Global Antarctic Research Declines Amid Growing Climate Crisis
Ice loss in Antarctica and its impact on the planet - sea level rise, changes to ocean currents and disturbance of wildlife and food webs - has been in the news a lot lately. All of these threats were likely on the minds of the delegates to the annual Antarctic Treaty Consultative Meeting, which finishes up today in Milan, Italy.
This meeting is where decisions are made about the continent's future. These decisions rely on evidence from scientific research. Moreover, only countries that produce significant Antarctic research - as well as being parties to the treaty - get to have a final say in these decisions.
Our new report - published as a preprint through the University of the Arctic - shows the rate of research on the Antarctic and Southern Ocean is falling at exactly the time when it should be increasing. Moreover, research leadership is changing, with China taking the lead for the first time.
This points to a dangerous disinvestment in Antarctic research just when it is needed, alongside a changing of the guard in national influence. Antarctica and the research done there are key to everyone's future, so it's vital to understand what this change might lead to.
Why is Antarctic research so important?
With the Antarctic region rapidly warming, its ice shelves destabilising and sea ice shrinking, understanding the South Polar environment is more crucial than ever.
Ice loss in Antarctica not only contributes to sea level rise, but impacts wildlife habitats and local food chains. It also changes the dynamics of ocean currents, which could interfere with global food webs, including international fisheries that supply a growing amount of food.
Research to understand these impacts is vital. First, knowing the impact of our actions - particularly carbon emissions - gives us an increased drive to make changes and lobby governments to do so.
Second, even when changes are already locked in, to prepare ourselves we need to know what these changes will look like.
And third, we need to understand the threats to the Antarctic and Southern Ocean environment to govern it properly. This is where the treaty comes in.
What is the Antarctic Treaty?
The region below 60 degrees south is governed by the 1959 Antarctic Treaty, along with subsequent agreements. Together they are known as the Antarctic Treaty System.
Fifty-eight countries are parties to the treaty, but only 29 of them - called consultative parties - can make binding decisions about the region. They comprise the 12 original signatories from 1959, along with 17 more recent signatory nations that produce substantial scientific research relating to Antarctica.
This makes research a key part of a nation's influence over what happens in Antarctica.
For most of its history, the Antarctic Treaty System has functioned remarkably well. It maintained peace in the region during the Cold War, facilitated scientific cooperation, and put arguments about territorial claims on indefinite hold. It indefinitely forbade mining, and managed fisheries.
Lately, however, there has been growing dysfunction in the treaty system.
Environmental protections that might seem obvious - such as marine protected areas and special protections for threatened emperor penguins - have stalled.
Because decisions are made by consensus, any country can effectively block progress. Russia and China - both long-term actors in the system - have been at the centre of the impasse.
What did our report find?
Tracking the amount of Antarctic research being done tells us whether nations as a whole are investing enough in understanding the region and its global impact.
It also tells us which nations are investing the most and are therefore likely to have substantial influence.
Our new report examined the number of papers published on Antarctic and Southern Ocean topics from 2016 to 2024, using the Scopus database. We also looked at other factors, such as the countries affiliated with each paper.
The results show five significant changes are happening in the world of Antarctic research.
The number of Antarctic and Southern Ocean publications peaked in 2021 and then fell slightly yearly through to 2024.
While the United States has for decades been the leader in Antarctic research, China overtook them in 2022.
If we look only at the high-quality publications (those published in the best 25% of journals) China still took over the US, in 2024.
Of the top six countries in overall publications (China, the US, the United Kingdom, Australia, Germany and Russia) all except China have declined in publication numbers since 2016.
Although collaboration in publications is higher for Antarctic research than in non-Antarctic fields, Russia, India and China have anomalously low rates of co-authorship compared with many other signatory countries.
Why is this research decline a problem?
A recent parliamentary inquiry in Australia emphasised the need for funding certainty. In the UK, a House of Commons committee report considered it "imperative for the UK to significantly expand its research efforts in Antarctica", in particular in relation to sea level rise.
US commentators have pointed to the inadequacy of the country's icebreaker infrastructure. The Trump administration's recent cuts to Antarctic funding are only likely to exacerbate the situation. Meanwhile China has built a fifth station in Antarctica and announced plans for a sixth.
Given the nation's population and global influence, China's leadership in Antarctic research is not surprising. If China were to take a lead in Antarctic environmental protection that matched its scientific heft, its move to lead position in the research ranks could be positive. Stronger multi-country collaboration in research could also strengthen overall cooperation.
But the overall drop in global Antarctic research investment is a problem however you look at it. We ignore it at our peril.
(Author: Elizabeth Leane, Professor of Antarctic Studies, School of Humanities, University of Tasmania and Keith Larson, Director of the Arctic Centre, Umeå University)
(Disclaimer Statement: Elizabeth Leane receives funding from the Australian Research Council, the Dutch Research Council, the Council on Australian and Latin American Relations DFAT and HX (Hurtigruten Expeditions). She has received in-kind support from Hurtigruten Expeditions in the recent past. The University of Tasmania is a member of the UArctic, which has provided support for this project.
Keith Larson is affiliated with the UArctic and European Polar Board. The UArctic paid for the development and publication of this report. The UArctic Thematic Network on Research Analytics and Bibliometrics conducted the analysis and developed the report. The Arctic Centre at Umea University provided in-kind support for staff time on the report.)
Hashtags
Try Our AI Features
Explore what Daily8 AI can do for you:
Comments
No comments yet...
Related Articles
Time of India
a day ago
- Time of India
Which is colder, the South or North Pole? And how is life at these places
The North Pole and South Pole are considered the coldest places on Earth, but do you know which one is colder? Well, if you are also curious to know the answer, this one is for you. Read on to learn more about the poles. Locations South and North, both the poles are located at the extremes of the planet, one at the top and the other at the bottom which is why they do not get direct light from the sun. They endure extreme cold and shifts in daylight throughout the year. Both of them consist of vast lands that are frozen, and one can also find unique forms of life here. And the answer is…. The South Pole is colder than the North Pole. According to LiveScience, the annual average temperature at the North Pole is -40 degrees Fahrenheit in winters and 32°F in summers, while the South Pole has an average temperature of -76°F in winters and -18°F in summers. The main difference between the two poles The North Pole or Arctic region is an ocean surrounded by land, while the Antarctic region or South Pole is land surrounded by ocean. This is the key difference between them, which also impacts their climate. Antarctica is a higher continent than the Arctic, which means the higher it is, the colder it will get. The ice in Antarctica is thick and is like a huge plateau, which is also why it is colder. The South Pole is surrounded by water on all sides, so the strength of the winds is stronger, while the North Pole is warmer as the winds slow down here. Life at the poles North Pole: Polar bears, Arctic foxes, and other terrestrial animals wander here in search of food. In the sea ecosystem, one can find shrimps, sea anemones, and tiny crustaceans. A few ringed seals as well as larger marine mammals like narwhals are also spotted here and are much rarer. Certain species of fish are also found, like Arctic cod, and some birds also visit the North Pole a lot, like the Arctic tern, which is the longest annual migration species. This land is also surrounded by inhabited lands like northern Canada, Greenland, Russia, and Alaska, where almost 4 million people live. South Pole: This coast is mainly used for scientific research, as the habitat is too harsh for organisms to survive. The more temperate parts of this pole support certain flora such as moss and lichen, and organisms such as mites and midges. However, one cannot find any native plant or animal life at the pole itself. Now you know that the South Pole is colder than the North Pole, and the habitat found at the two locations is completely different. The North Pole is warmer than the South Pole and has a better habitat for organisms, animals, and fauna, while the South Pole has a harsher climate, which is why only some flora can be seen here. (Image Credits: Canva) Get the latest lifestyle updates on Times of India, along with Friendship Day wishes , messages and quotes !
Time of India
3 days ago
- Time of India
Solar Eclipse on August 2, 2025 or 2027: Fact or Fiction? Find Out Now
There is a lot of confusion on social media about the astronomical event of a solar eclipse, which might be a fantastic chance for sky watchers but most of the people were thinking that it is going to happen on August 2, 2025 which is not truth as it will going to take place on August 2, 2027. The date is same but the year is different and people across the world got excited about it but now we must need to tell you that you have to wait for this celestial event as it is not related to 2025. When is Total Solar Eclipse ? According to the NASA's astronomical reports and panchang also, the Total Solar Eclipse will happen on August 2, 2027. Why everyone is talking about this Eclipse? This eclipse is predicted to be the longest total eclipse that may be seen from land between 1991 and 2114, in comparison to earlier ones. It will be a significant solar eclipse that will occur precisely two years later in 2027 over parts of Europe, North Africa, and the Middle East. It will be a singular and magnificent spectacle. Unlike previous solar eclipses, this one will last for six minutes and twenty-three seconds, making it the longest total solar eclipse ever. People are therefore urged to exercise patience for that event, which is scheduled for 2027 rather than 2025. by Taboola by Taboola Sponsored Links Sponsored Links Promoted Links Promoted Links You May Like Up to 70% off | Shop Sale Libas This was the reason, why astronomers around the world were already getting ready for the extraordinary and one-of-a-kind complete solar eclipse. When is next Solar Eclipse in 2025? According to NASA, the next partial solar eclipse will occur on September 21, 2025. People who are living in the Atlantic, Pacific, Antarctic, and Australian oceans, would be able to witness. Will September 21, 2025 Partial Solar Eclipse be visible in India? No, according to the Panchang, this partial solar eclipse will not be visible in India. Unfortunately Indians wont be able to witness this celestial event. Discover everything about astrology at Times of India , including daily horoscopes for Aries , Taurus , Gemini , Cancer , Leo , Virgo , Libra , Scorpio , Sagittarius , Capricorn , Aquarius , and Pisces . Read your detailed Horoscope Today and Horoscope Tomorrow here.
Time of India
4 days ago
- Time of India
Explainer: How synthetic aperture radar (SAR), at the heart of Nisar, works
Unlike optical sensors, the synthetic aperture radar (SAR) at the heart of the Nisar mission expected to launch at 5.40pm today (July 30), doesn't rely on visible light. SAR uses microwaves, allowing satellites to 'see' through clouds and operate day or night. Tired of too many ads? go ad free now This capability makes SAR a powerful tool for monitoring everything from Antarctic ice to earthquakes and deforestation. From conventional radar to SAR Conventional radar systems send out microwave pulses that bounce off the Earth's surface. The radar then captures the returning echoes, measuring how long the signal took to return, its strength, and frequency shifts. These data reveal information about the object's distance, movement, and texture — but not with high visual clarity. SAR takes this concept further by adding movement and computation into the equation. As a satellite like Nisar orbits Earth, its radar antenna continues to emit and receive microwave pulses. Since the satellite is moving, each return signal comes from a slightly different angle. These slight differences create changes in the frequency of the returned signal — a phenomenon known as the Doppler shift, familiar from how a siren sounds different when approaching and then receding. Synthesising an antenna Ordinarily, to get a radar image with high resolution, one would need a physically enormous antenna — too big to launch or operate in space. For example, Nisar's L-band radar would need a 19-km-wide antenna to produce 10-metre resolution images using traditional radar techniques. Instead, SAR 'synthesises' a large antenna using the movement of a smaller one over time. Nisar's actual radar antenna spans 12 metres when deployed — about the length of a city bus — but through SAR processing, it achieves resolution comparable to that of a much larger antenna. Tired of too many ads? go ad free now In effect, SAR uses the satellite's forward motion to simulate a larger antenna. It stitches together multiple radar returns, aligning them through complex onboard data processing. The spacecraft's flight path becomes like a camera lens sweeping across a landscape, focusing the echoes into a sharp, high-resolution image. Visualising with SAR Once the raw SAR data are collected, they can be processed into different types of images for scientific analysis. ■ Interfero metry (InSAR): By comparing two SAR images of the same location taken at different times, scientists can produce an interferogram. These look like colourful contour maps and highlight subtle shifts in land elevation — crucial for monitoring earthquakes, landslides, and glacier movement. The closer the bands in the image, the greater the surface displacement. ■ Polarimetry : This involves analysing how radar waves are oriented when they return. For example, vertical structures like buildings often reflect waves in the same orientation they were sent, while complex, irregular surfaces like tree canopies alter that orientation. This helps researchers distinguish between different types of land cover and assess damage after floods or storms. Why SAR matters SAR's ability to observe surface change in any weather, at any time, makes it essential for studying Earth's dynamic systems. It supports disaster response, environmental monitoring, and climate science . For example, SAR can measure how much a glacier has retreated, track soil moisture changes during droughts, or detect whether land near a fault line has subtly shifted. As Charles Elachi, former director of Nasa's Jet Propulsion Laboratory, puts it: SAR 'allows us to refine things very accurately.' By capturing frequent and detailed images of the same locations, missions like Nisar can monitor change over time, turning raw radar echoes into critical knowledge about Earth's evolving surface.
