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Congratulations to SKL-CRCC Members – 2026 FCE Dean’s Award for Outstanding Achievement in Research Funding (English Only)

We would like to extend our heartfelt congratulations to our SKL-CRCC members who have been awarded the 2026 FCE Dean’s Award for Outstanding Achievement in Research Funding by the Faculty of Construction and Environment (FCE), The Hong Kong Polytechnic University. Award recipients include: Prof. You DONG Prof. Yi-Qing NI Prof. Zhenyu YIN Prof. Tao YU Prof. Shipeng ZHANG This prestigious recognition highlights their valuable contributions and outstanding achievements in securing external competitive research funding. Their success reflects not only their dedication and perseverance, but also their commitment to driving technological innovation and advancing research excellence in civil and environmental engineering. Congratulations again to all award recipients. We look forward to their continued breakthrough research and the impactful outcomes it will bring to the community. Find the complete list of projects in the below link: https://www.polyu.edu.hk/fce/eBulletin/public/issue187/Dean's%20Award%20for%20Outstanding%20Achievement%20in%20Research%20Funding%202026_updated.pdf  

PolyU research reveals snow droughts continue to threaten global food security and calls for climate-resilient agriculture practices to promote sustainable development

Global climate change is reshaping agricultural ecosystems. As warmer winters become more prevalent, snow droughts caused by insufficient snowfall are becoming more frequent. This leaves winter wheat, which relies on snow cover for insulation and water supply, vulnerable to low-temperature frost damage and water stress, posing a major threat to global food security. A research team from The Hong Kong Polytechnic University (PolyU) has utilised innovative explainable machine learning to uncover the persistent and significant negative impact of snow droughts on winter wheat yields, highlighting that global food security is facing unprecedented challenges. This breakthrough study provides key scientific evidence for building climate-resilient agriculture, ensuring food security and promoting sustainable development. Led by Prof. Shuo WANG, Associate Professor of the PolyU Department of Land Surveying and Geo-Informatics, a core member of the Research Institute for Land and Space, and a member of the State Key Laboratory of Climate Resilience for Coastal Cities, the study was conducted in collaboration with scholars from the University of Hong Kong and the University of California, Irvine. The findings have been published in the international journal Nature Food. Over the past 60 years, the frequency of snow droughts across the Northern Hemisphere’s winter wheat croplands has increased significantly. The proportion of croplands affected by snow drought surged from 46–54% in 1960–1970 to 70–99% in 2010–2020, reflecting the fact that snow droughts have evolved from a localised risk into a widespread phenomenon. The research team developed the XGB-SHAP model framework to accurately identify the direct impact of snow drought on crop yields. The framework combines Extreme Gradient Boosting (XGBoost) with Shapley Additive exPlanations (SHAP) to effectively exclude interference from other climate factors such as high temperature and rainfall, enabling a quantitative analysis of the direct impact of snow drought on winter wheat yields. This study also systematically analysed snow–crop–water interactions, providing a robust empirical basis for developing climate-resilient agricultural systems. Using the XGB-SHAP framework, the study found that approximately 45% of croplands in the Northern Hemisphere experienced significant adverse impacts from snow droughts, with Europe, Central Asia and the United States being the regions most severely affected. Meanwhile, in East Asia, the yield benefits of longer growing seasons due to warmer winters are gradually diminishing and the regional hydrothermal balance is becoming increasingly unstable. The study also identifies increased fertiliser use, intensified freezing stress and reduced precipitation as the three primary factors contributing to winter wheat’s increased sensitivity to snow drought. While enhanced soil nutrient levels can promote crop growth, they also make crops more dependent on the water supply and thermal insulation provided by snow cover. When snow drought occurs, these factors can amplify the risk of yield loss. Prof. Shuo WANG noted, “As global warming continues, climate risks are no longer limited to ‘acute stressors’ such as heatwaves, but also include gradually accumulating and far-reaching ‘chronic stressors’ such as snow droughts. As winter wheat is a major commodity in global agricultural trade, the effect of its yield variability can ripple through global trade networks, driving up food prices and potentially leading to regional food security crises.” Looking ahead, the research team recommends strengthening the climate resilience of agricultural systems by enhancing crop varieties, improving agricultural management and monitoring risks. Alongside intensifying efforts to develop crop varieties with both cold and drought tolerance, agricultural management models have to shift from traditional, input-intensive production to more precise and sustainable nutrient management systems. Furthermore, snow cover monitoring should be incorporated into agricultural risk assessment and early warning systems. Identifying snow drought risks at an early stage and enhancing the resilience of agricultural systems will ensure that stable food production is maintained in the face of climate change, steering global agriculture towards a more sustainable future.   Online coverage: PolyU research reveals snow droughts continue to threaten global food security and calls for climate-resilient agriculture practices to promote sustainable development | The Hong Kong Polytechnic University  

Prof. Xinyan HUANG Receives 2026 Hiroshi Tsuji Early Career Researcher Award from The Combustion Institute

We would like to offer our warmest congratulations to Prof. Xinyan HUANG, Associate Professor of the Department of Building Environment and Energy Engineering (BEEE), and also a valued member of SKL-CRCC, for receiving the 2026 Hiroshi Tsuji Early Career Researcher Award from The Combustion Institute. The Hiroshi Tsuji Early Career Researcher Award, established in 2016, recognizes outstanding achievements in fundamental or applied combustion science research. In 2026, three early career researchers worldwide were selected for this prestigious honour, including Prof. HUANG. Prof. HUANG earned his PhD from Imperial College London and completed postdoctoral training at the University of California, Berkeley. He has co-authored more than 200 journal papers across areas such as smoldering dynamics, wildland fire, microgravity combustion, battery safety, and AI-powered fire resilience. Prof. HUANG also serves as an Associate Editor of Proceedings of the Combustion Institute. Upon receiving the award, Prof. HUANG expressed his heartfelt gratitude to his mentors, colleagues, and collaborators, and dedicated the recognition to his current and past students and postdocs. SKL-CRCC congratulates Prof. HUANG on this remarkable international recognition. We celebrate his outstanding research contributions to combustion science, fire safety, and engineering innovation, and we look forward to his continued breakthroughs and impact. SKL-CRCC is proud to support and recognize our members’ academic excellence and international impact. We look forward to continuing our mission of fostering innovation, collaboration, and long-term research excellence in combustion science and related engineering fields. For more details about the award, please visit: https://members.combustioninstitute.org/news_archive_headlines.php?org_id=CMBI&sniid=53953423#53953423

Prof. Xinyan HUANG Receives the 2025 Outstanding Associate Editor Award from the International Journal of Wildland Fire (IJWF) (English Only)

We are delighted to announce that Prof. Xinyan HUANG, a valued member of SKL-CRCC, has been awarded the 2025 Outstanding Associate Editor Award by the International Journal of Wildland Fire (IJWF). This award recognizes Associate Editors who have demonstrated sustained excellence in responsiveness, thoroughness, and timeliness. Prof. HUANG has served as an Associate Editor of IJWF since 2021, contributing actively to the journal’s editorial work and supporting the advancement of international wildland fire research. On behalf of the SKL-CRCC community, we would like to express our sincere congratulations to Prof. HUANG on this well-deserved achievement. His recognition from IJWF is a testament to his commitment, expertise, and contribution to the international scientific community. We hope this inspiring milestone will encourage the SKL-CRCC community to continue pursuing high-impact research and international collaboration in the areas of environment, safety, and resilience—and to keep strengthening PolyU’s research influence on global challenges. For readers who would like further details about the award, please refer to the IJWF information page: https://connectsci.au/wf/article/35/4/WFv35n4_AW/272471/Outstanding-Associate-Editor-Award Online coverage: IJWF - Outstanding Associate Editor Award | International Journal of Wildland Fire | ConnectSci

Establishment of the Alliance of Key Laboratories for Climate and Environmental Science (ANKL-CES)

  On April 3, 2026, the Alliance of Key Laboratories for Climate and Environmental Science (ANKL-CES) was officially established at Nanjing University of Information Science and Technology (NUIST). Comprising 14 top-tier Chinese research platforms – including the State Key Laboratory of Climate System Prediction and Risk Management and State Key Laboratory of Climate Resilience for Coastal Cities – the Alliance aims to integrate China’s strategic scientific and technological resources to collaboratively address climate change and extreme disaster risks. The inaugural conference gathered distinguished experts and leaders, including Academician Professor Dai Yongjiu (Sun Yat-sen University), Professor Cai Yingfeng (Deputy Director of the Jiangsu Provincial Department of Science and Technology), Professor Song Xiangzhou (Vice President of Hohai University), and Professor Chen Haishan (President of NUIST). The conference elected Academician Professor Wang Huijun as Chairman of the Alliance Council. Professor Li Xiangdong (Director of the State Key Laboratory of Climate Resilience for Coastal Cities) and Professor Li Xiaoyan were appointed as Vice Chairmen. In his address, Chairman Wang Huijun noted that the Alliance marks a new era of collaborative innovation in China’s climate sector. He emphasized that the group would enhance the nation’s capacity to meet environmental challenges through interdisciplinary collaboration, resource sharing, and joint research initiatives. Professor Duan Huan-Feng, Associate Director of the State Key Laboratory of Climate Resilience for Coastal Cities, represented the laboratory and delivered a speech during the first Council meeting. He expressed full support for the Alliance’s mission, proposing the creation of an open, long-term, and pragmatic platform to facilitate academic and research exchanges. He suggested integrating the strengths of alliance members to advance joint scientific research projects, personnel exchanges, and the sharing of laboratory resources. Furthermore, Professor Duan highlighted the importance of talent cultivation, advocating for an “incubation–mobility–retention” mechanism. He also suggested leveraging Hong Kong’s regional advantages to expand international perspectives and strengthen global academic influence and collaboration. Looking ahead, the ANKL-CES will align with national strategic priorities and major needs, leveraging the collective strengths of key laboratories to tackle core technological challenges in climate, environment, and disaster prevention. By establishing an innovative mechanism which integrating government-industry-academia-research, the Alliance seeks to foster high-quality economic development and high-level ecological protection.

Enhancing Hong Kong’s Defence Against Extreme Weather Through Research and Innovation

  To align with the national “15th Five-Year Plan” and its strategic focus on strengthening responses to global climate change, the Development Bureau of the Hong Kong Special Administrative Region is actively advancing research-driven solutions. The Bureau is deepening collaboration with the State Key Laboratory of Climate Resilience for Coastal Cities (jointly established by The Hong Kong Polytechnic University and The Hong Kong University of Science and Technology). By combining Hong Kong’s practical experience as a high-density coastal city with the cutting-edge research capabilities of its world-class universities, the initiative aims to significantly bolster the city’s resilience against extreme weather events. Over the past two months, the Development Bureau and the Climate Change Working Group on Infrastructure held two productive exchange sessions with the State Key Laboratory: First Meeting  (24 February): Senior representatives from the Development Bureau, Civil Engineering and Development Department, Drainage Services Department, Architectural Services Department, and Hong Kong Observatory met with the Laboratory team to define key collaboration areas. These include urban infrastructure resilience, compound urban disasters, extreme rainfall mitigation using green strategies, flood and coastal management, and slope safety. Both parties agreed to establish a robust information-sharing platform and schedule regular meetings to accelerate the translation of research into real-world applications. Special Seminar on Flood and Coastal Management (18 March): Experts from the Pearl River Water Resources Research Institute, South China University of Technology, and China Water Resources Pearl River Planning Surveying & Designing Co., Ltd. joined the discussion. Participants exchanged insights on smart flood prediction and early warning systems, artificial intelligence models, and digital twin technologies for coastal cities in Hong Kong and the Greater Bay Area. The Development Bureau will continue to foster close partnerships with the State Key Laboratory and research institutions in Hong Kong and mainland China, fully leveraging Hong Kong’s cross-university strengths to drive technological innovation and enhance infrastructure resilience for Hong Kong, the nation, and coastal cities globally.   Online coverage: Development Bureau - https://www.facebook.com/share/p/1CLkSd9B1E/

Prof. Jianli CHEN Named Winner of PolyU “Top 10 Research & Innovation Stories of the Year”

We are pleased to announce that Prof. Jianli CHEN, a valued member of SKL-CRCC, has been named one of the winners of the inaugural “PolyU Top 10 Research & Innovation Stories of the Year”. This university-wide selection and voting campaign was launched to recognise outstanding achievements with far-reaching impact both locally and globally. Through a combination of professional judging and public voting (with more than 7,700 votes), ten awardees were chosen from 20 finalists announced in 2025 across five strategic areas. Prof. CHEN leads a pioneering global research effort that uses satellite positioning data to track Greenland ice sheet melt behaviour and evaluate its impact on sea-level rise. By integrating modern space geodetic techniques, his team monitors vertical bedrock subsidence and quantifies summer water storage, providing valuable insights into how ice sheets respond to global environmental change. Please join us in offering our warmest congratulations to Prof. CHEN for this well-deserved recognition. We look forward to his continued contributions and the positive impact his research will bring to society and international science.   Press release: English - https://polyu.me/4s8plYJ; Chinese - https://polyu.me/3PUjoky   Online coverage: Headline Daily - https://polyu.me/4mFztqQ Headline Daily - https://polyu.me/414Ttcw Ta Kung Pao - https://polyu.me/4dmCKbP Bauhinia - https://polyu.me/4m1vfcL Mirage - https://polyu.me/4tiNeh2

Research of Prof. Yi-Qing Ni’s Team Published on Nature Communications

A recent study by Prof. Yi-Qing Ni, Chair Professor of CEE and member of the State Key Laboratory of Climate Resilience for Coastal Cities, and his team has been published in Nature Communications. The article, titled “Tropical Cyclone Rainfall Extends Inland”, explores the global landward extension of tropical cyclone rainfall and its implications for inland flood risk. The study demonstrates that tropical cyclone rainfall has extended inland globally from 1980 to 2023. Along the continental coasts of the Northern Hemisphere, the landward extent of tropical cyclone heavy rainfall has increased at a rate of 3.8 ± 1.8 km per decade (95% CI). Observations and model simulations suggest that nearshore sea-surface temperature warming is closely linked to this extension. Coastal urbanization may further enhance this trend. As coastal cities continue to extend inland, the landward extension of tropical cyclone heavy rainfall could exacerbate inland population exposure and potential flood risk. Nature Communications is an open access, multidisciplinary journal dedicated to publishing high-quality research in all areas of the biological, health, physical, chemical, Earth, social, mathematical, applied, and engineering sciences. Papers published by the journal aim to represent important advances of significance to specialists within each field. This research is supported by the Research Grants Council Theme-based Research Scheme (Grant No. T22-501/23-R). Review the full article: https://www.nature.com/articles/s41467-026-70647-1

SKL-CRCC Receives Multiple Accolades at the 51st International Exhibition of Inventions in Geneva

The Hong Kong Polytechnic University (PolyU) has been awarded 37 accolades at the 51st International Exhibition of Inventions Geneva, held from 11 to 15 March 2026. This international event brings together innovators and research teams from around the world to showcase cutting-edge ideas, technological breakthroughs, and practical solutions with global impact. Among PolyU’s impressive results, SKL-CRCC members secured two of the awards, reflecting the strength of their research capability and the value of their innovations. Their recognition highlights not only their technical excellence, but also their dedication to translating knowledge into meaningful outcomes for society, industry, and future development. We extend our warmest congratulations to all awardees, and in particular to the SKL-CRCC award recipients, for their outstanding performance and achievements. Their success serves as an inspiration to the wider research community and reinforces the importance of continued innovation and collaboration. Award  Principal Investigator(s)  Project  Gold Medal Prof Zhu Songye Interim Head and Professor of the Department of Civil and Environmental Engineering & Associate Director of State Key Laboratory of Climate Resilience for Coastal Cities Latching-based Smart Control System for Mitigating Ultra-low-frequency Vibrations: Inspired by Wave Energy Converters Silver Medal Prof Leng Zhen Professor of the Department of Civil and Environmental Engineering. Nanocarbon-coated Conductive Aggregates (NCCA) for Smart, Sustainable Asphalt Pavement   Press release: English - https://polyu.hk/rQulx ; Chinese - https://polyu.hk/fEVzk

PolyU research finds frequent Arctic wildfires could cut snow cover by 18 days, impacting global climate and ecology

The correlation between Arctic wildfires and abnormal snow cover under global warming is of growing concern. A comprehensive quantitative assessment by researchers at The Hong Kong Polytechnic University (PolyU) has shown that increasingly frequent seasonal wildland fires across the Arctic in recent years have delayed snow cover formation by at least five days and could lead to a future 18-day reduction of snow cover duration, with implications for global ecosystems. Against the backdrop of the United Nation’s “Decade of Action for Cryospheric Sciences”, this study not only underscores the urgency of addressing climate change, but also provides critical scientific evidence to inform global climate adaptation strategies. Snow cover in the Arctic plays a key role in the global climate system. It reflects solar radiation back into space thus keeping the surface cool, while its meltwater is an important source of freshwater. Snow is therefore central to the planet’s energy balance, hydrological cycles and weather patterns. Anomalies such as delayed snow formation or earlier melt can intensify warming, affect water supplies, and reduce forest ecosystem productivity and carbon sequestration beyond the Arctic, ultimately disrupting global ecosystems and biodiversity. Led by Prof. Shuo WANG, Associate Professor of the PolyU Department of Land Surveying and Geo-Informatics, a core member of the Research Institute for Land and Space, and a member of the State Key Laboratory of Climate Resilience for Coastal Cities, the study is conducted in collaboration with international researchers from the University of California, Irvine, and Columbia University. The findings have been published in the international journal Nature Climate Change. Prof. Wang elaborated, “Global warming has intensified Arctic wildland fires, making such fires increasingly frequent, larger in scale and in some cases more intense. In 2023, Canada experienced record-breaking fires, with over 45 million acres burned - nearly 10 times the average annual burned area over the past 40 years. This research aims to quantify the links among wildfires, snow formation and snow cover duration, thereby advancing our understanding of land-atmosphere interactions under climate change.” The research team compiled long-term satellite remote sensing data of the burned area together with the start day and end day of snow cover in the Arctic from 1982 to 2018. They integrated these data with an artificial intelligence model built on the state-of-the-art XGBoost machine learning algorithms, incorporating a range of climate factors before, during and after fires (such as albedo, surface temperature and air temperature), as well as fire location, to evaluate the influence of these variables on snow cover. The satellite data indicated that as burned area in the Arctic increased, the duration of snow cover decreased. Between 2001 and 2018, the average snow cover lasted 205 days, 10 days shorter than that from 1982 to 2000. The team further utilised the CMIP6 climate model projections to simulate future changes in Arctic wildfires and snow under different emission scenarios. They discovered that, under the high-emission scenario SSP5-8.5, the annual burned area of the Arctic could expand by 2.6 times by year 2100, while snow duration may shrink to about 130 days — approximately 18 days shorter than the historical average from 1950 to 2014. The study also found that major wildland fires significantly delay the formation of snow cover. Through regional impact analysis, the team determined that in the first year following a major wildfire, the snow start date is postponed by more than five days compared with the three-year average prior to the fire; moreover, the larger the burned area, the longer the delay. The research team identified the underlying physical mechanism as the deposition and persistenceof black carbon on the ground after fires, which reduces surface albedo and enhances the absorption of solar radiation. This additional energy increases both land surface temperature and near-surface air temperature, thereby suppressing effective snow accumulation and ultimately postponing snow formation.  “Wildland fires alter surface properties in the Arctic and subsequently shorten the duration of regional snow cover,” Prof. Wang added. “The reduction of snow coverfurther disrupts surface energy balance, prolongs land exposure, and leads to warmer, drier surfaces, which create favourable conditions for an earlier start and broader spread of fires. Such a feedback loop underscores the vulnerability of Arctic ecosystems to cascading climate impacts.” The research team envisions these findings will not only provide solid evidence for predicting the future hydrological cycle and climate dynamics of the Arctic, but also offer scientific guidance for assessing ecosystem resilience and formulating effective climate adaptation strategies to help mitigate the chain effect of climate change.   Press release: English - https://polyu.me/4bp74Bz; Chinese - https://polyu.me/4qaGFvM   Online coverage: Mirage - https://polyu.me/4jCiB2M PhysOrg- https://bit.ly/4bpAa3M Bastille Post - https://polyu.me/4blfeLd Dot Dot News - https://polyu.me/4qKcBr0