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Publication date: 15 January 2026

Source: Advances in Space Research, Volume 77, Issue 2

Author(s): Soraya Makhlouf, Mourad Djebli

Publication date: 15 January 2026

Source: Advances in Space Research, Volume 77, Issue 2

Author(s): Bin Chen, Xiaodong Shao, Haoyang Yang, Dongyu Li, Qinglei Hu

Publication date: 15 January 2026

Source: Advances in Space Research, Volume 77, Issue 2

Author(s): Wojciech Jarmołowski, Paweł Wielgosz, Anna Krypiak-Gregorczyk, Beata Milanowska

Publication date: 15 January 2026

Source: Advances in Space Research, Volume 77, Issue 2

Author(s): Yiding Li, Gang Zhang

Publication date: 15 January 2026

Source: Advances in Space Research, Volume 77, Issue 2

Author(s): Nitish Kumar, V.S. Rathore, Ajeet Kumar, Akhouri Pramod Krishna, Raja Biswas, Anup Kumar Das

Publication date: 15 January 2026

Source: Advances in Space Research, Volume 77, Issue 2

Author(s): Lihao Yin, Mingyuan Zhang, Qianyi Ren, Wenbin Gong, Richang Dong

Publication date: 15 January 2026

Source: Advances in Space Research, Volume 77, Issue 2

Author(s): Xiaohui Chen, Alireza Arabameri, M. Santosh, Hasan Raja Naqvi, Mohd Ramiz

Publication date: 15 January 2026

Source: Advances in Space Research, Volume 77, Issue 2

Author(s): Junye Zhu, Yutong Liu, Kefan Xu, Yangshu Lin, Keqi Wang, Zhiming Lin, Qiwen Jin, Chao Yang, Lijie Wang, Chenghang Zheng, Yongxin Zhang, Xuecheng Wu

Publication date: 15 January 2026

Source: Advances in Space Research, Volume 77, Issue 2

Author(s): Yu Guo, Ming Ma, Jing Peng, Hang Gong, Xin Yang, Gang Ou

Publication date: 15 January 2026

Source: Advances in Space Research, Volume 77, Issue 2

Author(s): Wei Xi, Xi-Ming Zhu, Lu Wang

Publication date: 15 January 2026

Source: Advances in Space Research, Volume 77, Issue 2

Author(s): Jiaqi Li, Lei Yang, Lizeng Gong, Zhenglong Yin, Quan Chen

Publication date: 15 January 2026

Source: Advances in Space Research, Volume 77, Issue 2

Author(s): Songhua Hu, Jingshi Tang

Publication date: 15 January 2026

Source: Advances in Space Research, Volume 77, Issue 2

Author(s): Xiangru Bai, Haibo Song, Caizhi Fan

Publication date: 15 January 2026

Source: Advances in Space Research, Volume 77, Issue 2

Author(s): Zhaoyu Li, Tianyou Li, Hao Zeng, Rui Xu

Publication date: 1 January 2026

Source: Advances in Space Research, Volume 77, Issue 1

Author(s): Chih-Ming Lin, I-Ching Yang

Publication date: 1 January 2026

Source: Advances in Space Research, Volume 77, Issue 1

Author(s): K.S. Paul, H. Haralambous, M. Moses, S.K. Panda

The Landslide Blog is written by Dave Petley, who is widely recognized as a world leader in the study and management of landslides.

Of course, allow me to start by wishing all my readers a Happy 2026. I suspect that we are in for quite a landslide journey again this year.

In late November, a very interesting open access paper (Darrow and Jacobs 2025) was published on the journal Landslides. This piece of work sought to understand the patterns of landslides in Alaska over a century through the creation of a database compiled from “a combination of 24 digital newspapers and online media sources, including historic digitised Alaskan newspapers”. Such a study is an epic amount of work, but yields fantastic data. This study is no exception.

What is of particular interest here is that Alaska suffers from a range of landslide hazards, and suffers significant losses from them, and it is an environment in which climate change is clearly occurring, with warming at a rate that is higher than the global average. Previous studies have shown that this is having a measurable impact on landslides in the mountains of Alaska.

In total, Darrow and Jacobs (2025) have identified 281 landslides since 1883 in Alaska, with the occurrence showing a strong seasonal pattern associated primarily with seasonal patterns of rainfall. The headline from the paper is summarised in this graphic from the paper:-

The recorded incidence of landslides in Alaska by decade, from Darrow and Jacobs (2025).

The data shows a dramatic increase in landslides in recent decades, and in particular in the last two decades or so. Of course, care is needed to ensure that this is not an artefact of the reporting of landslides, but Darrow and Jacobs (2025) explored this issue in detail, concluding that the signal is real. Fortunately, the number of fatalities caused by landslides in Alaska is small, and there is no significant trend in terms of fatal landslides.

So what lies behind this change? Darrow and Jacobs (2025) show that the increase in occurrence of landslides in Alaska is associated with a marked increase in in average annual air temperature that ranges between 1.2 C and 3.4 C, and an associated increase in precipitation that ranges from 3% to 27%, over the 50 years.

Of course, warming is not going to stop in Alaska in the next few decades, so the likely direction of travel in terms of landslides there is clear. There is recognition in Alaska that greater attention will be needed on landslides.

But more widely, this is further quantitative evidence that the climate is having a big impact on landslide hazard. It is remarkable how the evidence just keeps accumulating.

Reference

Darrow, M.M. and Jacobs, A. 2025. Read all about it! A review of more than a century of Alaskan landslides as recorded in periodicals. Landslides. https://doi.org/10.1007/s10346-025-02663-z.

Return to The Landslide Blog homepage Text © 2026. The authors. CC BY-NC-ND 3.0
Except where otherwise noted, images are subject to copyright. Any reuse without express permission from the copyright owner is prohibited.

Source: AGU Advances

In 2023, Earth experienced its warmest year since 1850, with heat waves stretching across oceans and land alike. East Asia, for example, experienced scorching temperatures and high humidity throughout the summer months. Humid-heat extremes like those seen that year can trigger heat-related illnesses and mortality at higher-than-average rates.

As on land, the ocean around East Asia also experienced unprecedented warming in 2023. Sea surface temperatures (SST) in the Kuroshio-Oyashio Extension region reached record highs, persisting through much of the year. Researchers know that marine heat waves can influence land heat waves, but the details of these connections remain unclear.

Okajima et al. modeled regional land-sea interactions to better understand the effects of the unprecedented 2023 marine heat wave on conditions on land in East Asia. The team focused on the peak hot and humid months of July, August, and September, using hourly data on atmospheric conditions, including temperature, humidity, wind velocity, and atmospheric pressure, as well as SST data from satellites and in situ sensors.

The modeling suggested that the 2023 marine heat wave greatly exacerbated the East Asian heat wave, particularly in Japan, by affecting atmospheric circulation and altering the usual radiative effects of clouds and water vapor. The team said the influence of the marine heat wave explains roughly 20% to 50% of the increase in the intensity and duration of hot and humid conditions observed on land in East Asia in summer 2023.

The scientists note that this research provides valuable insights that could help improve long-range weather predictions. Such predictions may help communities prepare for health risks, particularly in Asia, which the World Meteorological Organization reported earlier this year is warming twice as fast as the global average. (AGU Advances, https://doi.org/10.1029/2025AV001673, 2025)

—Sarah Derouin (@sarahderouin.com), Science Writer

Citation: Derouin, S. (2025), Marine heat waves can exacerbate heat and humidity over land, Eos, 107, https://doi.org/10.1029/2026EO260009. Published on 2 January 2026. Text © 2026. AGU. CC BY-NC-ND 3.0
Except where otherwise noted, images are subject to copyright. Any reuse without express permission from the copyright owner is prohibited.

SummarySpatial autocorrelation (SPAC), the azimuthal average of the normalized cross-correlation between equidistant station pairs deployed in a 2-D array, is widely used to image the subsurface structure. However, the rigorous estimate of subsurface structure and its uncertainties as a function of depth using SPAC data is challenging due to the nonlinear relation between the SPAC data and Earth structure as well as the trade-off between depth and velocity. Additionally, data noise is strongly correlated due to data processing (e.g., filtering, stacking from multiple time segments and azimuthal averaging). Most studies do not account for the correlated noise and fix the ratio of compressional-wave velocity (${V}_P$) to shear-wave velocity (${V}_s$) (i.e., ${V}_P$/${V}_s$ ratio) and the number of layers, both of which are typically unknown. To address these challenges, we develop a hierarchical trans-dimensional Bayesian inversion of fundamental mode of SPAC data that properly accounts for the correlated data noise, samples the ${V}_P$/${V}_s$ ratio, and relaxes the number of layers (i.e., model parameterization) to be unknown in the inversion. We further examine the limitation of using only fundamental modes in the inversion. Our synthetic experiments show that the inversion recovers an incorrect model unless we sample the correlated noise and ${V}_P$/${V}_s$ ratio in the inversion. The inversion is then applied to SPAC data acquired at 19 sites across the Tacoma basin in Washington State to characterize the ${V}_s$ and the time-averaged ${V}_s$ over 30-m depth ($V{s}_{30}$). Our results show that the $V{s}_{30}\ $varies from ∼200 m/s to 800 m/s. The $V{s}_{30}$ within the basin is higher in the middle and lower on the east and west sides. We find that these $V{s}_{30}$ values vary with geologic unit. The uncertainties for $V{s}_{30}$ are within 20 m/s in average except for the most eastern site TB28. Additionally, the uncertainties are greater for deeper depths beneath most of the sites as the sensitivity decreases as a function of depth. The ${V}_s$ structure as a function of depth is also complex beneath some sites, possibly because the SPAC curves are affected by higher order Rayleigh modes that are not considered in the inversion. To better constrain the deeper ${V}_s\ $structure, $V{s}_{30}$, and/or other average measures of ${V}_s$ over depth, additional constraints from complementary data, such as ellipticity or geologic data are needed. Moreover, our synthetic experiments show that higher order modes can have significant effect in the inversion results, particularly when there is a low-velocity layer.

SummaryRegional geomagnetic field models are used to delineate intricate details of the Earth’s magnetic field and have significant application value in precision navigation and geomagnetic exploration. However, traditional modeling methods often encounter challenges when applied to sparse data, leading to issues like low model resolution and accuracy, as well as limited generalizability. The recently developed physics-informed neural networks (PINNs), a powerful modeling tool, presents a viable alternative for regional geomagnetic field modeling. This study employed the PINNs method to construct a geomagnetic field model for satellite altitudes over the Chinese region, based on the Swarm satellite dataset provided by the European Space Agency. An adaptive weight training method was used for the two-stage training process, involving an initial pre-training and subsequent fine-tuning of the model. Experimental verification shows that the proposed algorithm enhanced the model’s fidelity to physical laws, improved its resolution and prediction accuracy (reducing the root mean square errors for geomagnetic components to as low as 4 nT), and enhanced its generalizability, with the total field intensity F and the prediction accuracy of both the X- and Y-components demonstrating superiority over that of other traditional methods. Collectively, these advancements enable efficient regional geomagnetic field modeling while providing a foundation for more reliable and precise predictions.