A window into the future of Amazonia

New research from a team of tropical biologists forecasts some of the changes that may occur in the Amazon rainforest as temperatures rise due to climate change

University of Miami

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It’s a place where few living things can survive in the water.

Deep in the world’s largest rainforest, there is a boiling river. Found in eastern central Peru, it is a small tributary that eventually leads to the Amazon River.

Heated by cracks in the Earth’s crust, at its warmest spots, the water can reach 200 degrees Fahrenheit, an inhospitable environment with air temperatures hotter than anywhere else in the Amazon.

But the steamy river, known locally as “Shanay-Timpishka,” which translates as “boiled with the heat of the sun,” also offers an interesting perspective on what may happen to plant and tree communities as climate change pushes temperatures upward. After visiting in 2021, a team of University of Miami biologists recognized that the boiling river could serve as a natural experiment.

“It really provides us a window into the future because the Amazon will get hotter whether we like it or not, so this allows us to understand what increases in temperature will do to the forest composition,” said Riley Fortier, lead author on a study of the site published recently in Global Change Biology, and a graduate student in professor Kenneth Feeley’s Jungle Biology lab. “It can tell us which species will be lost, and what the makeup of the forest might be like in the future.”

The boiling river, a tributary of the Amazon River.

The team returned to Peru in 2022 and mapped the tropical plants and trees found in the area at 70 locations, starting upstream, where temperatures were cooler, down to the hottest part of the boiling river, where air temperatures often exceed 110 degrees Fahrenheit.

By examining forests for about a mile along the sweltering river and monitoring temperatures with onsite sensors, the team found several insights. They saw that plant diversity declined in the hottest parts of the river—with an 11 percent drop in tree diversity per each degree of warming—and that only plants suited for very warm tropical climates are able to thrive near the boiling river. Their results predict how tropical rainforests could look in the future Amazon as global warming continues.

“Overall, the tree community is less diverse, so we see fewer species in hotter spots,” Fortier said. “And forest composition was also more homogenous in the warmest locations, whereas in cooler forest plots, there was more plant diversity.”

One thing that surprised Fortier was how quickly the vegetation changed along the river.

“We saw a very directional change in composition, where the hottest part of the forest along the river had a greater representation of species that grow in hotter areas of the Amazon,” Fortier added. “Then, there was a drastic change in species as you moved away from the hottest part of the river. Usually, you wouldn’t see such a clear change in the species composition over such a short distance.”

For example, Fortier and Feeley saw that the hotter areas around the boiling river were drier and had more vines and scrubby vegetation. The trees were also smaller and less diverse, similar to a transition zone between a forest and a savanna ecosystem, but all within less than a mile of lush, green jungle.

“Over the course of dozens of miles, you might expect to see dramatic changes like that, but in the small sampling area that we had, you typically wouldn’t see such a clear change in composition,” Fortier added.

From left: A research collaborator along with biology professor Ken Feeley, and graduate students Alyssa Kullberg and Riley Fortier.

Feeley’s lab will continue its research of the boiling river, since it is such a unique place that could portend much about our natural world.

“You can’t heat a whole forest, at least not artificially, which is one of the coolest aspects of the boiling river,” Fortier added. “It’s a useful system because we can isolate temperature as having such an important effect on an entire plant community. At the boiling river, the rainfall, soil, and humidity are constant, but what we see is that as global warming happens, everything will change.”

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Journal

Global Change Biology

DOI

10.1111/gcb.17555 

Method of Research

Experimental study

Subject of Research

Not applicable

Article Title

Hotter Temperatures Reduce the Diversity and Alter theComposition of Woody Plants in an Amazonian Forest

 

UC Irvine-led study notes need for better wildfire readiness in Eastern Coachella Valley

Improving communication is key in disadvantaged communities in unincorporated areas

University of California - Irvine

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Irvine, Calif., Jan. 29, 2025 — A study led by the University of California, Irvine Joe C. Wen School of Population & Public Health highlights the need for improved wildfire preparedness tailored to disadvantaged communities in unincorporated areas of the Eastern Coachella Valley and identifies effective ways to bridge critical communication gaps.

 

Recently published online in the International Journal of Disaster Risk Reduction, the research found that people living in geographically isolated regions of ECV may benefit from enhanced community-level social interactions to strengthen their awareness of wildfire risk.

 

“Residents in ECV face unique challenges, from linguistic barriers to marginal government support,” said corresponding author Jun Wu, UC Irvine professor of environmental and occupational health. “Our findings demonstrate the importance of fostering community ties; collaborating with emergency services; and implementing multilingual, culturally sensitive education campaigns to boost risk perception and preparedness.”

 

Between February and April 2023, the research team surveyed 115 individuals in four unincorporated EVC communities who had experienced wildfires. Nearly all of them self-identified as Hispanic/Latino, and 60 percent reported annual household incomes of less than $25,000.

 

The study provided insights into communication channel preferences among different demographic groups, which emphasized the need for a multifaceted approach. Short text messages and TV were preferred across all groups, while younger adults leaned heavily on social media. Older adults and those with limited education trusted their doctors for information, and agricultural workers relied on text messages and personal observations for updates.

 

In addition, community-level initiatives organized by residents using messaging apps to share emergency alerts, resources and safety tips proved to be very effective, demonstrating the potential for digital tools to help strengthen local networks.

 

Researchers also recommend enhanced partnerships between county governments and communities to bolster resilience, address gaps in preparedness and empower citizens to take proactive steps against wildfires. Suggestions include training residents to be first responders, forming Neighborhood Watch groups, conducting Spanish-language educational programs, and distributing easy-to-understand guides on risk and evacuation procedures.

 

“For regions like ECV, where wildfires are a recurring threat, fostering collaboration between emergency services and the community is essential,” said lead author Anqi Jiao, UC Irvine Ph.D. candidate in environmental and occupational health. “Tailored communications and active engagement can ensure that even the most disadvantaged populations are equipped to face the challenges and protected from devastating consequences.”

 

The research team also included faculty members and graduate and undergraduate students from UC Irvine’s Joe C. Wen School of Population & Public Health and School of Medicine and Mississippi State University, as well as a lead organizer from Communities for a New California Education Fund. For a full list, click here.

 

This study was supported by the California Air Resources Board under grant CARB; #21RD003.

 

About the University of California, Irvine: Founded in 1965, UC Irvine is a member of the prestigious Association of American Universities and is ranked among the nation’s top 10 public universities by U.S. News & World Report. The campus has produced five Nobel laureates and is known for its academic achievement, premier research, innovation and anteater mascot. Led by Chancellor Howard Gillman, UC Irvine has more than 36,000 students and offers 224 degree programs. It’s located in one of the world’s safest and most economically vibrant communities and is Orange County’s second-largest employer, contributing $7 billion annually to the local economy and $8 billion statewide. For more on UC Irvine, visit www.uci.edu.

 

Media access: Radio programs/stations may, for a fee, use an on-campus studio with a Comrex IP audio codec to interview UC Irvine faculty and experts, subject to availability and university approval. For more UC Irvine news, visit news.uci.edu. Additional resources for journalists may be found at https://news.uci.edu/media-resources.

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Journal

International Journal of Disaster Risk Reduction

Article Title

Wildfire risk perception and communication in disadvantaged communities: Insights from Eastern Coachella Valley in Southern California

Article Publication Date

28-Jan-2025

GREEN CHEMISTRY

Chemical looping turns environmental waste into fuel

Study finds low-carbon system boosts chemical efficiency

Ohio State University

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COLUMBUS, Ohio – Turning environmental waste into useful chemical resources could solve many of the inevitable challenges of our growing amounts of discarded plastics, paper and food waste, according to new research. 

In a significant breakthrough, researchers from The Ohio State University have developed a technology to transform materials like plastics and agricultural waste into syngas, a substance most often used to create chemicals and fuels like formaldehyde and methanol. 

Using simulations to test how well the system could break down waste, scientists found that their approach, called chemical looping, could produce high-quality syngas in a more efficient manner than other similar chemical techniques. Altogether, this refined process saves energy and is safer for the environment, said Ishani Karki Kudva, lead author of the study and a doctoral student in chemical and biomolecular engineering at Ohio State. 

“We use syngas for important chemicals that are required in our day-to-day life,” said Kudva. “So improving its purity means that we can utilize it in a variety of new ways.”

Today, most commercial processes create syngas that is about 80 to 85% pure, but Kudva’s team achieved a purity of around 90% in a process that takes only a few minutes.

This study builds on decades of previous research at Ohio State, led by Liang-Shih Fan, a distinguished university professor in chemical and biomolecular engineering who advised the study. This previous research used chemical looping technology to turn fossil fuels, sewer gas and coal into hydrogen, syngas and other useful products.

In the new study, the system consists of two reactors: a moving bed reducer where waste is broken down using oxygen provided by metal oxide material, and a fluidized bed combustor that replenishes the lost oxygen so that the material can be regenerated. The study showed that with this waste-to-fuel system, the reactors could run up to 45% more efficiently and still produce about 10% cleaner syngas than other methods. 

The study was recently published in the journal Energy and Fuels.

According to a report by the Environmental Protection Agency, 35.7 million tons of plastics were generated in the U.S. in 2018, of which about 12.2% is municipal solid waste, such as plastic containers, bags, appliances, furniture, agricultural residue, paper and food.

Unfortunately, since plastics are resistant to decomposition, they can persist in nature for long periods and can be difficult to completely break down and recycle. Conventional waste management, such as landfilling and incineration, also poses risks to the environment.  

Now, the researchers are presenting an alternative solution to help curb pollution. For example, by measuring how much carbon dioxide their system would pump out compared to conventional processes, findings revealed it could reduce carbon emissions by up to 45%. 

Their project’s design is just one of many in the chemical sector being driven by the urgent need for more sustainable technologies, said Shekhar Shinde, co-author of the study and a doctoral student in chemical and biomolecular engineering at Ohio State.

In this study’s case, their work could help drastically reduce society’s dependence on fossil fuels. 

“There has been a drastic shift in terms of what was done before and what people are trying to do now in terms of decarbonizing research,” he said. 

While earlier technologies could only filter biomass waste and plastics separately, this team’s technology also has the potential to handle multiple types of materials at once by continuously blending the conditions needed to convert them, noted the study. 

Once the team’s simulations yield more data, they eventually hope to test the system’s market capabilities by conducting experiments over a longer time frame with other unique components. 

“Expanding the process to include the municipal solid waste that we get from recycling centers is our next priority,” Kudva said. “The work in the lab is still going on with respect to commercializing this technology and decarbonizing the industry.”

Other Ohio State co-authors include Rushikesh K. Joshi, Tanay A. Jawdekar, Sudeshna Gun, Sonu Kumar, Ashin A Sunny, Darien Kulchytsky and Zhuo Cheng. The study was supported by Buckeye Precious Plastic.

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Contact: Ishani Karki Kudva, Kudva.8@osu.edu, 

Liang-Shih Fan, Fan.1@osu.edu

Written by: Tatyana Woodall, Woodall.52@osu.edu 

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Journal

Energy & Fuels

DOI

10.1021/acs.energyfuels.4c02643 

Article Title

Low Carbon Formaldehyde Generation from Chemical Looping Gasification of Heterogeneous Solid WasteArticle link copied!

 

Optical fiber sensor provides simple and sensitive detection of arsenic in drinking water

New cost-effective tool paves the way for household water quality monitoring, helping combat arsenic contamination

Optica

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A new easy-to-use optical fiber sensor achieves sensitive and real-time detection of extremely low levels of arsenic in water.

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Credit: Sunil Khijwania, Indian Institute of Technology Guwahati

WASHINGTON — Researchers have developed a new optical sensor that provides a simple way to achieve real-time detection of extremely low levels of arsenic in water. The technology could enable household testing for arsenic, empowering individuals to monitor their own water quality.

Arsenic contamination is a serious environmental and public health challenge affecting millions of people around the world. This contamination occurs when natural geological processes release arsenic from rocks and soil into groundwater and can be exacerbated by mining, industrial waste disposal and use of arsenic-based pesticides.

“Consuming arsenic-contaminated water can lead to severe health conditions including arsenic poisoning and cancers of the skin, lung, kidney and bladder,” said lead researcher Sunil Khijwania from the Indian Institute of Technology Guwahati. “By creating a sensor that is sensitive, selective, reusable and cost-effective, we aim to address the need for a reliable and user-friendly tool for routine monitoring, helping to protect communities from the risks of arsenic exposure.”

In the Optica Publishing Group journal Applied Optics, the researchers describe their new sensor, which uses an optical fiber and an optical phenomenon known as localized surface plasmon resonance. They used it to detect arsenic levels as low as 0.09 parts per billion (ppb), 111 times lower than the maximum permissible limit of 10 ppb established by the World Health Organization. The sensor also exhibited reliable performance when tested on real drinking water samples from diverse locations and conditions.

“The highly sensitive sensor provides analysis within just 0.5 seconds and demonstrates a high degree of reusability, repeatability, stability and reliability, making it a powerful tool for monitoring and ensuring safer water quality,” said Khijwania. “In the future, this technology could make it much easier for people to check whether their drinking water is safe, potentially saving lives by preventing exposure to harmful arsenic levels.”

A user-friendly yet accurate sensor

Although conventional spectroscopy methods for detecting arsenic are highly accurate and sensitive, they tend to require complex, bulky, expensive equipment that is time-consuming and complicated to use. To fill this critical gap, the researchers developed an optical fiber sensor that not only has a low detection limit but is also cost-effective and user-friendly enough for routine arsenic monitoring in drinking water.

To make the new sensor, the researchers coated the inside core of a fiber with gold nanoparticles and a thin layer of a unique nanocomposite composed of aluminum oxide and graphene oxide, which selectively binds to arsenic ions. A portion of the light traveling through the core also extends into the surrounding fiber cladding due to the evanescent wave created by total internal reflection. By removing the cladding in a small section of the fiber, the evanescent wave is exposed to the environment.

As light travels through the optical fiber, the evanescent wave interacts with gold nanoparticles, triggering localized surface plasmon resonance — a phenomenon where electrons on the nanoparticle surface collectively oscillate in response to specific light wavelengths. If arsenic is present, it will bind to the nanocomposite, causing a measurable shift in the surface plasmon resonance wavelength and enabling accurate detection of trace arsenic in water.

Thorough performance assessment

The researchers tested the sensor using varying concentrations of arsenic ion solutions, finding that it produced consistent and reliable detection of arsenic across the tested concentration range. After additional optimization, they tested other parameters, showing that the sensor produced consistent results during both low-to-high and high-to-low changes in arsenic ion concentration and achieved a fast response time of just 0.5 seconds.

The sensor exhibited a maximum resolution of ± 0.058 ppb of arsenic and showed negligible variations in results for samples with identical arsenic concentrations analyzed on four separate days over an 18-day period. The researchers also compared sensor measurements to those obtained with inductively coupled plasma mass spectrometry (ICP-MS), which is commonly used for arsenic measurements. The sensor showed a relative percentage difference of less than 5%, indicating strong agreement between the two methods.

To evaluate the real-world applicability of the sensor, the researchers tested it on drinking water samples collected from different locations in the city of Guwahati in India. The sensor maintained reliable performance under these varied conditions.

“These investigations established that the proposed optical fiber sensor offers a highly sensitive, selective, fast, cost-effective, straightforward and easy solution for arsenic detection in real field conditions,” said Khijwania. “In the long term, this new approach could potentially be modified to create a new wave of affordable and accessible environmental monitoring tools.”

The researchers note that although the sensor is ready for real-world use in detecting arsenic, a less expensive and easier-to-use optical source and detector would need to be developed to enable widespread application.

Paper: F. Banoo, S. K. Khijwania, “Localized Surface Plasmon Resonance based Novel Optical Fiber Arsenic Ion Sensor Employing Al2O3/GO Nanocomposite,” Applied Optics, 64, 1019-1027 (2025).
DOI: 10.1364/AO.544358

About Optica Publishing Group

Optica Publishing Group is a division of the society, Optica, Advancing Optics and Photonics Worldwide. It publishes the largest collection of peer-reviewed and most-cited content in optics and photonics, including 18 prestigious journals, the society’s flagship member magazine, and papers and videos from more than 835 conferences. With over 400,000 journal articles, conference papers and videos to search, discover and access, our publications portfolio represents the full range of research in the field from around the globe.

About Applied Optics

Applied Optics publishes in-depth peer-reviewed content about applications-centered research in optics. These articles cover research in optical technology, photonics, lasers, information processing, sensing, and environmental optics. Optica Publishing Group publishes Applied Optics three times per month and oversees Editor-in-Chief Gisele Bennett, MEPSS LLC. For more information, visit Applied Optics.

Media Contact

mediarelations@optica.org

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Journal

Applied Optics

DOI

10.1364/AO.544358 

Article Title

Localized Surface Plasmon Resonance based Novel Optical Fiber Arsenic Ion Sensor Employing Al2O3/GO Nanocomposite

 

Oceanic plate between Arabian and Eurasian continental plates is breaking away

Research team investigates influence of Zagros Mountains on bending Earth’s surface

University of Göttingen

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Map of the northern Middle East showing the Arabian and Eurasian plates and their collision zone, as well as the study area, the Kurdistan region of Iraq.

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Credit: available under Creative Commons 4.0 license from Solid Earth (https://doi.org/10.5194/se-15-1365-2024) and edited by Renas Koshnaw

An international research team led by the University of Göttingen has investigated the influence of the forces exerted by the Zagros Mountains in the Kurdistan region of Iraq on how much the surface of the Earth has bent over the last 20 million years. Their research revealed that in the present day, deep below the Earth’s surface, the Neotethys oceanic plate – the ocean floor that used to be between the Arabian and Eurasian continents – is breaking off horizontally, with a tear progressively lengthening from southeast Turkey to northwest Iran. Their findings show how the evolution of the Earth's surface is controlled by processes deep within the planet's interior. The research was published in the journal Solid Earth.

 

When two continents converge over millions of years, the oceanic floor between them slides to great depths beneath the continents. Eventually, the continents collide, and masses of rock from their edges are lifted up into towering mountain ranges. Over millions of years, the immense weight of these mountains causes the Earth's surface around them to bend downward. Over time, sediments eroded from the mountains accumulate in this depression, forming plains such as Mesopotamia in the Middle East. The researchers modelled the downward bend of the Earth's surfaces based on the Zagros Mountain's load where the Arabian continent is colliding with Eurasia. They combined the resulting size of the depression with the computed topography based on the Earth's mantle to reproduce the unusually deep depression in the southeastern segment of the study area. The researchers found that the weight of the mountains alone cannot account for the 3-4 km deep depression that has formed and been filled with sediment over the past 15 million years.

 

"Given the moderate topography in the north-western Zagros area, it was surprising to find out that so much sediment has accumulated in the part of the area we studied. This means the depression of the land is greater than could be caused by the load of the Zagros Mountains,” said Dr Renas Koshnaw, lead author and Postdoctoral Researcher at Göttingen University's Department of Structural Geology and Geothermics. Researchers propose that this is caused by the additional load of the sinking oceanic plate that is still attached to the Arabian plate. Koshnaw adds: “This plate is pulling the region downward from below, making space for more sediment accumulation. Towards Turkey, the sediment-filled depression becomes much shallower, suggesting that the slab has broken off in this area, relieving the downward pull force."

 

The geodynamic model developed in this research will benefit other fields as well. “This research contributes to understanding how the Earth’s rigid outer shell functions,” explains Koshnaw. Such research can lead to practical applications in the future by providing information for exploring natural resources such as sedimentary ore deposits and geothermal energy, and better characterization of the earthquake risks.

The Zagros Mountains and sediments that have accumulated over millions of years along the depression at the base of the mountains.

Credit

Renas Koshnaw

This research was made possible thanks to funding from the Alexander von Humboldt Foundation.

Original research: Renas Koshnaw et al., “The Miocene subsidence pattern of the NW Zagros foreland basin reflects the southeastward propagating tear of the Neotethys slab” Solid Earth 2024. DoI:  10.5194/se-15-1365-2024

 

Contact:

Department of Structural Geology and Geothermics

37077 Göttingen, Germany

Email: renas.koshnaw@geo.uni-goettingen.de  

www.uni-goettingen.de/en/609644.html

https://sites.google.com/view/dr-renas-i-koshnaw/home

 

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Journal

Solid Earth

DOI

10.5194/se-15-1365-2024 

Method of Research

Observational study

Subject of Research

Not applicable

Article Title

The Miocene subsidence pattern of the NW Zagros foreland basin reflects the southeastward propagating tear of the Neotethys slab