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1. Global Future Drought Layers Based on Downscaled CMIP6 Models and Multiple Socioeconomic Pathways

   https://doi.org/10.1038/s41597-025-04612-w  

   Araujo, Diogo_S_A; Enquist, Brian_J; Frazier, Amy_E; Merow, Cory; Roehrdanz, Patrick_R; Moulatlet, Gabriel_M; Zvoleff, Alex; Song, Lei; Maitner, Brian; Nikolopoulos, Efthymios_I (February 2025, Scientific Data)

   Abstract Droughts are a natural hazard of growing concern as they are projected to increase in frequency and severity for many regions of the world. The identification of droughts and their future characteristics is essential to building an understanding of the geography and magnitude of potential drought change trajectories, which in turn is critical information to manage drought resilience across multiple sectors and disciplines. Adding to this effort, we developed a dataset of global historical and projected future drought indices over the 1980–2100 period based on downscaled CMIP6 models across multiple shared socioeconomic pathways (SSP). The dataset is composed of two indices: the Standardized Precipitation Index (SPI) and Standardized Precipitation Evapotranspiration Index (SPEI) for 23 downscaled global climate models (GCMs) (0.25-degree resolution), including historical (1980–2014) and future projections (2015–2100) under four climate scenarios: SSP1-2.6, SSP2-4.5, SSP3-7.0, and SSP5-8.5. The drought indices were calculated for 3-, 6- and 12-month accumulation timescales and are available as gridded spatial datasets in a regular latitude-longitude format at monthly time resolution. 

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2. Global 0.25-Degree Future Drought Layers (1980-2100) Based on Downscaled CMIP6 Models and SSP-RCP Combinations, Version 1

   https://doi.org/10.7927/4es0-1v73  

   Araujo, DSA; Nikolopoulos, EI (January 2024, Palisades, NY: Socioeconomic Data and Applications Center (SEDAC))

   Droughts are a natural phenomenon with significant impact on society and the environment. Their frequency and severity are projected to increase toward the end of the century, which makes urgent the analysis of future drought characteristics to inform stakeholders and to allow the investigation of their effects on different domains. In this study, we developed Future Global Drought Layers composed of SPI and SPEI indices for 23 GCMs of the NEX-GDDP-CMIP6 dataset, including historical (1980-2014) data and 4 future projections (2015-2100) under four climate scenarios: SSP1-2.6, SSP2-4.5, SSP3-7.0, and SSP5-8.5. The drought indices were calculated for 3-, 6- and 12-month timescales. The data is gridded in a regular latitude-longitude format, with a spatial resolution of 0.25º (~25 km) and monthly time resolution. 

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3. Assessing Future Coastal Flood Hazards From Tropical Cyclones in the Northeastern United States

   https://doi.org/10.1029/2025EF006063  

   Begmohammadi, Amirhosein; Lin, Ning; Xi, Dazhi; Blackshaw, Christine (November 2025, Earth's Future)

   Coastal flooding from tropical cyclone (TC)‐induced storm surges is among the most devastating natural hazards in the US. Accurately quantifying storm surge hazards is crucial for risk mitigation and climate adaptation. In this study, we conduct climatology‐hydrodynamic modeling to estimate TC surge hazards along the US northeast coastline under future climate scenarios. In this methodology, we generate synthetic TCs for the northeastern US to drive a hydrodynamic model (ADCIRC) to simulate storm surges. Observing their significant effect on storm surge, for the first time, we bias‐correct landfall angles of synthetic TCs, in addition to bias‐correcting their frequency and intensity. Our findings show that under the combined effects of sea level rise (SLR) and TC climatology change, historical 100‐year extreme water levels (EWLs) along the US northeast coastline would occur annually at the end of the century in both SSP2‐4.5 and SSP5‐8.5 emissions scenarios. 500‐year EWLs are also projected to occur every 1–60 (1–20) years under SSP2‐4.5 (SSP5‐8.5). SLR is the dominant factor in the dramatic changes in the EWLs. However, while in higher latitudes () TC climatology change modestly affect EWLs ( contribution for 100‐year and for 500‐year EWL changes), in lower latitudes the impact is more significant (up to 40% contribution to 100‐year and 55% for 500‐year EWL changes). Extending previous methods, the physics‐based probabilistic framework presented here can be applied to project future coastal flood hazards under the effects of SLR and storm climatology change for any TC‐prone region. 

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4. A Novel Framework to Project the Permafrost Fate With Explicit Quantification of Soil Property and Future Climate Uncertainties

   https://doi.org/10.1029/2024JF008168  

   Zhou, Wenbo; Zhang, Liujing; Sheshukov, Aleksey; Wang, Jingfeng; Zhu, Modi; Sargsyan, Khachik; Xu, Donghui; Liu, Desheng; Zhang, Tianqi; Mazepa, Valeriy; et al (October 2025, Journal of Geophysical Research: Earth Surface)

   Abstract This study develops a novel general framework to project the permafrost fate with rigorous uncertainty quantification to assess dominant sources. Borehole temperature records from three sites in the Russian western Arctic are used to constrain the uncertainty of a high‐fidelity freeze‐thaw model. Projections from 9 Global Climate Models (GCM) are stochastically downscaled to generate future trajectories of surface ground heat flux. Under the two emission scenarios SSP2‐4.5 and SSP5‐8.5, the projected average thawing depths by 2100 vary from 0.4 to 14.4 m or 2.1 to 17.7 m, and the increase in the top 10 m average temperature from 2015 to 2100 is 1.2–2.7°C or 1.9–3.0°C. The results show that the freeze‐thaw model uncertainty can sometimes dominate over that of GCM outputs, calling for site‐specific information to improve model accuracy. The framework is applicable for understanding permafrost degradation and related uncertainties at larger scales. 

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5. Intensified Positive Arctic–Methane Feedback under IPCC Climate Scenarios in the 21st Century

   https://doi.org/10.34133/ehs.0185  

   Wang, Yihui; He, Liyuan; Liu, Jianzhao; Arndt, Kyle A; Mazza_Rodrigues, Jorge L; Zona, Donatella; Lipson, David A; Oechel, Walter C; Ricciuto, Daniel M; Wullschleger, Stan D; et al (April 2024, Ecosystem Health and Sustainability)

   The positive Arctic–methane (CH₄) feedback forms when more CH₄is released from the Arctic tundra to warm the climate, further stimulating the Arctic to emit CH₄. This study utilized the CLM-Microbe model to project CH₄emissions across five distinct Arctic tundra ecosystems on the Alaska North Slope, considering three Shared Socioeconomic Pathway (SSP) scenarios using climate data from three climate models from 2016 to 2100. Employing a hyper-resolution of 5 m × 5 m within 40,000 m²domains accounted for the Arctic tundra’s high spatial heterogeneity; three sites were near Utqiaġvik (US-Beo, US-Bes, and US-Brw), with one each in Atqasuk (US-Atq) and Ivotuk (US-Ivo). Simulated CH₄emissions substantially increased by a factor of 5.3 to 7.5 under the SSP5–8.5 scenario compared to the SSP1–2.6 and SSP2–4.5 scenarios. The projected CH₄emissions exhibited a stronger response to rising temperature under the SSP5–8.5 scenario than under the SSP1–2.6 and SSP2–4.5 scenarios, primarily due to strong temperature dependence and the enhanced precipitation-induced expansion of anoxic conditions that promoted methanogenesis. The CH₄transport via ebullition and plant-mediated transport is projected to increase under all three SSP scenarios, and ebullition dominated CH₄transport by 2100 across five sites. Projected CH₄emissions varied in temperature sensitivity, with a Q₁₀range of 2.7 to 60.9 under SSP1–2.6, 3.8 to 17.6 under SSP2–4.5, and 5.7 to 17.2 under SSP5–8.5. Compared with the other three sites, US-Atq and US-Ivo were estimated to have greater increases in CH₄emissions due to warmer temperatures and higher precipitation. The fact that warmer sites and warmer climate scenarios had higher CH₄emissions suggests an intensified positive Arctic–CH₄feedback in the 21st century. Microbial physiology and substrate availability dominated the enhanced CH₄production. The simulated intensified positive feedback underscores the urgent need for a more mechanistic understanding of CH₄dynamics and the development of strategies to mitigate CH₄across the Arctic. 

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