Dragonfly study challenges traditional ideas about biodiversity conservation

New research shows that climate conditions faced by dragonfly nymphs underwater have a greater impact on adult trait diversity than does their later environment on land

McGill University

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A study has found that the impact of climate change on an animal’s traits can begin much earlier than scientists previously thought – a discovery that could reshape how researchers and policymakers approach biodiversity conservation.

Focusing on dragonflies, the researchers developed a new statistical framework to quantify the extent to which traits formed in early life influence adult trait diversity, and thus biodiversity more broadly. They found that factors like water temperature and seasonal changes during the aquatic juvenile stage shaped adult trait diversity more strongly than the land-based adult environments themselves. Biodiversity refers to the variety of living things in an area, including how many species there are and how different they are from each other in their physical appearance (referred to as traits) such as body size or shape.

This suggests that climate adaptation strategies should focus not only on adult populations, but also on what species experience earlier in life, the researchers say.

“This is really useful going forward as the results will provide a new general rule to guide how biodiversity scientists forecast climate responses – depending on juvenile or adult characteristics,” said lead author Professor Lars L. Iversen, a biology researcher at McGill University. “The results can also help members of the public to understand how environmental shifts in life stages is important in driving climate responses.”

While most biodiversity models focus on adult traits, which are easier to observe because adults are larger, more mobile and more visible, the researchers found that conditions during the juvenile phase can leave lasting biological imprints. In dragonflies, these early conditions often occur underwater and out of sight.

 

Image by Erland Refling Nielsen.

Toward better biodiversity models

The team, which included scientists from McGill University, the University of Aberdeen and the Leibniz Institute in Germany, analyzed data from 87 dragonfly species across Europe. They compared climate, landscape and habitat data with traits observed in both aquatic nymphs and airborne adults, revealing strong carryover effects from early life stages. The study was published in Global Ecology and Biogeography.

“This is a really important study, as many predictions for how climate might affect diversity are based on observations of adult stages, because these tend to be more active, visible and larger,” said co-author Lesley Lancaster from the University of Aberdeen. “However, we find that the observed climate impacts are actually largely indirect consequences of processes affecting juveniles.”

“Scientists and policymakers will be able to use this knowledge to determine whether they should target juveniles or adults for active climate adaptation and mitigation practices,” Iversen said.

 

Image by Erland Refling Nielsen.

About the study

Complex Life Cycles Shape the Functional Biogeography of European Dragonflies by Lars L. Iversen, Jaime Garcia-Marquez, Afroditi Grigoropoulou, Michael O'Connor, Sami Domisch, Lesley T. Lancaster was published in Global Ecology and Biogeography.

This study was funded by the Natural Sciences and Engineering Research Council of Canada, the German Federal Ministry of Education and Research, and the Leibniz Association.

 

Why some coral reefs resist bleaching

McGill, STRI-led study shows that environmental history and microbiome stability shape how corals withstand extreme heat, offering insights for reef conservation in a warming world

McGill University

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A new study led by researchers at McGill University and the Smithsonian Tropical Research Institute (STRI) in Panama reveals why some corals resist bleaching while others don’t: the answer lies in a complex partnership between corals and their microbial allies, shaped by the history of the waters they inhabit.

As climate change warms the world’s oceans, coral reefs – ecosystems that support one-quarter of all marine biodiversity – are increasingly at risk. Bleaching occurs when stressed corals expel the algae living within them, causing the corals to lose their characteristic colours and putting them at greater risk of death. Coral reefs’ ecosystems sustain various marine species, so the loss of reefs have broader impacts.

Corals living in waters with frequent temperature swings are better at surviving extreme heat than are corals in waters with more stable temperatures, the researchers found. This suggests that their resilience depends not only on their genes, but on their environment. The stability of the algae and bacteria living inside the coral was also found to play a role. These microbial allies include symbiotic algae, which provide energy, and bacteria, which help regulate stress and disease.

“Understanding what makes some corals more resilient to increasing temperatures helps us figure out how reefs might survive climate change and where to focus conservation efforts,” said Victoria Glynn, lead author of the study, who conducted the work as a PhD student in McGill’s Department of Biology and STRI.

The team studied coral reefs in two regions of Panama’s Tropical Eastern Pacific, each with very different ocean conditions. In the Gulf of Panama, strong seasonal upwelling – a process that causes cold water to rise toward the surface – brings rapid fluctuations in temperature and water chemistry. In the Gulf of Chiriquí, conditions are much more stable.

• RELATED: Drawing out the secrets of coral reef resilience to high ocean temperatures

To test how corals from each region respond to extreme heat, the researchers collected samples and used a specialized lab system called the Coral Bleaching Automated Stress System (CBASS), which mimics marine heatwaves, allowing observation of how corals respond to sudden stress.

They also analyzed the coral’s genetic background and their microbiomes – algal and bacterial communities – of each coral and tracked physiological changes like antioxidant capacity and protein content.

More heat tolerance in corals from unstable waters

Despite sharing much of the same DNA, corals from the Gulf of Panama were more heat-tolerant than those from the Gulf of Chiriquí.

“Minor genetic differences seem to contribute to thermal tolerance, but the environmental context makes a big difference,” said McGill biology professor Rowan Barrett, who supervised Glynn’s doctoral research project.

In lab tests, Gulf of Panama corals maintained their protein levels and resisted oxidative damage more effectively than did their counterparts from the more stable Chiriquí. However, the team also found that bacterial microbiomes from both locations corals became more unstable and variable under heat stress, a sign of bleaching vulnerability.

One of the study’s most surprising findings challenges conventional wisdom about coral-algae relationships. While many stressed corals in other regions switch to Durusdinium algae – associated with higher heat tolerance some corals often retained Cladocopium at high temperatures, which provides more energy but less heat protection.

“This suggests there’s a trade-off between energy supply and heat resistance,” said Barrett.

Implications for reef survival

The findings support the idea that corals regularly exposed to variable conditions may be “pre-adapted” to future climate extremes. That could help explain why the Gulf of Panama’s reefs were able to recover from the catastrophic 1982 El Niño event.

“Panama’s reefs give us a natural laboratory to understand resilience,” said STRI’s Sean Connolly, a research biologist who co-advised Glynn’s doctoral work.”. “By studying how coral communities adapt to their environment, we can better predict which reefs are most at risk – and which might bounce back.”

About the study:

The role of holobiont composition and environmental history in thermotolerance of Tropical Eastern Pacific corals was published in Current Biology and co-led by Victoria Glynn and Rowan Barrett from McGill University, and Sean Connolly, Matthieu Leray, David Kline, and Laura Marangoni from the Smithsonian Tropical Research Institute.

Funding was provided by the Mark and Rachel Rohr Foundation. Additional support was provided to lead author Victoria Glynn through a Fulbright U.S. Scholar Grant and a Vanier Canada Graduate Scholarship. Further support came from the Smithsonian Tropical Research Institute, NSERC, and others.

 

New tool could help Florida homeowners weather flood risks, lower insurance costs

University of Florida

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With flood risks increasing from extreme weather events like hurricanes and even routine plumbing issues, a team from the University of Florida’s College of Design, Construction and Planning is helping Florida homeowners make smarter choices about building materials and interior finishes that better protect their homes and potentially save on their insurance premiums.

Lisa Platt, Ph.D., an assistant professor in the department of interior design and a researcher within the Florida Institute for Built Environment Resilience, or FIBER, and Arezoo Zeinali, a graduate research assistant in Platt’s Design Dynamics lab have developed a groundbreaking tool that helps homeowners, builders and policymakers make better, science-informed choices about what materials are used to build and furnish a house.

The system, called SAMPL™ — short for Sustainable Adaptive Material Performance Level — goes beyond checklists and code books. It uses computational modeling to evaluate how building materials respond to real-world risks, especially water-related damage.

“The platform helps people choose building materials that are less likely to be damaged if a disaster strikes,” said Platt, who originally developed it as a teaching tool to guide students in making smarter material choices.

To tailor the SAMPL™ platform for real-world application, Platt, Zeinali and research colleagues at FIBER refined the system specifically to assess flood-related risks. The work was part of a state-funded initiative commissioned by the Florida Office of Insurance Regulation, which asked UF researchers at FIBER to explore how enhancing the resilience of single-family homes could help lower insurance premiums.

By adjusting SAMPL’s risk formulas to emphasize moisture resistance, material imperviousness and failure likelihood in flood scenarios, the team produced a version of the platform capable of supporting data-driven decisions about which materials are most likely to withstand or recover from the risk water intrusion. The findings contributed to the development of the Resilience Inference Performance Level (RIPL) report, which aims to help insurance regulators, builders and homeowners identify cost-saving, risk-reducing strategies for residential construction.

A smart system for resilient design

SAMPL analyzes materials based on three key characteristics:

• Strength: How durable the material is under pressure from specific environmental conditions and regional risk factors.
• Symbiosis: How the material interacts with environmental conditions, particularly its resistance to moisture.
• Sustainability: How environmentally responsible the material is, factoring in things like embodied carbon and chemical transparency.

Platt, Zeinali and team, including Jeff Carney, an associate professor in the UF School of Architecture and the director of FIBER, and UF interior design and architecture students, have compiled a relational database of material data — everything from the hardness of flooring types to moisture-resistance ratings and environmental product declarations. The system assigns each material a resilience score based on its overall potential for failure based on a tunable risk level, allowing users to compare options and choose those most suited to their climate risks.

And it’s not just structural materials. SAMPL also evaluates common finishings and furnishings such as carpet types, wood varieties, porcelain tiles and more. While the system does not recommend brands, it gives users a sense of how different material types stack up in terms of performance and safety.

“We’re looking at materials as a proactive strategy,” Platt said. “Then we’re layering in smart-home technology, including systems for preventing water intrusion, automatic shutoff valves and foundation sensors, as a reactive safeguard. Together, they form a home design that connects risk-reducing and resilience-boosting strategies with potential insurance savings.”

Informing policy, protecting homes

The project aligns with proposed Florida legislation that would offer tax incentives for building with resilient materials. The ultimate goal, Platt said, is to provide homeowners and insurance regulators with a shared rubric: if a home meets certain resilience benchmarks, it could qualify for lower premiums.

The SAMPL platform is designed to be adaptable beyond Florida. While it’s currently calibrated to assess flood and storm risks common to coastal regions, it could be tuned for threats like extreme heat, wildfire, or other types of regional risks.

Platt, who has worked as both a designer and academic, said her personal experience as a Florida homeowner drives her research.

“I think about protecting my family just like anyone else,” she said. “Our goal as scientists and educators is to help others make better decisions that protect their homes, their health and their financial stability.

“SAMPL isn’t perfect, and it can’t predict everything,” Platt continued, “but it’s allowing us to move in the right direction for leveraging data to inform reliable design decisions.”

Toward an Open Access Future

Looking ahead, Platt envisions SAMPL becoming an open-access resource for anyone involved in homebuilding or renovation — especially in climate-vulnerable areas.

“This isn’t about telling people how to design their homes,” she said. “It’s about giving them the best information we have, in a usable form, so they can make informed choices that protect what matters most.”

 

Drones can detect fires and monitor greenhouse gas emissions

University of São Paulo researchers are developing an aircraft equipped with sensors that can detect and measure the concentrations of carbon dioxide and methane in the environment; the project was presented at FAPESP Week France in Toulouse.

Fundação de Amparo à Pesquisa do Estado de São Paulo

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To validate the use of drones for collecting GHG data, the researchers conducted tests around the USP campus in São Carlos 

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Credit: Antonio Daud

Forest fire prevention and control agencies in São Carlos, in the interior of the state of São Paulo, Brazil, will soon have help from the sky to detect fires more quickly and combat them before they grow out of control and cannot be extinguished.

Researchers at the University of São Paulo’s São Carlos Engineering School (EESC-USP) are developing drones equipped with gas sensors and artificial intelligence systems to detect forest fires.

The project was presented on Wednesday, June 11th, during the aeronautics session of FAPESP Week Toulouse, which took place from Tuesday, June 10th, to Thursday, June 12th, in the capital of the Occitanie region in southern France.

“We’re already working with the Civil Defense, the city government, and the São Carlos Department of the Environment, and we’ve submitted a proposal to evaluate using the drones we’re developing to identify fire hotspots in the municipality,” Glauco Augusto de Paula Caurin, a professor at the EESC-USP and project coordinator, told Agência FAPESP.

The drones are equipped with small, low-cost sensors developed by the researchers that can selectively detect and continuously measure atmospheric concentrations of carbon dioxide and methane in the air flowing inside the aircraft, as well as other parameters such as temperature and humidity. “We made several adjustments to integrate specific gas sensors that work together like an electronic nose,” Caurin compares.

The sensors collect gas concentration data, which artificial intelligence systems then analyze to identify their sources of emission. This allows the systems to detect the presence of carbon dioxide and trace gases, such as methane, which are released during a fire in an environment while the drones are flying overhead.

“Drones allow forest fires to be detected much more quickly than satellites can, for example. This enables the authorities to respond faster and control them more quickly,” Caurin explained.

GHG emission monitoring

In a project supported by FAPESP through the Research Center for Greenhouse Gas Innovation (RCGI) and funded by the Foundation in partnership with Shell, researchers evaluated the use of drones for GHG monitoring in recent years.

The test results indicated that drones are efficient and cheaper than the current methods, such as satellites, research aircraft, and observation towers, said the researcher. “Drones can be an alternative to these methods,” Caurin said.

The researcher compared the process of collecting data from a single flight with a research aircraft to making several flyovers with drones. Drones can also better define a location of interest for data collection than satellites can, which pass over and track a given area every two days, for example.

The researcher pointed out another advantage of using drones compared to these methods: the ability to vary the height at which data are collected.

“By collecting greenhouse gas data with drones, instead of an average of carbon dioxide or methane on a surface, it’s possible to obtain the volume of distribution of these gases in a given region,” he said.

“Today, even with the best satellites, we’re unable to obtain this volumetric information. With drones, greenhouse gas data collection is no longer a surface or map of the region, but rather volumetric information,” he explained.

According to the researcher, despite their excellent performance, the commercial drones currently available can only fly for between 15 minutes and half an hour. Therefore, they are not yet viable for flying over large areas, such as forests.

The group intends to improve the efficiency of the equipment through aerodynamics research projects, making it capable of flying longer and covering larger areas.

To validate the use of drones for collecting GHG data, the researchers conducted tests around the USP campus in São Carlos, which is located in a transition zone between the Atlantic Rainforest and the Cerrado (Brazilian savanna-like biome).

“In the future, with more suitable equipment, we intend to carry out missions in the Amazon,” says Caurin.

For more information about FAPESP Week France, visit: fapesp.br/week/2025/france.

 

Western standards behind the gender equality paradox

Uppsala University

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Mathias Berggren, PhD, Department of Psychology, Uppsala University and University of British Columbia

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Credit: Mathias Berggren

Previous research has asserted that women and men in gender-equal countries differ more in their preferences than women and men in less equal countries, for example by making more traditional educational choices. This relationship is known as the gender-equality paradox. However, new research from Uppsala University now shows that it is not possible to draw these conclusions from the data studied. The paper, published in the journal PNAS, shows that the question is based on Western perspectives and conditions and cannot be applied to other countries.

“I became interested in this paradox when I noticed that all the more gender-equal countries were Western,” says Mathias Berggren. “That made me want to investigate whether the methodology really held up and how they had designed their studies. There are major data problems, for example with personality measures developed in Western countries.”

The so-called gender-equality paradox has been a recurrent but controversial thesis in social research over the past decade. It assumes that when both women and men have more freedom to do what they want, i.e. when gender equality is high, they are more prone to adopt traditional gender roles. This could explain why, for example, female students in Sweden are less likely to apply for engineering, technology or maths programmes than women in less gender-equal countries such as Algeria.

Men and women are innately different, and more gender equality only makes it easier for them to show their true colours, the thesis goes. The paradox has received widespread attention both in research and in social media, and has led some to argue, for example, that gender equality efforts may be dysfunctional or meaningless. In recent years, the thesis has been questioned, and now researchers at Uppsala University have decided to thoroughly scrutinise the methodology to discover potential flaws.

The research team hypothesised that the link between more gender equality and larger gender differences is actually due to Western measures not working as well in other cultures. In other words, when – usually Western – researchers have found large gender differences for some characteristic in, say, the United States, it is often possible to find the same phenomenon in countries with similar cultures, for example in Western Europe.

“However, it does not work as well in countries that differ more from the West. For example, personality can manifest itself differently in different cultures and in some cases reliability drops significantly outside the Western world. This makes it very difficult to find the same large gender differences – because the search is simply carried out in the wrong way. For example, statements such as ‘I tend to vote for liberal politicians’ may systematically differ between people with different personalities in the West, but do not necessarily do so in countries with limited voting rights,” Berggren explains.

In the article published in PNAS, the researchers re-analysed data from multiple studies that demonstrated the gender-equality paradox.

When they took account of cultural clusters of countries as well as reliability and other statistical indications of measurement quality, the correlations between increased gender equality and larger gender differences disappeared. The researchers also tested a number of other variables besides gender equality, such as indications of economic development, but there were no general associations with gender differences in personality and the like after statistically controlling for cultural clusters and measurement quality.

The researchers chose to look at a wide range of other variables, such as cognitive abilities, school performance and aggression. Again, after controlling for reliability and cultural clusters, they did not observe any major differences associated with higher gender equality. In all, millions of participants from over 130 different countries were analysed.

In their study, the researchers go on to show that fictional explanations also exhibit the same association with gender differences as the evolutionary thesis, as long as the variables are similarly linked to the Western world.

Overall, the article suggests that there may be no connection at all between greater gender equality and larger gender differences.

“There is currently no strong evidence that increased gender equality leads to women and men more clearly revealing any underlying distinctions. We show that this type of study provides very poor evidence for such conclusions. If researchers want to investigate the effects of gender equality reforms, they need methods that better show cause and effect, for example using extensive data over time and/or natural experiments,” Berggren concludes.

 

Fact box: The gender-equality paradox

Since 2001, scientific studies have been presented showing larger gender differences (initially in personality) in more gender-equal countries. The researchers have compared countries with high and low levels of welfare and high and low levels of gender equality (according to UN indicators, for example). The finding that has received most attention is that in countries with a low gender equality index, more women study subjects leading to traditionally male occupations (STEM programmes: Science, Technology, Engineering, Mathematics), than in more gender-equal countries such as Sweden. This finding is known as the gender-equality paradox and has been used in many contexts. Among other things, it has been adduced as evidence that active gender equality policies do not pay off and that it is not worth countries working to promote equal opportunities between women and men.

 

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Journal

Proceedings of the National Academy of Sciences

DOI

10.1073/pnas.2422247122 

Article Title

Simpson’s gender-equality paradox

Article Publication Date

5-Jun-2025

 

Cannabis legalization and opioid use disorder in Veterans Health Administration patients

JAMA Health Forum

About The Study:

 The results of this cohort study suggest that medical cannabis laws and recreational cannabis laws enactment was associated with greater opioid use disorder (OUD) prevalence in Veterans Health Administration patients over time, with the greatest increases among middle-aged and older patients and those with chronic pain. The findings did not support state cannabis legalization as a means of reducing the burden of OUD during the ongoing opioid epidemic.

Corresponding Author: To contact the corresponding author, Deborah S. Hasin, PhD, email dsh2@cumc.columbia.edu.

To access the embargoed study: Visit our For The Media website at this link https://media.jamanetwork.com/

(doi:10.1001/jamahealthforum.2025.1369)

Editor’s Note: Please see the article for additional information, including other authors, author contributions and affiliations, conflict of interest and financial disclosures, and funding and support.

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Embed this link to provide your readers free access to the full-text article 

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About JAMA Health Forum: JAMA Health Forum is an international, peer-reviewed, online, open access journal that addresses health policy and strategies affecting medicine, health and health care. The journal publishes original research, evidence-based reports and opinion about national and global health policy; innovative approaches to health care delivery; and health care economics, access, quality, safety, equity and reform. Its distribution will be solely digital and all content will be freely available for anyone to read.

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JAMA Health Forum

 

New cooling tech could curb data centers' rising energy demands

University of California - San Diego

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Illustration of a fiber membrane removing heat from an electronic chip through evaporation.

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Credit: Tianshi Feng

Engineers at the University of California San Diego have developed a new cooling technology that could significantly improve the energy efficiency of data centers and high-powered electronics. The technology features a specially engineered fiber membrane that passively removes heat through evaporation. It offers a promising alternative to traditional cooling systems like fans, heat sinks and liquid pumps. It could also reduce the water use associated with many current cooling systems.

The advance is detailed in a paper published on June 13 in the journal Joule.

As artificial intelligence (AI) and cloud computing continue to expand, the demand for data processing—and the heat it generates—is skyrocketing. Currently, cooling accounts for up to 40% of a data center’s total energy use. If trends continue, global energy use for cooling could more than double by 2030.

The new evaporative cooling technology could help curb that trend. It uses a low-cost fiber membrane with a network of tiny, interconnected pores that draw cooling liquid across its surface using capillary action. As the liquid evaporates, it efficiently removes heat from the electronics underneath—no extra energy required. The membrane sits on top of microchannels above the electronics, pulling in liquid that flows through the channels and efficiently dissipating heat.

“Compared to traditional air or liquid cooling, evaporation can dissipate higher heat flux while using less energy,” said Renkun Chen, professor in the Department of Mechanical and Aerospace Engineering at the UC San Diego Jacobs School of Engineering, who co-led the project with professors Shengqiang Cai and Abhishek Saha, both from the same department. Mechanical and aerospace engineering Ph.D. student Tianshi Feng and postdoctoral researcher Yu Pei, both members of Chen’s research group, are co-first authors on the study.

Many applications currently rely on evaporation for cooling. Heat pipes in laptops and evaporators in air conditioners are some examples, explained Chen. But applying it effectively to high-power electronics has been a challenge. Previous attempts using porous membranes—which have high surface areas that are ideal for evaporation—have been unsuccessful because their pores were either too small they would clog or too large they would trigger unwanted boiling. “Here, we use porous fiber membranes with interconnected pores with the right size,” said Chen. This design achieves efficient evaporation without those downsides.

When tested across variable heat fluxes, the membrane achieved record-breaking performance. It managed heat fluxes exceeding 800 watts of heat per square centimeter—one of the highest levels ever recorded for this kind of cooling system. It also proved stable over multiple hours of operation.

“This success showcases the potential of reimagining materials for entirely new applications,” said Chen. “These fiber membranes were originally designed for filtration, and no one had previously explored their use in evaporation. We recognized that their unique structural characteristics—interconnected pores and just the right pore size—could make them ideal for efficient evaporative cooling. What surprised us was that, with the right mechanical reinforcement, they not only withstood the high heat flux–they performed extremely well under it.”

While the current results are promising, Chen says the technology is still operating well below its theoretical limit. The team is now working to refine the membrane and optimize performance. Next steps include integrating it into prototypes of cold plates, which are flat components that attach to chips like CPUs and GPUs to dissipate heat. The team is also launching a startup company to commercialize the technology.

Full study: “High-Flux and Stable Thin Film Evaporation from Fiber Membranes with Interconnected Pores.”

This research was supported by the National Science Foundation (grants CMMI-1762560 and DMR-2005181). The work was performed in part at the San Diego Nanotechnology Infrastructure (SDNI) at UC San Diego, a member of the National Nanotechnology Coordinated Infrastructure, which is supported by the National Science Foundation (grant ECCS-2025752).

Disclosures: A patent related to this work was filed by the Regents of the University of California (PCT Application No. PCT/US24/46923.). The authors declare that they have no other competing interests.

Illustration of the fiber membrane pulling liquid from microchannels into its pores through capillary action and cooling a heat source as the liquid evaporates.

Credit

Tianshi Feng

Evaporation test setup using the fiber membrane.

Credit

Tianshi Feng and Yu Pei

Journal

Joule

Article Title

High-Flux and Stable Thin Film Evaporation from Fiber Membranes with Interconnected Pores

Article Publication Date

13-Jun-2025

COI Statement

A patent related to this work was filed by the Regents of the University of California (PCT Application No. PCT/US24/46923.). The authors declare that they have no other competing interests.