Climate risks to insurance and reinsurance of global supply chains

– a new report from Stockholm Environment Institute 

Stockholm Environment Institute

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Global supply chains are increasingly exposed to climate-related disruptions, redrawing the boundaries of what can be insured and how risk is distributed across the global economy. In recent years insured catastrophe losses have grown by roughly 5–7% per year in real terms. As insurers retreat from high-risk geographies and sectors, the burden of loss increasingly shifts to public budgets, enterprises, and households.

Disruption of international supply chains are a major systemic risk for Europe and countries beyond – alongside food insecurity, energy instability and financial stress. The 2021 floods in Germany and Belgium paralysed logistics and manufacturing across Europe and droughts in southern Europe in 2022 cut harvests and strained water supplies.

“Climate shocks are now driving supply-chain shocks, cascading through interconnected networks rather than remaining isolated disasters. As local weather extremes ripple through interdependent systems, they can quickly become global shortages and delays that threaten economic security,” says Dr. Mikael A. Mikaelsson, Policy Fellow at Stockholm Environment Institute (SEI).

Insurance and reinsurance, the financial mechanisms normally absorbing these shocks, are being tested by the growing complexity, frequency, and severity of climate hazards. The report Insurance and reinsurance under climate stress: managing systemic risk in global supply chains draws on interviews with leading experts from several of Europe’s top (re)insurance actors to examine how these sectors are responding to climate change challenges and the emerging limits of traditional risk-transfer models.

Without substantial changes to business models, regulation, and public-private coordination, there is a risk the sector will undermine stability by amplifying systemic climate stress, the report says.

“Climate risk is becoming systemic faster than insurance systems can adapt – and when losses can no longer be diversified, insurance stops working as designed,” says Mikael A. Mikaelsson.

Key findings

• The physical and financial foundations of insurability are eroding. As hazards increase in number and intensity, assets concentrate in exposed regions and correlated losses across portfolios are undermining the principle of diversification on which (re)insurance depends, accelerating market withdrawals and widening protection gaps.
• While innovative solutions, such as parametric products, Contingent Business Interruption (CBI) cover and resilience-linked assessments, offer valuable tools, they are limited in scope and reliability.
• The scope of insurance coverage remains narrowly focused on assets and direct damages, excluding slow-onset, indirect and social dimensions of climate risk. Climate-related risks to human health and productivity among supply-chain workers are particularly under-recognized.
• Structural and technical limits – including reliance on historical data, incomplete climate-adjusted modelling, and fragmented risk metrics – undermine insurers’ ability to anticipate systemic exposure. There is a need for harmonized standards and forward-looking, probabilistic models.
• Short-term underwriting cycles and annual repricing prevent insurance from supporting long-term adaptation, since the focus on immediate solvency and profitability conflicts with the multi-decadal nature of climate risk.
• Risks to labour in supply chains are effectively invisible to current life and health insurance systems, particularly in physically exposed roles such as agriculture, construction, and logistics. Workers in such roles often fall outside formal insurance systems, and even when insured, climate-related illness, productivity loss, or mental health impacts are rarely recognized or compensated.

“Insurance alone cannot manage systemic climate risk. Without stronger adaptation, better data, and coordinated public–private governance, risk transfer will increasingly fail where resilience is needed most,” says Mikael A. Mikaelsson.

About the report

The report is based on a literature review and expert consultations with senior climate risk specialists across the European (re)insurance ecosystem. Based on the findings, three recommendations are directed at policymakers and regulators, the (re)insurance sector, and businesses whose operations depend on insurable and resilient supply chains.

For further information, contact:

In Stockholm, Sweden

Mikael Allan Mikaelsson, Policy Fellow, SEI, mikael.mikaelsson@sei.org, +46 73 050 1818

Ulrika Lamberth, Senior Press Officer, SEI, ulrika.lamberth@sei.org, + 46 73 801 7053

In Seattle, US

Lynsi Burton, Communications Officer, SEI US, lynsi.burton@sei.org, +1 360 485 3041

Stockholm Environment Institute is an international non-profit research institute that tackles climate, environment and sustainable development challenges. We empower partners to meet these challenges through cutting-edge research, knowledge, tools and capacity building. Through SEI’s HQ and seven centres around the world, we engage with policy, practice and development action for a sustainable, prosperous future for all. www.sei.org @SEIresearch

Global warming and CO2 emissions 56 million years ago resulted in massive forest fires and soil erosion

Royal Netherlands Institute for Sea Research

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56 million years ago, the Earth was already warm. ‘As a result, there was a lot of vegetation, even at high latitudes. That means that a lot of carbon was stored in, for example, vast coniferous forests.’ Biologist Mei Nelissen is conducting PhD research at NIOZ and Utrecht University. She analysed pollen and spores in clearly layered sediment that her supervisors had drilled from the seabed in the Norwegian Sea in 2021. This revealed unique information in great detail – even per season – about what happened when the Earth warmed by five degrees in a short period of time those 56 million years ago.

Layers in drill cores

Nelissen: 'We could see that within a maximum of three hundred years from the start of the explosive increase in CO2, the conifer-dominated vegetation disappeared at the studied site and many ferns appeared. The ecosystems on land were disrupted for thousands of years; an increase in charcoal indicates that there were more forest fires. An increase in clay minerals in the sea sediment also indicates that entire sections of land washed into the sea due to erosion.' Thanks to the exceptionally well-defined layers in the sediment – even per season! – researchers were able to demonstrate for the first time how quickly trees and plants respond to disruption.

More was already known about the major impact on the sea, says Nelissen. ‘In drill cores from the deep sea, for example, we see that there is suddenly no more calcium carbonate, because the seawater rapidly acidified due to all the CO2 it absorbed. This made the water too acidic for organisms to form calcium carbonate skeletons or shells.’

Even faster warming now than then

What was going on? The period around 56 million years ago is known as the PETM: Paleocene-Eocene Thermal Maximum. It was already warm and ‘suddenly’ it became even warmer. Nelissen: 'The cause is unknown; it is probably a combination of factors. Methane hydrates in the seabed became unstable due to the heat, which led to methane emissions. There was also a lot of volcanic activity during that period.' Nowadays, climate change is mainly due to the burning of fossil fuels. ‘Today, CO2 emissions are about two to ten times faster than in the PETM, but the rate at which CO2 concentrations in the atmosphere increased at that time is closest to the increase caused by human emissions. In geological terms, such a rate is unprecedented.’

The disruption amplified the warming

It is important to know what consequences the disruption of the carbon cycle and warming had at that time, because we can deduce what lies ahead if the rapid warming of today continues, the researchers write. We are already seeing more forest fires, but we also expect more extreme weather with more intense rainfall, flooding and drought. Nelissen: 'We must take this seriously. Our results are consistent with findings from other researchers in other areas. We now know that terrestrial ecosystems can respond quickly and dramatically to climate change. The carbon released into the atmosphere by the terrestrial disturbances, including fires and soil erosion,can further exacerbate global warming.'

Milestone in the research

Nelissen's supervisors Joost Frieling (University of Oxford and Ghent University) and Henk Brinkhuis (NIOZ and Utrecht University) went on a sea expedition with the International Ocean Discovery Program in 2021 to take sediment samples.

The drill cores turned out to be particularly clearly ‘laminated’: they showed very distinct layers, even per season. When they found the microfossils of the algae Apectodinium augustum, they happily posed for a photo together. Nelissen: ‘That's when my PhD position came about. This microfossil was proof that this beautifully preserved sediment comes from the PETM period, the period that researchers are keen to learn more about.’

[Article]

Widespread terrestrial ecosystem disruption at the onset of the Paleocene-Eocene Thermal Maximum, PNAS, Mei Nelissen, Debra A. Willard, Han van Konijnenburg-van Cittert, Gabriel J. Bowen, Teuntje Hollaar, Appy Sluijs, Joost Frieling, Henk Brinkhuis

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Journal

Proceedings of the National Academy of Sciences

Method of Research

Experimental study

Subject of Research

Not applicable

Article Title

Widespread terrestrial ecosystem disruption at the onset of the Paleocene-Eocene Thermal Maximum

Article Publication Date

19-Jan-2026

 

A two-week leap in breeding: Antarctic penguins’ striking climate adaptation

University of Oxford

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image: 

Gentoo colony at Neko Harbour (ES: Puerto Neko). An egg is visible at one of the nests. Credit Ignacio Juarez Martinez

view more 

Credit: Ignacio Juarez Martinez

More images available via the link in the notes section

 

A decade-long study led by Penguin Watch1, at the University of Oxford and Oxford Brookes University, has uncovered a record shift in the breeding season of Antarctic penguins, likely in response to climate change. These changes threaten to disrupt penguins’ access to food and increase interspecies competition. The results have been published today (20 January - World Penguin Awareness Day) in the Journal of Animal Ecology.

Lead author Dr Ignacio Juarez Martínez (University of Oxford/Oxford Brookes University) said: “Our results indicate that there will likely be ‘winners and losers of climate change’ for these penguin species. Specifically, the increasingly subpolar conditions of the Antarctic Peninsula likely favour generalists like Gentoos at the expense of polar specialists like the krill-specialist Chinstraps and the ice-specialist Adélies. Penguins play a key role in Antarctic food chains, and losing penguin diversity increases the risk of broad ecosystem collapse.’

The researchers examined changes in the timing of penguin breeding between 2012 and 2022, specifically their “settlement” at the colony, the first date at which penguins continuously occupied a nesting zone. The three species of penguins studied were the Adélie (Pygoscelis adeliae), Chinstrap (P. antarcticus) and Gentoo (P. papua), with colony sizes ranging from a dozen to up to hundreds of thousands of nests. They used evidence from 77 time-lapse cameras overlooking 37 colonies in Antarctica and some sub-Antarctic islands, which ensures conclusions are relevant to species as a whole and not just specific populations.

The results demonstrated that the timing of the breeding season for all three species advanced at record rates. Gentoo penguins showed the greatest change, with an average advance of 13 days per decade (up to 24 days in some colonies). This represents the fastest change in phenology recorded in any bird – and possibly any vertebrate – to date. Adélie and Chinstrap penguins also advanced their breeding by an average of 10 days.

Senior author Professor Tom Hart (Oxford Brookes University and founder of Penguin Watch) said: “Ecologists are good at counting populations to show trends, but often the early warnings of decline can be found in the behavioural change of animals, which can be very hard to monitor. The idea of this whole monitoring network is to put something in place that does both; monitoring populations and their behavioural responses to threats. This study proves the benefits of monitoring animals at a landscape level.”

These record shifts are happening in relation to changes in the environment including sea-ice, productivity and temperature. Each monitoring camera was equipped with a thermometer, enabling researchers to also track the temperature changes at colonies. The data revealed that colony locations are warming up four times faster (0.3ºC/year) than the Antarctic average (0.07ºC/year), making them one of the fastest-warming habitats on Earth.

Though statistical models suggest that temperature appears to be one of the dominant drivers of the observed shifts in breeding season, it remains unclear whether the changes reflect an adaptive response or not, risking a potential mismatch with other ecological factors such as prey availability. Even in the best-case scenario, it is unclear how much more elasticity these species will be capable of displaying if temperatures keep rising at the current rate.

Co-author Dr Fiona Jones (University of Oxford) added: “As penguins are considered 'a bellwether of climate change', the results of this study have implications for species across the planet. Further monitoring is needed to understand whether this record advance in the breeding seasons of these penguin species is impacting their breeding success.”

This research was also made possible thanks to international collaborators in the UK (University of Oxford, Oxford Brookes University, British Antarctic Survey), US (Stony Brook University, NOAA) and Argentina (CADIC-CONICET). The researchers would also like to thank the John Ellerman Foundation, Save our Seas Foundation, Quark Expeditions and the UK Government's Darwin Plus funding scheme for their support.

Notes to editors:

For media enquiries and interview requests, contact Ignacio Juarez at ijuarez.research@gmail.com and Tom Hart at t.hart@brookes.ac.uk

The study ‘Record phenological responses to climate change in three sympatric penguin species’ will be published in Journal of Animal Ecology at 05:01 AM (GMT), Tuesday 20 January, 2026 at doi.org/10.1111/1365-2656.70201. To view a copy of the study before this under embargo, contact ijuarez.research@gmail.com

Images available to use in articles can be found here Outreach Images IJM. These are for editorial purposes relating to the press release ONLY and MUST be credited. They MUST NOT be sold on to third parties.

About the University of Oxford

Oxford University has been placed number 1 in the Times Higher Education World University Rankings for the tenth year running, and ​number 3 in the QS World Rankings 2024. At the heart of this success are the twin-pillars of our ground-breaking research and innovation and our distinctive educational offer. Oxford is world-famous for research and teaching excellence and home to some of the most talented people from across the globe. Our work helps the lives of millions, solving real-world problems through a huge network of partnerships and collaborations. The breadth and interdisciplinary nature of our research alongside our personalised approach to teaching sparks imaginative and inventive insights and solutions. Through its research commercialisation arm, Oxford University Innovation, Oxford is the highest university patent filer in the UK and is ranked first in the UK for university spinouts, having created more than 300 new companies since 1988. Over a third of these companies have been created in the past five years. The university is a catalyst for prosperity in Oxfordshire and the United Kingdom, contributing around £16.9 billion to the UK economy in 2021/22, and supports more than 90,400 full time jobs.

About Oxford Brookes University
www.brookes.ac.uk

Oxford Brookes is one of the UK's leading modern universities, and is amongst the world’s top universities in 23 subject areas. Oxford Brookes prides itself as a diverse and inclusive university with students and staff from over 170 countries and it enjoys an international reputation for teaching excellence as well as strong links with business, industry and the public sector.

1. Penguin Watch project
https://www.polarsentinels.org/projects/penguin-watch

Penguin Watch is the largest penguin monitoring project in the Southern Ocean. Initiated at the University of Oxford in 2009 and currently hosted at Oxford Brookes University, it focuses on disentangling the confounded threats faced by penguins by harnessing time-lapse cameras to monitor penguin colonies year-round.

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Journal

Journal of Animal Ecology

DOI

10.1111/1365-2656.70201 

Article Title

Record phenological responses to climate change in three sympatric penguin species

Article Publication Date

20-Jan-2026

Chinstrap penguin with its chick. Chinstrap penguins are more oceanic and they are krill specialists that only hunt krill in open waters. This species is declining fast throughout their range with some models showing this species could go extinct before the end of the century. Credit Ignacio Juarez Martinez.

Adélie penguin (ES: Pingüino Adelia) with its chick at Madder cliffs colony (ES: Cabo Madder). This species lives in the iciest of conditions as they hunt krill among the ice. They are considered one of the true antarctic penguins together with the Emperor Penguin and their numbers are shrinking in West Antarctica, our area of study. Credit Ignacio Juarez Martinez.

CIgncio Juarez, leader of the study, servicing one of the monitoring cameras overlooking a Chinstrap colony at Spigot Peak (ES: Nunatak Negro), Antarctica. These 77 cameras need to be manually serviced once a year to download the images, change the batteries and check on the stability of the tripods. Credit Ignacio Juarez Martinez

Credit

Ignacio Juarez Martinez