Sunday, April 19, 2026

 

Andes volcanoes – the missing link between algae blooms, whales and climate millions of years ago



Record volcanic eruptions in the Andes could explain the mysterious death of dozens of whales about 5 to 8 million years ago, according to a study led by University of Arizona researchers.




University of Arizona

Researchers in the field 

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Researchers work in the field at Cerro Ballena near Caldera, Chile, as part of a study showing that an increase in volcanic activity in the Andes in the Late Miocene Epoch likely resulted in a cooling of the Earth between 5.4 million and 7 million years ago. From left are team members Carolina Gutstein, Mark Clementz, Barbara Carrapa, Whitney Worrell, Priscilla Martinez and Fabían Muñoz.

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Credit: Carolina Gutstein





In 2010, construction workers on the Panamerican Highway traversing Chile's Atacama Desert stumbled upon a nearly perfectly preserved fossilized whale – and once paleontologists rushed to the site to document the ancient treasures in a race against time while the road project was on hold, more were unearthed in quick succession. 

Totaling more than 40 specimens – whales, porpoises and other marine mammals – dating from about 6 to 9 million years ago, the site known as Cerro Ballena, or "Whale Hill," is now famously recognized as the world's largest concentration of whale fossils. Paleontologists soon realized the animals perished quickly and in a relatively small area. But why?

As if one mystery wasn't enough, around the same time marine life experienced important changes, whales became bigger and climate data reveal a dramatic shift toward cooler sea surface temperatures. Geologic records from that time, known as the late Miocene, bear witness to intense volcanic eruptions in the wake of tectonic upheaval that led to the building of the Andes mountain range along the western edge of South America. 

Now, a study led by researchers at the University of Arizona provides a previously unrecognized piece of the puzzle: The vast amounts of volcanic ashes released into the atmosphere ended up in the ocean, particularly in the Southern Ocean, where they provided a smorgasbord for marine algae to feast on. Volcanic ash is known to contain important nutrients, including phosphorus, iron and silicon. A significant increase in volcanic activity in the Andes peaking between eight and four million years ago, therefore, likely delivered a significant pulse of nutrients – especially iron – to the Southern Ocean.

This induced a chain reaction driving environmental changes by increasing productivity among primary producers – organisms that consume carbon dioxide and use sunlight to create their own food and energy. Increased productivity also supported larger body size in whales. However, in some localities, like Cerro Ballena, nutrients from Andes volcanoes lead to widespread algal blooms, which released toxins that proved detrimental to any whales in the affected areas. The same algal blooms also would have removed large amounts of carbon dioxide, a powerful greenhouse gas, from the atmosphere, which would have helped cool the planet. 

Volcanic eruptions have long been recognized as major sources of carbon dioxide in the atmosphere before humans began burning fossil fuels on an industrial scale, thus driving warming. But the role of volcanism in doing the opposite – cooling down the Earth system – has gone largely unrecognized, said Barbara Carrapa, a professor of geosciences in the University of Arizona College of Science and first author of this study, which is published in the journal Nature Communications Earth & Environment.

"Once you put a lot of very important nutrients coming from volcanoes into the ocean, then your primary producers are going to go crazy, because all of a sudden they have a lot of nutrients available to them, and that, in turn, is going to affect the entire marine ecosystem," she said. 

Among those primary producers, some of the globally most abundant are diatoms, single-celled algae that build intricate silicate shells. 

Bringing together experts from a variety of fields, including climate modeling, ocean geochemistry, geology and paleobiology, the study showed that Andean volcanoes provide the missing link between changes in ocean geochemistry and marine ecosystems and ultimately resulted in carbon sequestration and global cooling via biological processes in the ocean. Surprisingly, the geochronology of volcanic ashes in the region and the relationships between volcanism, ocean productivity and ultimately climate had been largely unexplored. 

By combining paleoclimate records, fossil evidence and geologic data with computer climate modeling simulations, the study shows a potential link between sustained, large-scale volcanism in the Altiplano-Puna Volcanic Complex in the Central Andes, the largest active silicic magma system on Earth, and global climatic and ecological change.

The Miocene witnessed a major transition in both geography and climate, continuing a cooling trend that had begun around 60 million years ago, at the end of Mesozoic era, also known as the "Age of the Dinosaurs." The continents had taken their present-day positions for the most part, only Antarctica was covered by ice, extensive forests were replaced by grasslands in many places of the world, and mammals were diversifying. 

According to co-author Kaustubh Thirumalai, an associate professor in the U of A's Department of Geosciences, the Miocene was a time of profound change, establishing the ecosystems we see today. Giant mammals roamed the continents, including ground sloths, mammoths and whales, which had set out as moderately sized creatures, embarked on an evolutionary trend toward the gigantic sizes they are known for.

Not surprisingly, the cooling trend, particularly during the late Miocene, was accompanied by declining carbon dioxide levels in the atmosphere, but the exact cause was a mystery, Thirumalai said. Was the change caused by a decrease in volcanic activity releasing less carbon dioxide, or by an increase in chemical weathering, which takes carbon dioxide out of the atmosphere? 

To find answers, the team took advantage of climate simulation models to test various scenarios, Thirumalai explained. 

"To illustrate our approach, we'd say, 'Let's start erupting the Andes on purpose and see what happens,'" he said. "And what we found is that there is another component that wasn't really appreciated – the biology of the ocean responds, with feedback effects on climate worldwide."

These feedback mechanisms can help store carbon in the deep ocean resulting in global cooling, Carrapa explained.

"Once you take the biological effects of volcanoes fertilizing the ocean into consideration, we could see a beautiful correlation between Andean volcanism and all those changes that are happening in the ocean, specifically those looking at the late Miocene cooling event," she said. "Together with the Humbold Current, which serves to distribute nutrients along the Pacific coast of South America, everything together created the perfect storm where, if you put the ash in the right place, and you ignite primary production, you eventually affect marine ecosystems as a whole, including whales."

"This work improves our understanding of how natural processes can regulate Earth's climate, which is directly relevant to anticipating future climate change and its impacts on society," said co-author and whale expert Mark Clementz, a professor of geology and geophysics at the University of Wyoming and co-author of this study. "By identifying links between volcanism, ocean productivity, and carbon dioxide drawdown, it provides insight into mechanisms that can influence global climate over long timescales."


Now extinct, Cerro Aconcagua in northwestern Argentina was an active stratovolcano until the Miocene epoch, when it was part of the Altiplano-Puna Volcanic Complex in the Central Andes, the largest active silicic magma system on Earth.

Two of the study's co-authors, Mark Clementz and Carolina Gutstein, are pictured with an outcrop bearing whale fossils.

Credit

Barbara Carrapa

 

Tectonic “pump” may close the evolutionary loop for subseafloor microbes






Seismological Society of America





In subduction zones, the sites of the world’s largest earthquakes, tectonic activity may generate a “pump” that transports long-buried subseafloor microbes back toward the seafloor, according to research presented at the 2026 SSA Annual Meeting.

These microbes are the world’s most dedicated sleeping beauties, lying dormant for thousands or even millions of years beneath a kilometer-deep blanket of ocean sediment. They survive this prolonged dormancy with the help of a range of specialized adaptations.

But to pass on these adaptations to the next generation, the microbes must eventually reach the shallowest layers of the seafloor where they can eat, grow and disperse.

That’s where the tectonic pump comes in, said Zhengze Li, a Ph.D. student at the University of Southern California.

Li and his colleagues suggest that fault slip in subduction zones drives fluid flow that transports long-buried subsurface microbes back toward the seafloor. According to their models, this tectonic pump could circulate more than 1 million gigatons of fluid per million years, potentially transporting up to 1030 microbial cells.

At the meeting, Li explained how this microbial “elevator” might work. In subduction zones, where one tectonic plate descends beneath another, layers of sediment on the downgoing plate are scraped off and accumulate in a wedge against the overriding plate.

Some of the deep, dormant microbes remain on the downgoing plate and continue their descent beneath the overriding plate toward the mantle, a journey Li and his colleagues call “the trip to hell.”

Microbes that avoid that fate, however, may be transported upward through fractures and faults in the sediment wedge, or more diffusely through the sediments, driven by subduction-related slip.

Relocated to the shallow seafloor, the microbes “can now be reactivated and can reproduce,” Li said. “The full cycle—from burial and transport with the subducting plate to eventual return—can take tens of millions of years or longer.”

Cold seeps on the seafloor, where fluids are preferentially discharged from the subseafloor, provide direct evidence of active fluid transport and are consistent with ongoing tectonic pumping. These seep sites also offer accessible windows for sampling microbial communities, enabling further evaluation of the relationship between tectonic processes and subseafloor microbial life.

“We can also examine how seismic activity relates to the relative abundance of different microbial groups, and we find a positive correlation between seismic energy and the abundance of subsurface-associated microbes,” Li said.

The researchers have examined this idea in the subduction zone of Costa Rica and found that higher seismic energy indices are associated with greater relative abundance of microbial taxa typically found in subsurface environments.

Tectonic pumping is not limited to large earthquakes, Li added. Even seismically “silent” slow slip events, tremor, and aseismic creep can generate stress perturbations that drive fluid mobilization and microbial transport.

Research by Li’s coauthor Karen Lloyd, a microbial biogeochemist also at USC, and others has identified a range of adaptations that allow deep-buried microbes to survive long-term dormancy, including DNA repair mechanisms and enzymes that enable the degradation of organic matter at depth.

Genomic studies further suggest that mutations in these microbes often act to preserve traits over thousands to millions of years.

For a chance to pass on these adaptations and undergo genetic innovation, the microbes have to wait for the tectonic elevator to bring them to a more hospitable realm.

Graphitized biochar rewires soil microbes to accelerate pollutant breakdown in rice paddies






Biochar Editorial Office, Shenyang Agricultural University

Geoconductor function of graphitized biochar redirects microbial Fe(III) reduction and stimulates hydroxyl radical production in paddy soil 

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Geoconductor function of graphitized biochar redirects microbial Fe(III) reduction and stimulates hydroxyl radical production in paddy soil

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Credit: Hua Shang, Chao Jia, Song Wu, Ning Chen, Yujun Wang & Xiangdong Zhu





A new study reveals that a specially engineered form of biochar can dramatically enhance the natural ability of soil microbes to break down pollutants in rice paddies, offering a promising strategy for cleaner and more sustainable agriculture.

Researchers have developed a highly conductive “graphitized biochar” that acts as an electronic bridge in soil, enabling faster and more efficient interactions between microorganisms and iron minerals. This process boosts the formation of highly reactive molecules that can degrade harmful contaminants such as antibiotics.

“By improving the electrical properties of biochar, we found a way to fundamentally change how electrons move through soil systems,” said the study’s corresponding author. “This allows microbes to work more efficiently, ultimately accelerating pollutant removal in agricultural environments.”

Rice paddies are known to accumulate organic pollutants, including antibiotics from manure and irrigation water. These contaminants can persist in soils at levels exceeding natural degradation capacity. One key pathway for breaking them down involves hydroxyl radicals, highly reactive molecules that can rapidly oxidize pollutants. However, the production of these radicals depends on microbial processes that are often limited by inefficient electron transfer.

To address this challenge, the research team used a rapid heating technique known as flash Joule heating to transform conventional biochar into a more graphitized structure. This modification increased the material’s electrical conductivity by more than twofold, enabling it to function as a “geoconductor” that facilitates long-range electron transport in soil.

Laboratory experiments showed that this graphitized biochar significantly enhanced microbial iron reduction, a key step in generating reactive species. Compared to untreated conditions, the modified biochar increased the production of reactive iron species by nearly 19 percent and boosted hydroxyl radical formation by more than 50 percent.

As a result, the degradation rate of the antibiotic sulfamethoxazole improved substantially, with removal efficiencies reaching complete degradation under experimental conditions. In contrast, soils without the modified biochar showed much lower pollutant removal.

The study also found that the material reshaped soil microbial communities. Beneficial bacteria capable of reducing iron became more abundant, creating a positive feedback loop that further enhanced electron transfer and pollutant breakdown.

Importantly, the effectiveness of the graphitized biochar varied across different soil types, depending on the native microbial community and soil properties. Soils with more active microbial populations showed the greatest improvements, highlighting the importance of biological factors in environmental remediation.

Beyond its immediate application in pollutant removal, the research challenges long-standing assumptions about how biochar functions in soil. Traditionally, biochar has been viewed as an “electron reservoir” that stores and releases electrons through surface chemical groups. This study demonstrates that its role as an electron conductor may be even more critical.

“Our findings suggest that facilitating direct electron transfer, rather than simply storing electrons, is the key to unlocking biochar’s full potential in soil remediation,” the authors noted.

The results open new avenues for designing advanced carbon-based materials that work in harmony with natural microbial processes. Such approaches could help reduce contamination risks in agricultural systems while supporting sustainable soil management practices.

As global concerns grow over soil pollution and antibiotic residues in food production, innovations like graphitized biochar may offer scalable solutions that harness the power of both materials science and microbiology.

 

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Journal Reference: Shang, H., Jia, C., Wu, S. et al. Geoconductor function of graphitized biochar redirects microbial Fe(III) reduction and stimulates hydroxyl radical production in paddy soil. Biochar 8, 92 (2026).   

https://doi.org/10.1007/s42773-026-00597-w   

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About Biochar

Biochar (e-ISSN: 2524-7867) is the first journal dedicated exclusively to biochar research, spanning agronomy, environmental science, and materials science. It publishes original studies on biochar production, processing, and applications—such as bioenergy, environmental remediation, soil enhancement, climate mitigation, water treatment, and sustainability analysis. The journal serves as an innovative and professional platform for global researchers to share advances in this rapidly expanding field. 

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‘Tis the season: Sharing resources sustains ocean microbial biodiversity




University of Hawaii at Manoa
Water sampler 

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A view of the rosette water sampler as it ascends toward the surface to collect samples. 

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Credit: Hawai'i Ocean Time-series





Oceanographers from the University of Hawai‘i at Mānoa discovered that microbial communities–from the sunlit surface to extreme depths–in the North Pacific Subtropical Gyre exhibit robust seasonal cycles. The study provides new insight into how high levels of biodiversity are maintained in the open ocean. 

“A long-standing question in biological oceanography, which we refer to as the “paradox of the plankton”, asks: How can open ocean species diversity be so vast and sustained, in a seemingly homogeneous environment like the open ocean?,” said Fuyan Li, lead author of the study and affiliate researcher in the Center for Microbial Oceanography: Research and Education in the UH Mānoa School of Ocean and Earth Science and Technology (SOEST).

The blue, deep waters of the Pacific Ocean have extremely low nutrient concentrations compared to coastal areas that teem with visible life, such as kelp forests off California or coral reefs in Hawai‘i. 

“Theoretical ecology suggests that one way co-occurring species diversity can be maintained, is if shared resources, such as nutrients, are used at different times of year, thereby minimizing competition,” Li shared. “Though seasonal cycles are a fundamental property of many diverse ecosystems, seasonality in the tropics is less pronounced than in temperate or polar ocean habitats.”  

Tracking microbes through DNA

To determine whether microbial communities at Station ALOHA, a tropical, open ocean research station 60 miles north of O‘ahu, Hawai‘i, have seasonal cycles, Li and colleagues analyzed microbial DNA in samples collected monthly over eight years. The combination of frequent sampling over a long time period, and high-resolution species identification, allowed the researchers to make these new and unprecedented open ocean observations. 

They found that more than 60% of the microbial groups they tracked exhibited seasonal cycling. While these seasonal cycles diminished at depths below 150 meters, surprisingly, they remained measurable in some deep-sea microbial species at depths of nearly two and a half miles. 

“Notably, very closely related species or subspecies “bloomed” at different times of the year, similar to seasonal patterns observed in some terrestrial plants and animals,” Li said. “Taking turns with respect to nutrient use throughout the year seems to be a key ecological strategy for microbial communities to maintain their diversity.”

By sustaining their populations throughout the year, microbial communities consistently supply organic matter and energy to organisms higher in the food web, for example larval fish. In this way, microbes ensure the stability of the marine food web and productivity in waters across the Pacific Ocean.


Nighttime sampling operations 

Researchers deployed a rosette water sampler to colllect water from the surface to the deepest depths at Station ALOHA, 60 miles north of O‘ahu, Hawai‘i.

Credit

Fuyan Li, University of Hawai‘i at Mānoa