remains unclear how often El Niños develop through oceanic processes alone. Ultimately, their study showed that the ocean can be more than a passive partner in El Niño – it can be the driving force.

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Mauna Loa in Hawaii is the world’s largest active volcano, and its 2022 eruption was the volcano’s 34th since 1843. But why is such a giant volcano located in the middle of the...

The post Why is the world’s largest volcano in the middle of nowhere? first appeared on Science Illustrated.