Hail conditions on the move as winter crops face rising risk

University of New South Wales

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A hailstorm can undo a season’s work in minutes. It can strike quickly and unevenly, shredding wheat, bruising fruit, flattening crops – while also leaving neighbouring paddocks untouched.

In a new Nature Climate Change study, scientists from UNSW Sydney say the geography and seasonality of that risk is changing.

As the planet warms, the atmospheric conditions that produce damaging hail are projected to shift away from some warmer regions towards the cooler parts of the world – including south-eastern Australia and New Zealand.

Lead author Dr Tim Raupach from the UNSW Institute of Climate Risk and Response says this is part of an overall hail condition frequency shift towards the poles.

“Under modelling scenarios of 2°C and 3°C of global warming, we see this overall shift towards more risk in cooler places and cooler times of the year,” Dr Raupach says.

“So increasing risk in winter and often decreasing risk in summer – a shift from warmer to cooler regions and seasons,” he says. “Those cooler regions include not only parts of southern Australia and New Zealand, but northern North America and Europe.

“And there are decreases – though still with a lot of uncertainty – in the subtropics and parts of the mid-latitudes. This includes much of Australia as well as regions of India, China and much of Africa.”

An atmospheric tug of war

Because hailstorms are brief and difficult to observe, the researchers did not model hailstones directly. Instead, they used three different proxies, or methods, to detect atmospheric conditions that occur when hail is more likely to form.

These proxies did not always agree, particularly in the tropics, underscoring how difficult future hail risk remains to predict. The disagreement showed that with a warmer atmosphere, several forces act at the same time.

“Usually, as the atmosphere gets warmer, we expect it to have more energy, which could be turned into updrafts,” Dr Raupach says. Updrafts are a key feature of hailstorms.

“When you have these strong winds in the thunderstorms, they can support the growth of larger hailstones,” he says.

At the same time, warmer air also raises the level at which frozen hailstones begin to melt.

“There is a lot more melting in a warmer atmosphere,” Dr Raupach says.

“This can make smaller hailstones melt away.”

The result is an offsetting effect, or an atmospheric tug of war, where warming pushes the system in two directions at once.

“The atmosphere might be more prone to create storms, but the storms that are created might be less likely to have hail reach the ground,” Dr Raupach says.

However, he says the concern is that while hail may become less common across some regions or seasons, they may be more destructive when they do happen.

“Larger hailstones are more likely with stronger storm dynamics,” he says. “That still has important implications for agriculture.”

Winter crops in the firing line

A decrease in summer hail risk also does not necessarily help a winter crop if the danger rises during growing season.

The researchers examined 26 major crop types globally.

“One of the things that makes this study unique is that we looked at the changes in risk to crops based on the hazard changes that we see in the hail-prone environments,” Dr Raupach says.

He and the team looked at what proportion of each crop’s growing season was likely to be affected by hail-prone conditions, and how that exposure changed in future climate projections.

“We saw in the future projections that often the hazard was increasing for winter crops.”

In Australia, where wheat is a major winter crop, the signal is clearest in the south-east – from Tasmania up along the broad arc from Melbourne towards Sydney – where hail-prone environment increases appear in both past trends and future projections.

Risk planning

A crop does not even need to be damaged often for hail to matter – just one severe storm is enough. But for farmers, insurers and policymakers, it is a difficult risk to plan around.

The findings also complicate some assumptions about climate adaptation. As global warming forces crop-growing regions to shift poleward, agriculture may also move into areas where hail risk is increasing.

This means that potential gains from a warmer climate, such as new growing zones or longer seasons in cooler regions, could be offset by exposure to more damaging storm conditions.

Dr Raupach says the uncertainty surrounding future hail risk remains a major challenge.

“It’s hard,” he says. “The uncertainty of it and the difficulty in getting at exactly what’s going on is one of the challenges that we face, and that decision-makers face.

“But we can make broad statements. And the shift towards the poles is the broad statement we can make here.”

Dr Joanna Aldridge is the Head of Research & Development, Catastrophes at QBE, which supported the research.

She says this work is building the scientific evidence base needed to understand how hail risk is shifting.

“This enables better risk assessment, resilience planning and decision-making across industries such as insurance and agriculture,” Dr Aldridge says.

On the move

For Australia, another broad statement concerns the south-east of the continent.

“The southeast of Australia comes up not only in the trends that we see in the past, but also in the future projections as a place where the hazard is increasing,” Dr Raupach says.

While hail has often received less public attention than other climate-linked agricultural threats – such as drought, heatwaves, floods and bushfires – for farmers it can be one of the most immediate and damaging hazards.

The study warns these overlapping shifts “may attenuate any positive impact on crop yields in a warming world”.

 

Dr Tim Raupach’s position at UNSW is supported by QBE Insurance. Dr Raupach and study co-author Professor Steven Sherwood are affiliated with the UNSW Climate Change Research Centre and the ARC Centre of Excellence for 21st Century Weather – where Dr Raupach is an Associate Investigator and Prof. Sherwood is a Chief Investigator.

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Journal

Nature Climate Change

DOI

10.1038/s41558-026-02660-7 

Article Title

Shifting hail hazard under global warming and effects on crop hail risk

Article Publication Date

3-Jun-2026

Help wanted: Australian conservation group seeks new koala rescue dog

Sydney (AFP) – An Australian animal welfare group is seeking a heroic dog with an appetite for adventure for a full-time position as a koala rescuer.

Issued on: 20/05/2026 - FRANCE24

Bear the koala rescue dog has retired, and an Australian animal welfare group is looking for his successor © Handout / International Fund for Animal Welfare (IFAW)/AFP

The successful pooch will replace the world-famous Bear, credited with saving over 100 koalas from bushfires during a decade of service.

"Bear set the gold standard for koala detection dogs," the International Fund for Animal Welfare (IFAW) Oceania head of programmes Josey Sharrad said.

"He's leaving very big boots to fill, but now it's time to find his successor to follow in his pawprints and keep protecting koalas."

The ideal candidate will be a rescue pup with a lot of energy and an "obsessive" personality -- attributes that might make it hard to find a home but which make it perfect for saving koalas, IFAW said.

"By only recruiting a rescue dog, it's a win-win -- giving a dog the chance of a new life while helping our iconic koalas," Innovation for Conservation director and handler Russell Miller said.

Other key attributes are a love of play, confidence and a gentle temperament towards fellow animals is crucial.

They must also be medium sized -- "not too small that they struggle in the bush, not too big that the handlers can't carry them when needed", according to the IFAW job ad.

Interviews were being held in eastern Australia's Sunshine Coast but applications by video are also welcome.

Bear's skills saved over 100 koalas as the Black Summer bushfires raged across Australia's eastern seaboard from late 2019 to early 2020, razing millions of hectares, destroying thousands of homes and blanketing cities in noxious smoke.

The tail-wagging detective with a "joyful and goofy" personality retired with an extensive list of accolades -- including an Animal of the Year award and Puppy Tales Photos Australian Dog of the Year award.

© 2026 AFP

 

Koala milk study may hold key to better care for orphaned joeys

Edith Cowan University

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New research into koala milk could prove crucial to future conservation of the iconic, yet endangered Australian species.

The paper, led by Edith Cowan University (ECU) PhD candidate Manujaya W. Jayamanna Mohottige, is part of a larger study into koalas and their survival led by the Australian Wildlife Genomics Group at The University of Sydney and the Australian Research Council Centre of Excellence for Innovations in Peptide and Protein Science. Mr Mohottige’s PhD work reveals how koala milk transforms throughout the first year to meet a growing joey’s needs.

“Koala milk is more than just food. It contains peptides and proteins that help the joey grow stronger, supporting energy, development and early protection,” Mr Mohottige explained. “Young koalas are born tiny and fragile. They rely heavily on their mothers to grow, stay safe and survive.

“A healthy pouch environment, together with nutrition and immune protection from its mother’s milk, is essential for a joey’s growth and survival.”

Unlike human milk, marsupial milk is known to change its composition over time to meet the joey’s evolving growth and immune needs. This study followed koala milk across early, mid and late lactation stages, uncovering how it adapts to meet the needs of the growing young.

“We were able to identify and quantify the proteins at each key lactation stage,” Mr Mohottige said. “Early milk plays a key role in protecting the joey, mid-stage milk may help protect the brain during its fastest growth, and later milk has a composition reflecting the joey’s increasing independence.”

A deeper understanding of koala milk could help scientists develop improved milk substitutes for orphaned joeys, strengthening rehabilitation efforts and supporting koala conservation.

Professor Michelle Colgrave from ECU’s School of Science said koalas faced many threats, including bushfires, road accidents, disease and habitat loss.

“The ultimate goal of our study is to improve milk formulas for orphaned koala joeys by adding key peptides and proteins found in natural koala milk, helping them survive and grow stronger,” Professor Colgrave explained. “Many young koalas that enter rehabilitation centres need to be hand-reared, and survival rates can be improved.

“Koalas have an extremely short gestation period of just over a month and complete most of their development in the pouch. That is why the proteins and peptides in their milk play such crucial roles in providing both nutrition and immune protection to the developing joey.

“Matching milk replacers to the natural shifts we see in koala milk could greatly help hand-reared joeys grow and thrive,” she said.

The next step for the research team is to study how the milk proteins are influenced by where they live, what they eat and their genetic differences.

Lactation-stage specific protein shifts in koala milk mirror the joey's growth needs was published in the International Journal of Biological Macromolecules.

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Journal

International Journal of Biological Macromolecules

DOI

10.1016/j.ijbiomac.2026.151640 

Method of Research

Meta-analysis

Subject of Research

Animals

Article Title

Lactation-stage specific protein shifts in koala milk mirror the joey's growth needs

 

Researchers reconstruct path and intensity of China's Guangzhou 'April 27' tornado using multi-source data

KeAi Communications Co., Ltd.

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image: 

Damage Assessment Map: Documenting the Damage Swath and Survey Sites.

view more 

Credit: Yi Yang

Existing disaster investigation systems often focus on meteorological cause analysis, while systematic research from the perspective of structural wind engineering on building damage mechanisms remains relatively limited.

In a study published in the journal Advances in Wind Engineering, researchers from South China University of Technology and collaborating institutions described the EF3-level tornado that occurred in Guangzhou, China on April 27, 2024. They achieved this by integrating methods such as UAV remote sensing, detailed ground-based post-disaster surveys, and mesoscale numerical simulation.

"This research combines meteorological simulation with structural damage analysis, systematically examining the tornado disaster from an engineering perspective," shares corresponding author Professor Yi Yang. "The findings can provide empirical data reference for refining the descriptions of engineering structural damage in China's national standard, the 'Tornado Intensity Scale'."

In the study, the research team established six main survey lines and 12 branch lines within an affected area of approximately 15 square kilometers in Guangzhou’s Baiyun District, collecting and analyzing disaster data from 471 characteristic sites. By examining nearly 500 sets of UAV images and about 1,200 sets of ground-based photos and videos, the team delineated the tornado's path: moving from west to east-southeast, with a total length of approximately 8.2 kilometers, an average width of 0.7 kilometers, and a maximum width reaching 1 kilometer. Based on the damage levels of indicators such as buildings, trees, and utility poles observed on-site, and referring to the Chinese national standard "Tornado Intensity Scale," the team rated the tornado as EF3 (with wind speeds approximately 61-73 m/s).

In the more severely affected areas (Main Survey Lines 2 and 3), numerous light-steel industrial buildings suffered severe damage to their metal roofing systems. Analysis of 431 building sites revealed that 18.33% experienced severe damage, including collapsed rigid frames and exterior walls. Common metal roof failure modes included localized tearing at self-drilling screw connections and connector pull-out from purlins.

Based on these findings, the team proposed wind-resistant design improvements such as optimizing ridge/eave geometry, increasing connector density, and using standing seam roof systems.

The study also employed the Weather Research and Forecasting (WRF) model to simulate the event. The KF-Eta scheme effectively reproduced the environmental conditions, successfully simulating parent storm characteristics like the "hook echo" signature, storm trajectory, and helicity patterns consistent with observational data. Additionally, by back-calculating the load capacity of two collapsed concrete utility poles, the research estimated peak gust wind speeds during the tornado at 74.59 m/s and 79.77 m/s.

###

Contact the author: Yi Yang, State Key Laboratory of Subtropical Building and Urban Science, South China University of Technology, Guangzhou, Guangdong, China, ctyangyi@scut.edu.cn

The publisher KeAi was established by Elsevier and China Science Publishing & Media Ltd to unfold quality research globally. In 2013, our focus shifted to open access publishing. We now proudly publish more than 200 world-class, open access, English language journals, spanning all scientific disciplines. Many of these are titles we publish in partnership with prestigious societies and academic institutions, such as the National Natural Science Foundation of China (NSFC).

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Journal

Advances in Wind Engineering

DOI

10.1016/j.awe.2025.100098 

Method of Research

Survey

Subject of Research

Not applicable

Article Title

Post-disaster investigation and WRF model reconstruction of April 27th tornado in Guangzhou based on muti-source data fusion

'Indian Niño' drove record heat in 2023 and 2024, new UMD study finds

It’s the first time this Indian Ocean climate pattern has been connected to the recent years’ unusually high temperatures.

University of Maryland

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In 2023 and 2024, Earth’s average global surface temperature spiked nearly 0.3 degrees Celsius above what was already expected from climate change. Each year was declared the hottest on record and coincided with deadly wildfires, heat waves and historic numbers of climate-related disasters. 

Scientists have struggled to explain what caused these anomalously warm years. In a new study, published May 6, 2026, in the journal Earth System Dynamics, University of Maryland researchers propose a novel answer: They attribute part of the temperature surge to the Indian Ocean Dipole (IOD), a climate cycle similar to El Niño. It’s the first time the IOD has been linked to these two unusually hot years.

The researchers built a climate model that predicts global temperatures based on an extensive list of natural and manmade factors. The variables they considered could explain 93% of the global surface temperature anomaly in 2023 and 92% in 2024—the closest scientists have gotten to explaining the record-breaking heat. The IOD was among the most important predictors. When the researchers omitted the IOD from the model, they could only account for 69% of the temperature spike in 2023 and 77% in 2024. The authors say that understanding how such natural factors influence global temperatures will help global decision-makers isolate and potentially mitigate the climate impact of human activity. 

“This is probably the most comprehensive attribution that’s out there right now,” said study lead author Endre Farago, who conducted this research as part of his chemistry Ph.D. research at UMD. “Being able to explain 92% to 93% of the anomaly—that’s basically spot on.”

The IOD, sometimes called “Indian Niňo,” refers to the difference in sea surface temperatures in the Indian Ocean’s western and eastern sides. Depending on the year, the western side can be warmer or cooler than the eastern side by varying degrees. This temperature gradient affects everything from rainfall patterns in India to bushfires in Australia.  

The IOD was only discovered in the late 1990s and is still not fully understood. Until the 2010s, scientists debated whether it was an independent cycle or a consequence of the more well-known El Niño Southern Oscillation (ENSO) in the Pacific Ocean. And because the Indian Ocean is the smallest of the three major ocean basins, many people didn’t think it could strongly affect the global climate, said study co-author and Atmospheric and Oceanic Science Professor Ross Salawitch. 

“There was a view in the climate community that the Pacific Ocean was the dog, and the Indian Ocean was the tail,” said Salawitch, who also holds joint appointments in the Department of Chemistry and Biochemistry and the Earth System Science Interdisciplinary Center. 

Even Salawitch was skeptical when Farago, his former graduate student who is now a postdoctoral researcher at Cornell University, first told him about the IOD result. But Salawitch was convinced by the regional patterns of warming in South America and southern Australia in 2023 that were uniquely associated with the IOD, and how much worse the model performed when they removed this climate cycle from consideration. 

Farago was impressed that the model could explain nearly all of the temperature anomaly in 2023 and 2024. Leading atmospheric scientists had been racing to identify the causes. But those studies, including one by the World Meteorological Organization, didn’t include the IOD and could not fully explain the temperature spike—especially in 2023, which was one of the two most extreme IOD events since modern recordings began around 1850.

In addition to the IOD, the research team estimated contributions from other natural cycles, including the other two major ocean basins: high sea surface temperatures in the North Atlantic and an ENSO event in the Pacific. The IOD affected global temperatures almost as much as ENSO in 2023 and nearly half as much in 2024. 

Although natural climate cycles partly explained the hot temperatures, the researchers emphasize that human activity was a key factor as well. The new study found that in 2023 and 2024, anthropogenic greenhouse gas emissions increased temperatures by about 0.022 degrees Celsius per year—an acceleration compared with the late 20th century.

Additionally, recent efforts to clean up the shipping industry affected temperatures in subtle but noticeable ways. To improve public health, the International Maritime Organization implemented a regulation in 2020 that limited the allowable amount of sulfur in ship fuel. The new rule reduced toxic sulfur oxide emissions. Although these pollutants are unhealthy to breathe, they reflect solar radiation away from Earth, so reducing their presence in the atmosphere unintentionally allowed more radiation to heat the planet. In 2023 and 2024, that caused heating equivalent to up to 25% to 30% of that caused by the recent rise in greenhouse gases, per the new study. It’s also possible that these maritime regulations contributed significantly to the unusually warm conditions in the North Atlantic in 2023 and 2024, which were also a major driver of the record global surface temperatures, the study states.

Although the extent of the temperature anomaly (0.3 degrees Celsius) seems small, it is meaningful. It represents about 20% of the roughly 1.5 degrees Celsius Earth has warmed since 1850 and manifests as prolonged heat waves, stronger precipitation and other climate extremes that harm people and the economy, Farago said. He says it’s crucial to understand the natural and manmade factors that lead to such drastic temperature swings.

Thus, Salawitch hopes that other researchers will include the IOD in their climate models moving forward. 

“After our paper comes out, colleagues will have serious conversations about whether they should include IOD in future global warming attribution studies. It's our hope that they'll find some importance and truth—some veritas—to what we did and what we found,” Salawitch said. “Doing so will hopefully lead to better quantification of the various natural and human factors that drive global warming, with meaningful implications for future policies to address climate change.” 

###

UMD AOSC graduate student Brian Bennett and Associate Professor Timothy Canty co-authored this article with McLane and Dodson.

The paper, “Quantification of the influence of anthropogenic and natural factors on the record-high temperatures in 2023 and 2024,” was published in Earth System Dynamics on May 6, 2026.

This research was supported by the NASA Climate Indicators and Data Products for Future National Climate Assessments program. This article does not necessarily reflect the views of this organization.

---

Journal

Earth System Dynamics

Method of Research

Computational simulation/modeling

Subject of Research

Not applicable

Article Title

Quantification of the influence of anthropogenic and natural factors on the record-high temperatures in 2023 and 2024

Article Publication Date

6-May-2026

 

Dangerous droughts triggered by heatwaves are accelerating at an alarming rate, study shows

Copyright AP Photo/Emilio Morenatti, File

By Seth Borenstein with AP

Published on 09/03/2026 

Heatwaves, drought, wildfire risk and El Niño are compounding to create a dangerous cocktail of climate change.

Heatwaves that lead to sudden and damaging drought are spreading across the globe at an accelerating rate, highlighting how climate change-fuelled extremes can build dangerously off each other, a new study found.

Researchers from South Korea and Australia looked at compound extreme weather – a one-two punch of heat and drought – and found it increasing as the world warms. But what's rising especially fast is the more damaging type when the heat comes first and that triggers the drought.

In the 1980s, that kind of extreme covered only about 2.5 per cent of Earth's land each year. By 2023, the last year the researchers studied, it was up to 16.7 per cent, with a 10-year average of 7.9 per cent.

The average has likely gone even higher with 2024's record global heat and a 2025 that was nearly as warm, the study's authors said.

Relate

Extreme heat followed by drought is rising at an alarming pace

In their study published in Science Advances on 6 March, the scientists said the quickening rate of change is even more concerning than the raw numbers. For about the first two decades since 1980 they examined, the spread of heat-first extremes increased, but the rate in the last 22 years is eight times higher than the earlier rate, the study found.

Events where drought happens first, followed by high heat, remain more common and are also rising. But the researchers focused on those increasing cases where heat struck first. That's because when heat strikes first, the droughts are stronger than when the droughts come first or don't come with high heat, says co-author Sang-Wook Yeh, a climate scientist at Hanyang University in South Korea.

They also lead to 'flash droughts', which are more damaging than ordinary droughts because they come on suddenly, not allowing people and farmers to prepare, says lead author Yong-Jun Kim, a Hanyang climate scientist.

Flash droughts – when warmer air gets thirstier it sucks more water out of soil – have been increasing in a warming world, past studies show.

A resident of a riverside community carries food and containers of drinking water during a drought in Careiro da Varzea, Amazonas state, Brazil, Oct. 24, 2023. AP Photo /Edmar Barros, File

Climate change is driving 'compound extremes'

“The study illustrates a key point about climate change: the most damaging impacts often come from compound extremes. When heatwaves, drought and wildfire risk occur together – as we saw in events like the Russian heatwave of 2010 or the Australian bushfires in 2019-20 – the impacts can escalate quickly,” says Andrew Weaver, a climate scientist at the University of Victoria in British Columbia, Canada

“What this study shows is that warming doesn’t just make heatwaves more likely – it changes how heat and drought interact, amplifying the risks we face."

Weaver was not part of the study, but he lives in the Pacific Northwest, where the 2021 heat dome and drought was what Kim calls a top example of what they see rapidly increasing. Others include the 2022 heat and drought around China's Yangtze River and the 2023-24 record heat and drought in the Amazon, Kim says.

“The 2021 Pacific Northwest heat dome illustrates how quickly these compound extremes can escalate – temperatures near 50°C in Lytton (British Columbia) were followed by rapid drying and extreme wildfire conditions that destroyed the community,” Weaver, a former Canadian legislator, says.

Related

Where is most at risk of heat-first droughts?

The study found the biggest increases in heat-first droughts in South America, western Canada, Alaska and the western United States, and parts of central and eastern Africa.

Kim and Yeh say they noticed a “change point” around the year 2000, when everything sped up for heat-then-drought situations.

Jennifer Francis, a Woodwell Climate Research Center climate scientist who wasn’t part of the study, says that change point was “eerily coincident with the onset of rapid Arctic warming, sea-ice loss, and decline in spring snow cover on Northern Hemisphere continents.”

In addition to long-term warming causing more compound extremes, Kim says they saw a speeding-up in the way heat went from land to air and back again just before that 2000 change point. He and Yeh speculate that Earth may have crossed a “tipping point" where the change is irreversible.

Several aspects of Earth's climate and ecological systems changed in the late 1990s, with a possible trigger by a major El Niño event in 1997-98, says Gerald Meehl, a climate scientist at the National Center for Atmospheric Research who wasn't part of the study. But he adds that it's hard to tell whether they are permanent changes.

Some computer models forecast another major El Nino – a natural warming of parts of the Pacific that warp weather worldwide – brewing later this year.