Sunday, June 02, 2024

 

Some species may better tolerate climate change than expected



UNIVERSITY OF LAUSANNE
Some species may better tolerate climate change than expected 

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A NEW MODEL, DEVELOPED BY IFREMER AND LAUSANNE UNIVERSITY RESEARCHERS AND published in the journal Nature Ecology and Evolution, REASSESSES THE PROPORTION OF TERRESTRIAL AND MARINE SPECIES THREATENED WITH EXTINCTION BY CLIMATE CHANGE.

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CREDIT: OLIVIER DUGORNAY © CC-BY IFREMER




A new model, developed by Ifremer and Lausanne University researchers and published in the journal Nature Ecology and Evolution, reassesses the proportion of terrestrial and marine species threatened with extinction by climate change. While the forecasts of traditional models estimate that the diversity of terrestrial species in tropical areas could decrease by 54% between now and 2041-2060, this model is more moderate, predicting a decrease of 39%. Nevertheless, this proportion remains alarming and confirms the importance of taking urgent measures to mitigate climate change and its impact on biodiversity. 

Today, temperatures on Earth vary from around -70°C in Antarctica to +48°C at the equator. These "climatic limits" that currently exist on our planet have always evolved. For example, 130,000 years ago, during the last interglacial period, the climate was warmer and similar to what we could expect by the end of the century. The species that evolved during this period could therefore be "pre-adapted" to the changes to come. However, until now, statistical models predicting the response of species to climate change did not take this potential pre-adaptation into account, which could lead to inaccurate predictions.

Take the example of a tropical marine or terrestrial species: traditional statistical models predict that it will disappear in places where the temperature exceeds the current warm limit of 48°C. But this view could be too restrictive, as our knowledge is limited by the study of current climatic conditions. Could this species live with an air temperature of 50°C? Or in warmer or saltier water? Under the effect of climate change, such conditions could reappear and lead to an expansion of the climatic niche of certain species", explains Mathieu Chevalier, marine ecology researcher at Ifremer.

When a species is 'marked' by climatic conditions, it retains a pre-adaptation to these conditions that can last for thousands or even millions of years. If its habitat evolves towards a climate that the species has already experienced in the past, this pre-adaptation will provide it with a tolerance to these new climatic conditions", adds Antoine Guisan, professor of spatial ecology at the University of Lausanne.

The scientists from Ifremer and the University of Lausanne have applied their model to almost 25,000 terrestrial and marine species - including animals and plants - from around the world for which the International Union for Conservation of Nature (IUCN) provides geographical distribution maps. By cross-referencing this data in their model with scenarios of future climate change (IPCC/CMIP5), they found that 49% of these species currently live in climate niches that are contiguous ("stuck") to the limits of current climate conditions, and that 86% of them could have a niche potentially extending beyond current climate limits. This figure rises to 92% for marine species.

The most striking result concerns tropical areas, for terrestrial and marine species. It is widely accepted that climate change will lead to a massive loss of biodiversity in these areas, up to 54% of tropical terrestrial species by 2041-2060 according to traditional models. Our model puts this prognosis into perspective and predicts a reduction of 'only' 39% in species diversity," says Mathieu Chevalier, a marine ecology researcher at Ifremer.

Does that mean this is good news? Clearly not. Scientists are advising us to remain prudent: this estimate of threatened biodiversity remains alarming, and climate is not the only variable to take into account for a realistic prediction of species extinction risk. We also need to consider other anthropogenic pressures, such as habitat loss, pollution, overexploitation or biological invasions. It is clear, for example, that even if certain species are pre-adapted to future conditions, they will not be able to survive if their habitat disappears. Ideally, all these aspects should be taken into account, but here the scientists have concentrated on the climatic aspects, for which knowledge on past and future conditions is available.

Our study shows that it is important to constantly refine our models, and develop new hypotheses about the possible response of certain species. If it is likely that tropical species could better tolerate climate change than previously thought, the old estimates remain valid for species in cold, alpine and polar regions, and to a large extent for species in temperate zones, because the climate that currently prevails in these areas will no longer exist by 2041. These species are already living at the limit of their climatic niche and will not be able to tolerate significantly warmer temperatures. That is a sure thing! warns Olivier Broennimann, a researcher in spatial ecology at the University of Lausanne.

Read the article:

Chevalier M. (Ifremer), Broennimann O. and Guisan A. (Université de Lausanne), « Climate change may reveal currently unavailable parts of species ecological niches », May 2024, Nature Ecology & Evolutionhttps://doi.org/10.1038/s41559-024-02426-4 https://www.nature.com/articles/s41559-024-02426-4

 

 

Controlling ion transport for a blue energy future


Researchers from Osaka University show the control of ion passage through a nanopore membrane by applying a voltage to a gate electrode, paving the way for sustainable blue energy harvesting


OSAKA UNIVERSITY

Fig. 1 

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SCHEMATIC ILLUSTRATION DEPICTING GATE VOLTAGE CONTROL OF ION SELECTIVITY IN A NANOPORE.

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CREDIT: MAKUSU TSUTSUI




Osaka, Japan – Blue energy has the potential to provide a sustainable alternative to fossil fuels. In simple terms, it involves harnessing the energy produced when the ions in a salt solution move from high to low concentrations. A team including researchers from Osaka University has probed the effect of voltage on the passage of ions through a nanopore membrane to demonstrate greater control of the process.

In a study recently published in ACS Nano the researchers looked at tailoring the flow of ions through the array of nanopores that make up their membrane, and how this control could make applying the technology on a large scale a reality.

If the membranes are made from a charged material, nanopores can cause a current to flow through them by attracting solution ions with the opposite charge. The ions with the same charge can then move through the pore generating the current. This means that the pore material is very important and choosing it has been the means of controlling the flow and current to date.

However, producing the exact same pore structures in a range of different materials to understand their comparative performances is challenging. The researchers therefore decided to investigate another way of tailoring the flow of ions across nanopore membranes.

“Instead of simply using the basic surface charge of our membrane to dictate the flow, we looked at what happens when voltages are applied,” explains study lead author Makusu Tsutsui. “We used a gate electrode embedded across the membrane to control the field through voltage in a similar way to how semiconductor transistors work in conventional circuits.”

The researchers found that with no voltage applied there was no charge generated by the flow of cations—positively charged ions—because they were attracted to the negatively charged membrane surface.

However, if different voltages were applied, this performance could be tuned to allow cations to flow, even providing complete selectivity for cations. This led to a six-fold increase in the osmotic energy efficiency.

“By enhancing the charge density at the surface of the nanopores that make up the membrane, we achieved a power density of 15 W/m2,” says senior author Tomoji Kawai. “This is very encouraging in terms of progressing the technology.”

The study findings reveal the potential for scaling nanopore membranes for everyday application. It is hoped that nanopore osmotic power generators will provide a means of bringing blue energy to the mainstream for a more sustainable energy future.

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The study, “Gate-All-Around Nanopore Osmotic Power Generators,” was published in ACS Nano at https://doi.org/10.1021/acsnano.4c01989.

About Osaka University
Osaka University was founded in 1931 as one of the seven imperial universities of Japan and is now one of Japan's leading comprehensive universities with a broad disciplinary spectrum. This strength is coupled with a singular drive for innovation that extends throughout the scientific process, from fundamental research to the creation of applied technology with positive economic impacts. Its commitment to innovation has been recognized in Japan and around the world. Now, Osaka University is leveraging its role as a Designated National University Corporation selected by the Ministry of Education, Culture, Sports, Science and Technology to contribute to innovation for human welfare, sustainable development of society, and social transformation.
Website: https://resou.osaka-u.ac.jp/en

 

Structural inequities amplify homelessness challenges for pregnant people in Washington DC




GEORGETOWN UNIVERSITY MEDICAL CENTER





WASHINGTON -- New research conducted with Washington, DC, residents who experienced homelessness during pregnancy sheds light on the intersection of homelessness, pregnancy, and racial inequities. The findings underscore the urgent need for policy and practice changes to support vulnerable populations.

The study, published May 30, 2024 in the journal Health Equity (DOI: 10.1089/heq.2023.0235), is grounded in a reproductive justice framework and delves into the lived experiences of 20 DC residents who faced homelessness while pregnant.

Homelessness during pregnancy is a symptom of broader structural inequities in access to safe and stable housing, and exacerbates adverse health outcomes for birthing people and infants. Conducted by researchers aiming for an action-oriented recommendations, the findings emphasized three key areas for policy and practice improvements:

  • Timely Access to Safe Housing: One of the foremost recommendations is ensuring pregnant individuals have timely and meaningful access to safe and stable housing. The lack of secure housing not only impacts immediate health but also sets the stage for long-term challenges in child-rearing and family stability.
  • Comprehensive Care Coordination: The study advocates for improved care coordination encompassing services and referrals that support physical, mental, and social well-being. Housing insecurity often intertwines with other complex needs, necessitating a holistic approach to healthcare and social support systems.
  • Economic Justice and Affordable Housing: Access to a living wage and affordable housing emerged as critical components. Economic disparities, compounded by lack of affordable housing, disproportionately affect marginalized communities, amplifying the cycle of homelessness and health disparities.

The study’s lead researcher says stable housing is critical to health outcomes for the child and parents.

"Pregnant and parenting people in Washington, DC, must have a stable home as early in pregnancy as possible,” says Christina X. Marea, PhD, MA, MSN, FACNM, assistant professor of nursing at Georgetown’s School of Nursing. “That stability can improve health outcomes for birthing people and infants, support their ability to plan for the postpartum period, and enable them to enjoy this incredible life transition without the unrelenting stress and fear of homelessness.”

The study's insights have directly influenced strategic policy and practice recommendations, paving the way for a new model of collaboration across sectors. Initiatives like the DC Calling All Sectors Initiative (CASI), spearheaded by the DC Health Office of Health Equity, exemplify the commitment to bridging structural gaps and addressing the needs of vulnerable populations.

“The perspectives of people with lived experience has led directly to new initiatives at Community of Hope to support people who are pregnant and experiencing homelessness, says Kelly Sweeney McShane, CEO at Community of Hope, a community health center and homeless services provider who supported the study. “ The perinatal period is such an important one, and stable housing and access to healthcare are important components for both parent and baby during that critical period.”

The study's recommendations align with broader efforts to promote health equity and dismantle systemic injustices. Sustained political will and collaborative endeavors are essential to effectuating tangible improvements in housing accessibility and perinatal care.

The authors stress that as the nation grapples with ongoing challenges in housing insecurity and healthcare disparities, initiatives rooted in community based participatory research, that are intentionally informed by the lived experience of impacted residents, offer a beacon of hope for transformative change. The voices and experiences of those navigating homelessness during pregnancy serve as catalysts for a more inclusive and equitable future.

The work was supported by a grant from the Health Impact Project, a collaboration of the Robert Wood Johnson Foundation and the Pew Charitable Trusts.

C. Anneta Arno, PhD, MPH, Chief Health Equity Officer at DC Health, says, “The Office of Health Equity is appreciative of the grant, which enabled us to tangibly demonstrate the importance of proactive engagement of non-traditional partners, including impacted residents, government agencies, community-based organizations, as well as academia, to inform equity-driven collaborative practice change, by applying a health in all policies framework to address persistent structural barriers to health.”

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In addition to Marea, Arno, and McShane, collaborating researchers include Andrew Lozano, MPH, and Makeda Vanderpuije, MPH CPH,  DC Health Office of Health Equity; Kelley N. Robinson, PhD, CNM, CNE, University of Maryland; Karen Trister Grace, PhD, MSN, CNM, FACNM, George Mason University School of Nursing; and Noelene K. Jeffers, PhD, CNM, IBCLC, Johns Hopkins University School of Nursing.

The authors report having no personal financial interests related to the study.

 

University of Maryland study shows N95 masks near-perfect at blocking escape of airborne COVID-19



Study finds all masks effective, but “duckbill” N95 masks far outperform others, suggests they should be the standard in high-risk settings


UNIVERSITY OF MARYLAND





COLLEGE PARK, Md. – In a head-to-head comparison of masks worn by people with active
COVID-19, the inexpensive “duckbill” N95 came out on top, stopping 98% of COVID-19 particles
in the breath of infected people from escaping into the air. Led by researchers from the University
of Maryland School of Public Health
 (SPH), results showed other masks also performed well,
blocking at least 70% of viral particles from escaping from the source – an infected person’s
exhaled breath.

The study, Relative efficacy of masks and respirators as source control for viral aerosol shedding
from people infected with SARS-CoV-2
, published May 29 in eBioMedicine, a Lancet journal.

“The research shows that any mask is much better than no mask, and an N95 is significantly
better than the other options. That’s the number one message,” says the study’s senior author,
Dr. Donald Milton. Milton is a UMD SPH professor of environmental health and a global expert on
how viruses spread through the air.

The study started in May 2020, shortly after the pandemic began, and compared breath samples
from volunteers who had active COVID-19, testing the performance of four commonly-used
masks. Even without giving participants fit tests or training on how to wear masks correctly, all
masks significantly reduced the amount of virus escaping into the air. The study tested masks as
a way to control the spread of the virus from the source, i.e. the infected person, and did not test
masks as protection from COVID-19 in the surrounding air.

“Because COVID-19 is airborne, we focused on the extent to which wearing a mask reduces
contamination of the air around you,” Milton says. This latest study is a continuation of
investigations by UMD’s Public Health AeroBiology Lab (PHAB Lab) into how contagious
respiratory viruses such as influenza contaminate the air.

Researchers asked volunteers with COVID-19 to breathe into a unique contraption known as the
Gesundheit II Machine, developed by Milton and colleagues to measure viruses in exhaled
breath. Participants, who breathed into the machine for 30 minutes at a time, were asked to do a
variety of vocalizations such as repeating the alphabet, singing Happy Birthday, and even
honoring UMD’s mascot by repeatedly shouting “Go Terps!”

In each instance, researchers measured the amount of viral particles in the exhaled breath of
volunteers, pairing each 30-minute session of breathing with a mask on with another 30-minute
session with no mask.

“Data from our study suggests that a mildly symptomatic person with COVID-19 who is not
wearing a mask exhales a little over two infectious doses per hour,” says first author Dr. Jianyu
Lai, a postdoctoral researcher at the PHAB Lab. “But when wearing an N95 mask, the risk goes
down exponentially.”

The duckbill N95 blocked 99% of large particles and 98% of small particles from escaping out of
a person’s mask. Milton says the design’s tight seal, a powerful filter, and large air space for
breath to move around all contribute to the duckbill’s success.

Surprisingly, KN95 masks – the disposable masks used widely – were no more effective than
cloth or surgical masks. The study found that a common brand of KN95 masks leak more air than
duckbills or other studied masks, because they don’t conform to the face well. That flaw is
compounded by a powerful filter with more flow resistance that pushes air out of the mask at the
sides instead of through the filter, allowing more virus particles to escape into the surrounding air.

Cloth masks also outperformed both KN95 and surgical masks. Milton theorizes that cloth masks
with greater coverage, wrap around the face and give a better seal than either KN95 or surgical
masks. With cloth mask filters, flow resistance is also lower, allowing breath to pass through the
filter and not leak out the sides of the mask.

Limiting the amount of viral particles in the air is a key way to control highly contagious
respiratory viruses in general, Milton said. This is even more the case with the COVID-19 virus,
given transmissibility has increased over time, with Omicron in particular breaking through the
immunity people developed from vaccinations or prior infections.

“Our research shows definitively why it’s so important to have non-pharmaceutical responses like
wearing masks, and why we need studies like this to illuminate which masks are most effective,”
says Milton.

Both Milton and Lai hope that their findings will inform health policies going forward, including
when combatting potential outbreaks like bird flu or even the common flu.

“Duckbill N95 masks should be the standard of care in high-risk situations, such as nursing
homes and health care settings,” Lai says. “Now, when the next outbreak of a severe respiratory
virus occurs, we know exactly how to help control the spread, with this simple and inexpensive
solution.”

In addition to researchers from the UMD School of Public Health, collaborators include authors
from the UMD A. James Clark School of Engineering and the World Health Organization
Collaborating Centre for Infectious Disease Epidemiology and Control at the University of Hong
Kong, China.

This research was supported by the Prometheus-UMD, sponsored by the Defence Advanced
Research Projects Agency (agreement N66001-18-2-4015), the National Institute of Allergy and
Infectious Diseases Centers of Excellence for Influenza Research and Surveillance (contract
12-HHSN272201400008C), and the Centers for Disease Control and Prevention (contract
200-2020-09528); by a grant from the Bill & Melinda Gates Foundation; and by a gift from The
Flu Lab.

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Innovative bird-eye-inspired camera developed for enhanced object detection


A new type of perovskite-based camera specializing in object detection is developed by mimicking bird's eye


INSTITUTE FOR BASIC SCIENCE

Figure 1 

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STRUCTURES AND FUNCTIONS OF BIRD’S EYE. (A) BIRD VISION. (B) DEEP CENTRAL FOVEA AND FOUR TYPES OF CONES. (C) FOVEATED VISION AND TETRACHROMATIC VISION.

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CREDIT: INSTITUTE FOR BASIC SCIENCE




The eyes of raptors such as eagles can accurately perceive prey from kilometers away. Is it possible to model the camera technology after the bird’s eyes?

Researchers developed a new type of camera, which was inspired by the structures and functions of bird's eyes. A research team led by Prof. KIM Dae-Hyeong at the Center for Nanoparticle Research within the Institute for Basic Science (IBS), in collaboration with Prof. SONG Young Min at the Gwangju Institute of Science and Technology (GIST), has developed perovskite-based camera specializing in object detection.

The eyes of different organisms in the natural world have evolved and been optimized to suit their habitat and the environment in which they survive. As a result of countless years of evolutionary adaptation to the environment of living and flying at high altitudes, bird eyes also have unique structures and visual functions (Figure 1a).

In the retina of an animal's eye, there is a small pit called the fovea that refracts the light entering the eye. Unlike the shallow foveae found in human eyes, bird eyes have deep central foveae, which refract the incoming light to a large extent. The region of the highest cone density lies within the foveae (Figure 1b), allowing the birds to clearly perceive distant objects through magnification (Figure 1c). This specialized vision is known as foveated vision.

While human eyes can only see visible light, bird eyes have four cones that respond to ultraviolet (UV) as well as visible (red, green, blue; RGB) light. This tetrachromatic vision enables birds to acquire abundant visual information and effectively detect target objects in a dynamic environment (Figure 1c).

Inspired by these capabilities, the IBS research team designed a new type of camera that specializes in object detection, incorporating artificial fovea and a multispectral image sensor that responds to both UV and RGB (Figure 2a). First, the researchers fabricated the artificial fovea by mimicking the deep central foveae in the bird's eyes (Figure 2b) and optimized the design through the optical simulation. This allows for the camera to magnify distant target objects without image distortion.

The team then used perovskite, a material known for its excellent electrical and optical properties, to fabricate the multispectral image sensor. Four types of photodetectors were fabricated using different perovskite materials that absorb different wavelengths. The multispectral image sensor was finally fabricated by vertically stacking the four photodetectors (Figures 2c and 2d).

The first co-author Dr. PARK Jinhong states, “We also developed a new transfer process to vertically stack the photodetectors. By using the perovskite patterning method developed in our previous research, we were able to fabricate the multispectral image sensor that can detect UV and RGB without additional color filters.”

Conventional cameras that use a zoom lens to magnify objects have the disadvantage of focusing only on the target object and not its surroundings. On the other hand, the bird-eye-inspired camera provides both a magnified view of the foveal region along with the surrounding view of the peripheral region (Figures 3a and 3b). By comparing the two fields of vision, the bird-eye-inspired camera can achieve greater motion detection capabilities than the conventional camera (Figure 3c and 3d). In addition, the camera is more cost-effective and lightweight as it can distinguish UV and RGB light without additional color filters.

The research team verified the object recognition and motion detection capabilities of the developed camera through simulations. In terms of object recognition, the new camera demonstrated a confidence score of 0.76, which is about twice as high as the existing camera system's confidence score of 0.39. The motion detection rate also increased by 3.6 times compared to the existing camera system, indicating significantly enhanced sensitivity to motion.

"Birds’ eyes have evolved to quickly and accurately detect distant objects while in flight. Our camera can be used in areas that need to detect objects clearly, such as robots and autonomous vehicles. In particular, the camera has great potential for application to drones operating in environments similar to those in which birds live,” remarked Prof. Kim.

This innovative camera technology represents a significant advancement in object detection, offering numerous potential applications across various industries.


Bird-eye-inspired camera. (a) Schematic view of bird-eye-inspired camera. (b) Artificial fovea. (c) Schematic of a multispectral image sensor. (d) Multispectral image sensor.


Performance of the bird-eye-inspired camera. (a) Setup for measurement. (b) Bird-eye-inspired camera perceives both the distant object (star) through magnification in the foveal region and nearby objects (triangle, square, circle) in the peripheral region. (c, d) The multispectral image sensor can distinguish UV and RGB light without color filters and capture colored images.

CREDIT

Institute for Basic Science


Local bright spot among melting glaciers: 2000 km of Antarctic ice-covered coastline has been stable for 85 years


first woman to set foot in Antarctica 


A whaler's forgotten aerial photos from 1937 have given researchers at the University of Copenhagen the most detailed picture of the ice evolution in East Antarctica to date


UNIVERSITY OF COPENHAGEN - FACULTY OF SCIENCE

Overview map 

IMAGE: 

OVERVIEW MAP OF THE EXPEDITION ROUTE IN 1936/1937 AND THE AREAS INVESTIGATED BY THE RESEARCHERS.

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CREDIT: MADS DØMGAARD



A whaler's forgotten aerial photos from 1937 have given researchers at the University of Copenhagen the most detailed picture of the ice evolution in East Antarctica to date. The results show that the ice has remained stable and even grown slightly over almost a century, though scientists observe early signs of weakening. The research offers new insights that enhance predictions of ice changes and sea level rise.

Higher temperatures, extreme weather, melting glaciers, and rising sea levels - all indicators that the climate and the world's ice masses are in a critical state. However, a new study from the Department of Geosciences and Natural Resource Management at the University of Copenhagen offers a local bright spot.

Using hundreds of old aerial photographs dating back to 1937, combined with modern computer technology, the researchers have tracked the evolution of glaciers in East Antarctica. The area covers approximately 2000 kilometers of coastline and contains as much ice as the entire Greenland Ice Sheet.

By comparing the historical aerial photos with modern satellite data, the researchers have been able to determine whether the glaciers have retreated or advanced and whether they have thickened or thinned. The study reveals that the ice has not only remained stable but grown slightly over the last 85 years, partly due to increasing snowfall.

“We constantly hear about climate change and new melt records, so it's refreshing to observe an area of glaciers that has remained stable for almost a century,” says PhD student Mads Dømgaard, the study’s first author.    

However, the researcher emphasizes that the study also shows the first signs of changes in the sea ice off the glacier. This could mean that the stable East Antarctic glaciers might shrink in the future.

“Our results also indicate weakening sea ice conditions, making the glaciers’ floating ice tongues more vulnerable and unable to grow as large as seen in the early aerial images from 1937. We know from other parts of Antarctica that the ocean plays an extremely important role and drives the massive and increasing melt we see in e.g. West Antarctica,” says Mads Dømgaard.

Hidden from the Nazis

Most of the images used in the study were captured during a 1937 expedition organized and paid for by Norwegian whaler Lars Christensen. The mission aimed to produce the first maps of this part of East Antarctica, but the maps were never published due to the German invasion of Norway. Since then, the images have been stored at the Norwegian Polar Institute in Tromsø and forgotten.

When the researchers from the University of Copenhagen read about the expedition, they realized that valuable images were likely hidden in an archive in Norway. They traveled to Tromsø and reviewed all 2200 images taken during the expedition. They supplemented the Norwegian aerial images with images of the same glaciers from Australian surveys conducted between 1950 and 1974.

“By comparing the historical aerial photos with modern satellite data, we have gained critical knowledge about glaciers that we would not otherwise have had. I think it's fantastic that these old images can be used to generated new research results almost 100 years after they were taken,” says Assistant Professor Anders Bjørk from the University of Copenhagen, who leads the group working with the historical images.

Potential for major sea level rise

The Antarctic Ice Sheet is receiving increasing attention from researchers, due to its potential for extremely large and rapid sea level rise. Unlike Greenland, very little was known about Antarctica glaciers until the 1990s, when the first good satellite observations became available.

“Early observations of glaciers are extremely valuable as they give us a unique insight into how the ice has evolved through a varying climate and whether current changes in the ice exceed the glaciers' normal cycle of advance and retreat,” explains Mads Dømgaard.

According to the researcher, solid, long-term data is crucial for producing accurate predictions of future glacier evolutions and sea level rise, and this study provides new insights into a vast area in East Antarctica.

“The long time series of glaciers improves our ability to make more accurate models of future ice changes, as the models are trained on historical observations,” concludes Anders Bjørk.

The results have just been published in Nature Communications and are a collaboration between researchers from the University of Copenhagen, the Norwegian Polar Institute, the Arctic University of Norway and the Institute of Environmental Geosciences in France.

Honnörbrygga Glacier in Lützow-Holm Bay in 1937 compared to a modern Landsat satellite image from 2023 


A Stinson Reliant poton aircraft 

The whaling ship Firern, with the Stinson Reliant aircraft on board, near Klarius Mikkelsen Fjell in Lars Christensen Land in East Antarctica. Copyright Norwegian Polar Institute

CREDIT

Copyright Norwegian Polar Institute

More about the study

- Out of 2200 images photographed from seaplanes in 1937, 130 were selected for the analysis.

- The researchers combined the historical photos with modern satellite data to create 3D reconstructions of the glaciers.

- The Norwegian aerial images were supplemented with 165 aerial images of the same glaciers from Australian surveys conducted between 1950 and 1974. This allowed the researchers to examine the evolution of the glaciers over different periods and calculate historical ice flow speeds for selected glaciers.

- Compared to modern data, the ice flow speeds are unchanged. While some glaciers have thinned over shorter intermediate periods of 10-20 years, they have remained stable or grown slightly in the long term, indicating a system in balance.

Authors behind the study:

- The research is funded by the Villum Foundation.