Wednesday, April 09, 2025

Predicting animal movements under global change

Why science fails in this vital task and how it can improve

Swansea University

African lions on a road, Hluhluwe National Park, South Africa — image:
Young African lions (*Panthera leo*) on the road in Hluhluwe National Park, South Africa. When they leave their mothers, young male lions have to disperse to find new territories. To do this, they travel through the savannah, now dominated by roads and tourist activities, which have an impact on their behaviour and movements.
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Credit: Sara Gomez, CEFE-CNRS, Montpellier University

New research will help scientists predict where and when animals will move, a task which is becoming more urgent, given the current rapid pace of global change.

On our planet, at any one moment, billions of animals are on the move. From migratory birds, insects, marine mammals and sharks connecting distant continents and seas, to bees and other insects pollinating our crops, to grazing animals roaming across the plains, and the foxes and hedgehogs visiting urban gardens.

Understanding the complexities of how and why animals move is vital. It can help to conserve species, but also to protect wider ecosystems and our environment and the many services these provide to human wellbeing.

The study of animal movement has grown fast in recent decades. Most animal movements go unobserved by humans, but using technology - radiotracking, GPS, satellite tags, Fitbit-type sensors, radar - we can record them in impressive detail. Billions of new data are recorded each year, analysed using increasingly sophisticated statistical and mathematical methods.

However, much of this work still focuses on describing and understanding current patterns, rather than predicting future movements.

The problem is that using the past and present as a guide will be of limited use given how quickly environments are changing, due to new patterns of land use, climate change, and human population shifts.

This is where the new research comes in. It sets out a framework that can help scientists provide more robust predictions in rapidly changing environmental conditions.

The research has been carried out by an international team, formed during an annual meeting of the Movement Ecology group of the British Ecological Society, led by Prof Luca Börger of the Department of Biosciences at Swansea University and two former students from the department, Sara Gomez and Dr Holly English, who are now researchers at the CNRS in Montpellier (France) and University College Dublin (Ireland), respectively.

In the research paper, the team set out the full range of human-induced changes in environmental conditions and review how they impact and drive animal movements. These include overall changes in climate, such as warming oceans, as well as more specific impacts such as urbanisation, construction, light pollution, oil spills and invasive species.

They highlight how scientists need to change the ways they collect and model data, in order to develop better predictions about how animals move in changing landscapes, and how this can be used to design improved conservation actions and policies.

Lead author Sara Gomez of CNRS (Centre National de la Recherche Scientifique) Montpellier said:

“To predict where animals will move in rapidly changing environments, we cannot rely on correlative approaches. We must incorporate biological mechanisms into our models, starting from first principles of animal movements and decision making, and develop models adequate for dynamical systems.

We must also increase the number of different species studied and record their movements also in human-dominated environments and not only in more undisturbed natural areas”.

Co-lead Dr Holly English of University College Dublin said:

“This is not just for scientific interest. We discuss the challenges and opportunities of including these predictions into more effective wildlife management and policy. We give examples of conservation schemes, such as rewilding and translocations, which offer exciting, but vastly unused, opportunities to collect data from novel environments and test our model predictions.”

Professor Luca Borger of Swansea University biosciences department, lead researcher, said:

“Animal movements fundamentally affect ecosystem processes. Current research in the field however fails to address one of the most pressing problems we are facing: predicting where and when animals will move in rapidly changing or ‘novel’ environments. We believe we are at an exciting point now where we can achieve such a crucial transformation in our field, from a descriptive to a predictive science, which is much needed under current rapid global change.”

The research is published in the Journal of Animal Ecology, under the title 'Understanding and predicting animal movements and distributions in the Anthropocene '.

END

African elephant walking along a road in Hluhluwe National Park, South Africa (IMAGE)

Swansea University

African elephant (*Loxodonta loxodonta*) walking along a road in Hluhluwe National Park, South Africa. Elephants can cover dozens of kilometres a day in the savannah. Because they facilitate travel, roads are often used by elephants and ultimately shape their movements and their distribution in the landsca

Zebra (Equus Burchellii) fitted with a GPS collar in Hluhluwe National Park, South Africa. Tracking technologies have improved considerably in recent decades, allowing researchers to follow the movements of animals in the wild and better understand their use of the human-modified landscape.

Credit

Sara Gomez, CEFE-CNRS, Montpellier University

Notes to editors:

Founded in 1920, Swansea University is a research-led institution with two campuses along Swansea Bay in south Wales, UK. Its scenic beachfront location and welcoming atmosphere attract more than 28,000 students from around the world.

In 2024, Swansea achieved its highest-ever ranking in the QS World University Rankings 2025, reaching 298th globally and entering the top 300 for the first time. It was also named Welsh University of the Year 2025 by The Times and Sunday Times, and ranked 29th in the Guardian University Guide 2025.

The 2021 Research Excellence Framework rated 86% of Swansea’s research and 91% of its research environment as world-leading or internationally excellent, with 86% of its research impact recognised as outstanding.

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Journal

Journal of Animal Ecology

DOI

10.1111/1365-2656.70040

Article Title

Understanding and predicting animal movements and distributions in the Anthropocene

Article Publication Date

4-Apr-2025

U.S. global scientific enterprise leadership status at risk

Biophysical Society

ROCKVILLE, MD – The Biophysical Society, on behalf of its members in the U.S. and around the world, is alarmed by the ongoing reductions in force (RIFs) and how those reductions will impact the ability of federal research funding agencies to support the missions outlined by Congress. For decades the U.S. has been a world leader in critical and emerging technologies; which has attracted the best and brightest around the world to matriculate and engage in new discoveries, develop critical technologies and advance scientific research. The utilization of RIF initiatives to roll back the federal workforce threatens to have a chilling effect on development of future basic and biomedical researchers, and also jeopardizes the scientific, technological and economic advancements that have made the U.S. a global leader in scientific enterprise.

While change is always challenging in any industry or endeavor, within the realm of scientific research abrupt starts and stops that come from pauses in funding, loss of program directors and general uncertainty as to whether funding will be awarded or continued will have far-reaching consequences. Throughout the years, Congress and the scientific community have worked collaboratively toward providing stable, predictable funding for basic and biomedical research.

The Biophysical Society stands ready to work with Congress and the Administration to engage in the goal of reducing federal waste, without sacrificing the robust federal investment in science that has made the U.S. a global leader and yielded tremendous benefits for our national security and economic prosperity. Maintaining these benefits requires continued investment in intramural and extramural research to enable the missions of federal science agencies.

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The Biophysical Society, founded in 1958, is a professional, scientific Society established to lead the development and dissemination of knowledge in biophysics. The Society promotes growth in this expanding field through its meetings, publications, and committee and outreach activities. Its 7,000 members are located throughout the United States and the world, where they teach and conduct research in colleges, universities, laboratories, government agencies, and industry.

Development of a chaotic light receiver for secure communication in hostile environments

A study by Télécom Paris and the Politecnico di Milano in Light: Science & Applications

Politecnico di Milano

image:
Photo of the photonic chip made
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Credit: Politecnico di Milano

Milan, 8 April 2025 - Development of a new type of optical receiver, able to restore chaotic signals in free-space optical communication links distorted by atmospheric turbulence. By use of a system of optical antennas integrated into a programmable photonic chip, the receiver can adapt in real time, maintaining the integrity of the signal even in harsh atmospheric conditions. The study by a team of researchers led by Télécom Paris and the Politecnico di Milano, has just been published in Light: Science & Applications, and paves the way for the use of chaos-based encryption for secure, high-speed communication in hostile environments.

The idea behind secure, chaos-based communication is to encode a secret message into a light signal, which appears so unpredictable and complex that it is almost impossible to decipher. However, when these chaotic signals travel in the real wireless world, they encounter a major obstacle: atmospheric turbulence. And what's the result? Transmissions are distorted and security is compromised.

The Study has found a solution to this problem. The secret lies in a new type of receiver, which uses a system of optical micro-antennas integrated into a programmable photonic chip. The micro-antennas act like many "smart eyes", capturing light from multiple points of view; the photonic chip self-calibrates in real time to rebuild these fragments into a secure and reliable chaotic signal.

The result is amazing: even in the presence of heavy rain, wind or pollutants, the signal can be fully retrieved.

Sara Zaminga, of LTCI Télécom Paris, Institut Polytechnique de Paris and author of the study, explained the thinking behind it: "Chaos is a robust system, but can only be used in cryptosystems if its inherent nature is fully preserved. Atmospheric turbulence degrades the optical signal and apparently destroys the properties of chaos, making it hard to maintain secure and reliable communications. With our approach, we're not just mitigating the effects of turbulence, we're completely restoring the chaos of light in all its intrinsic complexity."

Andrés Martínez of the Department of Electronics, Information and Bioengineering at the Politecnico di Milano and co-author of the study, also added this: "What makes this solution really special is its ability to adapt in real time. Our receiver automatically adjusts to changes in the amount of turbulence, ensuring a stable and secure channel of communication without the need for manual interference."

Why is all this so important? Chaos-based systems have an inherent advantage: their unpredictability makes them naturally secure. However, atmospheric turbulence by its very nature has long constituted a main obstacle to optical wireless communications.

The impacts of this advance go far beyond its technological applications, providing new ways to send confidential messages even in extreme conditions. As Francesco Morichetti, head of the Photonic Devices Lab at the Politecnico di Milano, pointed out: "In remote areas or emergency zones, places where traditional networks fail, a chaos-based, turbulence-resistant system could provide a secure connection when it's most needed."

This work was supported by the NextGenerationEU National Recovery and Resilience Plan (PNRR), the partnership on "Telecommunications of the Future" (PE00000001 —"RESTART" programme, the "Rigoletto" Structural Project and "HePIC" Targeted Project), by the Direction Générale de l 'Armement (DGA), by the European Office of Aerospace Research and Development (FA8655-22-1-7032) and by the Chair in Photonics. The research work also involved Polifab, the micro and nano-fabrication facility of the Politecnico di Milano (https://www.polifab.polimi.it/)

Artistic representation of the optical chip receiving a light beam deteriorated by atmospheric turbulence and recovering its integrity.