Destined to melt

ISTA study confirms: Glaciers are fighting a losing battle against climate change

Institute of Science and Technology Austria

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Cold air flows down on a warm day. Tsanteleina Glacier, northwestern Italy. 

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Credit: © Thomas Shaw | ISTA

Glaciers are fighting back against climate change by cooling the air that touches their surfaces. But for how long? The Pellicciotti group at the Institute of Science and Technology Austria (ISTA) has compiled and re-analyzed an unprecedented dataset of on-glacier observations worldwide. Their findings, published today in Nature Climate Change, demonstrate that glaciers will likely reach the peak of their self-cooling power by the next decade before their near-surface temperatures spike up and melting accelerates.

Thomas Shaw keeps a vivid memory of this special summer day in August 2022. The postdoctoral researcher in Francesca Pellicciotti’s group at the Institute of Science and Technology Austria (ISTA) was in the Swiss Alps, with a blue sky and a pleasant temperature of 17 degrees Celsius. Except that he was on top of the Glacier de Corbassière, at an altitude of 2,600 meters, collecting data about the glacier’s health.

Are glaciers taking it too cool? While ambient temperatures have been increasing steadily worldwide, the near-surface temperatures of glaciers seem to be lagging behind. The massive Himalayan glaciers are even blowing cold winds down their slopes in an attempt to cool themselves and preserve their ecosystems. Yet, this strange effect is far from being an indicator of the glaciers’ long-term stability.

A new study led by Shaw demonstrates that this reaction of glaciers is likely to reach its peak in the 2030s. “The more the climate warms, the more it will trigger the glaciers to cool their own microclimate and local environments down-valley,” says Shaw. “But this effect will not last long, and a trend shift will ensue before the middle of the century.” From then on, the glaciers’ melting and fragmentation due to human-caused climate change will intensify, and their near-surface temperatures will rise more rapidly, hastening their decline.

Large glaciers and cold winds

It takes a tremendous effort to understand local climate effects in some of the world’s remotest areas and map their evolution on a global scale. Often, on-site data is simply lacking. This poses a challenge to the precision of computational models which simulate the climate’s detailed evolution. When Pellicciotti and her collaborators first saw the data collected at a 5000-meter-high climate station on the slopes of Mount Everest, they could hardly believe their eyes. “Upon examining the data thoroughly, we understood that the glaciers were reacting to the warming air in summer by intensifying their temperature exchange at the surface,” Pellicciotti says. Due to the sheer size of the Himalayan glaciers, this results in the cooling of large air masses in direct contact with the glacier surfaces. “These large, dense cold air masses then flow down the slopes with the effect of gravity in a phenomenon called ‘katabatic winds.’” Other large glaciers around the world behave similarly.

Scientists going out of their way

Now, Shaw sought to develop a robust global model that overcomes the limitations of data scarcity. He developed a new method to estimate how long glaciers would continue to absorb the climate shock worldwide. “We compiled data from past and recent projects across our research group, pooled them with all published data, and reached out to other researchers to request that they share with us their unpublished data,” says Shaw. “Using this unprecedented dataset, we reassessed the physical processes to find generalizable aspects and developed a statistical framework that can give us a glimpse into the evolution of glacier cooling worldwide.”

Peak cooling

Shaw and the team compiled an inventory of hourly data from 350 weather stations located on 62 glaciers worldwide, representing a total of 169 summer-long measurement campaigns. They specifically examined the ratio of near-surface temperature to ambient, non-glacier temperature right above each station and analyzed it over space and time. “We call the difference in temperature ‘decoupling,’ because it seems at odds with the warming of ambient temperatures,” says Shaw. They showed that, on average, the near-surface temperature on mountain glaciers worldwide warmed 0.83 degrees Celsius for every degree rise in ambient temperature.

They also investigated the glacier properties most likely to limit the decoupling effect, such as the presence of a debris mantle on the lower part of a glacier, and refined their model with this information. By modeling future projections, they demonstrated that this cooling effect will peak between the 2020s and 2040s, before the glaciers’ steady mass loss leads to their large-scale retreat, reversing the cooling trend. “By then, the worn-out and considerably degraded glaciers will ‘recouple’ to the steadily warming atmosphere, sealing their fate,” says Shaw.

Accepting the loss and coordinating future actions

While the projection paints a bleak future for the world’s majestic water towers, there are pragmatic consequences if the current trend continues. “Knowing that the glaciers’ self-cooling will continue a little longer could buy us some extra time to optimize our water management plans over the next decades,” says Shaw.

However, the team is fully aware that they can neither salvage nor recover the world’s mountain glaciers. “We must accept the committed ice loss and put our full efforts into limiting further climatic warming rather than into ineffective geo-engineering strategies such as seeding clouds and covering glaciers. These are like putting an expensive Band-Aid on a bullet wound. The coming decades are a time for reflection, effective water management, and action to change public consciousness about human-caused climate change.” The researchers further underline the need for coordinated global climate policies to drastically reduce emissions and safeguard human life on Earth from the unforeseeable effects of global warming. “Every bit of a degree counts,” says Shaw, echoing the words that scientists have been stressing for decades.

Video: Melting Pasterze Glacier in Austria. [VIDEO] 

Drone footage over the glacier. Research on katabatic winds was conducted there in the 1990s.

Credit

© Thomas Shaw | ISTA

Installing a station on the Glacier de Corbassière, Swiss Alps. ISTA researcher Thomas Shaw looking upward to the Grand Combin. 

Credit

© Pascal Buri

Journal

Nature Climate Change

DOI

10.1038/s41558-025-02449-0 

Method of Research

Computational simulation/modeling

Subject of Research

Not applicable

Article Title

Mountain Glaciers will Recouple to Atmospheric Warming Over the 21st Century

Article Publication Date

10-Oct-2025

 

Old tricks, new tech: Scams in the age of AI

Gabriel Aguilar’s research highlights AI scams and how technical writing can prepare students to spot deception

University of Texas at Arlington

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headshot of Gabriel Aguilar

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Credit: UT Arlington

As a college student, Gabriel Aguilar fell victim to an elaborate scam. The fraudsters posed as employers offering job opportunities that provided quick income.

He completed what seemed like a legitimate interview process, was offered a position and was even sent a check to purchase a laptop—which included a note from the perpetrators to send them the change. The scam was to unfold with the check bouncing and Dr. Aguilar being out his own money. Thankfully, his bank flagged the check because of typos and errors.

Aguilar, now an assistant professor of technical writing and professional communication in The University of Texas at Arlington’s Department of English, examines how today’s scammers are employing artificial intelligence (AI) to help con the public—in particular, the Latino population, which is often targeted.

Years ago when Aguilar was scammed, the world had not yet seen the explosive increase in AI use. If fraudsters had tried the same scam with AI today, would it have been more likely to succeed and Aguilar be successfully scammed out of money?

Aguilar’s new research aims to decrease the likelihood of vulnerable populations falling victim to AI scams by increasing his students’ AI literacy through technical writing skills.

Technical writing courses teach students how to present complex or specialized information in a way that’s clear, precise and easy for the intended audience to understand. It helps people grasp a subject, follow instructions or make informed decisions.

Aguilar’s study, recently published in the Journal of Business and Technical Communication, explores how AI scammers target susceptible populations by using age-old exploitation tactics enhanced by the rapid technological advances of this new era. His research notes deepfake, voice-cloning and AI voice bots as some of the most commonly used AI tactics to modernize some of the oldest tricks in the scammer’s playbook.

“In my field, there’s a growing consensus that when humans and AI work together, they enter into what we call creative partnerships—usually to produce work with positive and good intentions,” Aguilar said. “I pick up on the conversation and look at how these creative partnerships are happening with people who nefariously use AI in order to scam others.”

And so, for students to gain a comprehensive grasp of potential AI scams, Aguilar outlined a four-part framework for technical and professional communication instructors to use when teaching about AI.

“Essentially, this framework is to teach that AI didn’t revolutionize scamming—it gave scammers more tools to make their scam tactics more convincing,” Aguilar said. “And after students learn to detect when something is off, they can disseminate the information back to their families and communities to incrementally raise AI literacy.”

Courses like technical writing, Aguilar said, are valuable to prepare students for life beyond graduation, to teach skills that are transferable to meaningful career opportunities and to help them think critically about those opportunities.

“For me, technical writing is a tool to help dissolve blinders people may put up and get them to think and quickly see when things seem too good to be true,” Aguilar said.

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Journal

Journal of Business and Technical Communication

 

Biochar and plants join forces to clean up polluted soils and boost ecosystem recovery

Biochar Editorial Office, Shenyang Agricultural University

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Biochar-driven rhizoremediation of soil contaminated with organic pollutants: engineered solutions, microbiome enrichment, and bioeconomic benefits for ecosystem restoration
 

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Credit: Nandita Das & Piyush Pandey

Soil pollution from pesticides, pharmaceuticals, and industrial chemicals is a growing threat to global food security and public health. With nearly 80 percent of agricultural soils containing traces of organic contaminants, researchers are looking for sustainable ways to restore damaged land. A new study in Biochar highlights an emerging solution that pairs plant-microbe partnerships with biochar, an engineered carbon-rich material, to detoxify polluted soils while supporting plant growth and economic resilience.

The review, led by Nandita Das and Piyush Pandey, explores how combining biochar with rhizoremediation, a nature-based process that uses plant roots and beneficial microbes to break down pollutants, can greatly enhance soil restoration. Biochar acts as both a catalyst and a habitat for microbes, improving soil structure, nutrient availability, and the bioavailability of pollutants for microbial degradation. This synergy accelerates the breakdown of contaminants such as crude oil, pesticides, polycyclic aromatic hydrocarbons (PAHs), antibiotics, and plastic residues.

“Biochar doesn’t just trap pollutants—it creates a thriving environment where plants and microbes can work together to clean the soil naturally,” said Pandey. “This approach supports ecosystem restoration while aligning with circular bioeconomy goals.”

The study highlights how biochar’s porous structure and surface chemistry can be fine-tuned through “bioengineering” to optimize contaminant removal. Meta-omics tools—such as metagenomics and metabolomics—help researchers identify the most active microbial communities in the biochar-enhanced rhizosphere. These insights pave the way for designing precision remediation strategies suited to different pollutants and soil types.

Beyond its environmental benefits, the biochar market itself is expanding rapidly, valued at 2.05 billion USD in 2023 and projected to nearly double by 2032. Its increasing use in agriculture and waste management demonstrates how sustainable technologies can also generate economic opportunities.

The authors emphasize that integrating biochar into rhizoremediation offers a scalable, low-cost, and eco-friendly route for restoring contaminated soils. By turning agricultural residues and organic waste into high-value remediation materials, the approach contributes to carbon sequestration, climate mitigation, and biodiversity protection.

“This is not just soil cleanup—it’s ecosystem healing,” said Das. “Biochar-assisted rhizoremediation brings us closer to a future where pollution control and sustainable agriculture go hand in hand.”

 

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Journal Reference:  Das, N., Pandey, P. Biochar-driven rhizoremediation of soil contaminated with organic pollutants: engineered solutions, microbiome enrichment, and bioeconomic benefits for ecosystem restoration. Biochar 7, 101 (2025). https://doi.org/10.1007/s42773-025-00491-x  

 

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About Biochar

Biochar 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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Journal

Biochar

DOI

10.1007/s42773-025-00491-x 

Method of Research

Literature review

Subject of Research

Not applicable

Article Title

Biochar-driven rhizoremediation of soil contaminated with organic pollutants: engineered solutions, microbiome enrichment, and bioeconomic benefits for ecosystem restoration