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1. Presentations and Zoom Recordings from the 75th Anniversary Celebration of the Naval Arctic Research Laboratory (NARL) and the Enhancing Arctic Science and Engineering (EASE) Workshop, Utqiaġvik, Alaska, 1-5 August 2022

   https://doi.org/10.18739/A26688M4F  

   Jones, Benjamin (January 2024, NSF Arctic Data Center)

   In early August 2022, a multidisciplinary, intergenerational, and cross-cultural group of participants converged on Utqiaġvik, Alaska to celebrate the 75th Anniversary of the Naval Arctic Research Laboratory (NARL) and to take part in a National Science Foundation (NSF) funded workshop focused on Enhancing Arctic Science and Engineering (EASE). The foundation of the EASE workshop was grounded in a legacy of promoting sustainable Arctic science in Utqiaġvik, as a model for the circumpolar north, being guided by the important role of the Inupiat in furthering scientific understanding of climatic and social-ecological change in the rapidly changing Arctic. The five-day event focused on summarizing science and engineering in Utqiaġvik and the greater North Slope region over the last 75 years, an assessment of the current state of the science and engineering being conducted, and a prospectus on science and engineering in the Arctic over the next 25 years. The workshop included oral and poster presentations and featured keynote speakers that focused on key achievements and past research endeavors to provide the framework for envisioning the trajectory of Arctic science, engineering, and education in the future. Specific themes of the EASE workshop included marine and coastal research, terrestrial and freshwater research, atmospheric research, social science research, co-production of knowledge, convergent research, and education and outreach opportunities. The gathering included more than 140 participants from academia, federal agencies, nonprofit organizations, industry, community members, and local-to-regional governments and corporations. Participant expertise included natural and social scientists from the range of disciplines reflected in the workshop’s themes, as well as engineers, planners, students, and local and Indigenous leaders and knowledge holders. U.S. government representatives came from the National Science Foundation, the National Oceanic and Atmospheric Administration, U.S. Arctic Research Commission, Department of Energy’s Arctic Energy Office and Office of Science, Sandia National Lab, Pacific Northwest National Lab, Lawrence Livermore National Lab, U.S. Department of Agriculture, Ted Stevens Center for Arctic Security Studies, and the U.S. Navy. Senator Murkowski’s and Senator Sullivan’s offices each contributed introductory remarks that provided context for the importance of this event in the State of Alaska’s history. The data archived here includes PDF documents for each of the presentations at the event as well as the accompanying zoom recordings of each presentation where documented. There are also zoom recordings of panel summaries and interviews with several past Arctic researchers. This material is based upon work supported by the National Science Foundation under NSF grant no. 2224192. Any opinions, findings and conclusions or recommendations expressed in this material are those of the author(s) and do not necessarily reflect the views of the National Science Foundation. Material from the event is also available at https://narl75.alaska.edu/ 

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2. The Circumpolar Arctic Vegetation Science Initiative (CAVSI): A framework to help guide the next decade of Arctic vegetation research

   https://doi.org/10.18739/A2T43J49W  

   CAVSI_Organizing_Team (June 2025, National Science Foundation Arctic Data Center)

   Walker, D A; Peirce, J L (Ed.)

   Arctic vegetation is the visible surface expression of Arctic terrestrial systems. It is the key to monitoring and modeling changes to most components of the system, such as shrub distribution; greening patterns, plant and animal habitats and biodiversity, hydrological networks, and snow distribution, as well as the less visible aspects, such as permafrost, soil carbon stocks, and greenhouse-gas emissions. Currently, there are no standardized approaches to sample, describe, map, and analyze circumpolar patterns of Arctic vegetation across a hierarchy of spatial scales and international boundaries. There is a need for a well-distributed Arctic vegetation observatory network and a set of internationally accepted protocols for sampling, data information systems, classifying, and mapping vegetation to aid in addressing priority research topics for the Fourth International Conference on Arctic Research Planning (ICARP IV) and the The Fifth International Polar Year (IPY5). The Circumpolar Arctic Vegetation Science Initiative (CAVSI) is a response to these needs and those expressed by ICARP IV Research Priority Team 1 (RPT 1) (Zhang and Rasouli 2025) and Research Priority Team 2 (RPT2) (Bret-Harte 2025), which focus on the role of the Arctic in the global system and observing, reconstructing, and predicting future Arctic climate dynamics and ecosystem responses. CAVSI is also a response to the recommendation by the Arctic Council for long-term biodiversity monitoring to address key gaps in Arctic-system knowledge (Conservation of Arctic Flora and Fauna (CAFF) 2013, Christiansen et al. 2020, Barry 2023). It aligns with several national and international Arctic research plans and policies that involve observation, monitoring, modeling, and prediction, including those of the United States (Office of Science & Technology Policy (OSTP) 2022, United States Army Reserve Command (USARC) 2023) and the international Sustaining Arctic Research Network (Sustaining Arctic Observing Networks (SAON), Starkweather et al. 2021). This white paper provides a framework for vegetation description and monitoring. It includes: (1) a network of sites across the full range of Arctic climates, phytogeographic regions, local habitats, and disturbance regimes; (2) standardized methods to describe and monitor local floras, vegetation composition, and key environmental factors; (3) a pan-Arctic vegetation plot archive to store legacy and recent plot data; (4) a consistent hierarchical classification and checklist of Arctic vegetation; (5) an archive of Arctic vegetation and landcover maps; (6) applications and ideas for CAVSI IPY5 initiatives; (7) an 11-year timeline for CAVSI activities leading up to and including synthesis from IPY5 activities; and (8) recommendations for priority activities and research related to ICARP IV RPTs 1 and 2. 

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3. Advancing Arctic Sea Ice Remote Sensing with AI and Deep Learning: Opportunities and Challenges

   https://doi.org/10.3390/rs16203764  

   Li, Wenwen; Hsu, Chia-Yu; Tedesco, Marco (October 2024, Remote Sensing)

   Revolutionary advances in artificial intelligence (AI) in the past decade have brought transformative innovation across science and engineering disciplines. In the field of Arctic science, we have witnessed an increasing trend in the adoption of AI, especially deep learning, to support the analysis of Arctic big data and facilitate new discoveries. In this paper, we provide a comprehensive review of the applications of deep learning in sea ice remote sensing domains, focusing on problems such as sea ice lead detection, thickness estimation, sea ice concentration and extent forecasting, motion detection, and sea ice type classification. In addition to discussing these applications, we also summarize technological advances that provide customized deep learning solutions, including new loss functions and learning strategies to better understand sea ice dynamics. To promote the growth of this exciting interdisciplinary field, we further explore several research areas where the Arctic sea ice community can benefit from cutting-edge AI technology. These areas include improving multimodal deep learning capabilities, enhancing model accuracy in measuring prediction uncertainty, better leveraging AI foundation models, and deepening integration with physics-based models. We hope that this paper can serve as a cornerstone in the progress of Arctic sea ice research using AI and inspire further advances in this field. 

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4. A new ice-rich-permafrost-system observatory, Prudhoe Bay Oilfield, Alaska: landscape evolution on ice-rich calcareous fluvial, eolian, and lacustrine deposits

   Walker, DA (June 2024, NSF PAR)

   Long-term permafrost observatories are needed to document and monitor rapid changes to ice-rich permafrost systems (IRPS) in a variety of geological, climatic, and infrastructure settings. As part of the US National Science Foundation’s Navigating the New Arctic (NNA) Program, a new observatory was established near the Deadhorse Airport in the eastern part of the Prudhoe Bay Oilfield (PBO) in 2020–23. The NNA-IRPS project has three main research themes: (1) evolution of and degradation of ground ice within the major surficial-geology units; (2) rapid changes in permafrost, landforms, and vegetation due to infrastructure and climate change; and (3) ecological landscapes associated with the calcareous fluvial deposits of the Central Arctic Coastal Plain. 

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5. An Optimal GeoAI Workflow for Pan-Arctic Permafrost Feature Detection from High-Resolution Satellite Imagery

   https://doi.org/10.14358/PERS.21-00059R2  

   Udawalpola, Mahendra R.; Hasan, Amit; Liljedahl, Anna; Soliman, Aiman; Terstriep, Jeffrey; Witharana, Chandi (March 2022, Photogrammetric Engineering & Remote Sensing)

   High-spatial-resolution satellite imagery enables transformational opportunities to observe, map, and document the micro-topographic transitions occurring in Arctic polygonal tundra at multiple spatial and temporal frequencies. Knowledge discovery through artificial intelligence, big imagery, and high-performance computing (HPC) resources is just starting to be realized in Arctic permafrost science. We have developed a novel high-performance image-analysis framework—Mapping Application for Arctic Permafrost Land Environment (MAPLE)—that enables the integration of operational-scale GeoAI capabilities into Arctic permafrost modeling. Interoperability across heterogeneous HPC systems and optimal usage of computational resources are key design goals of MAPLE. We systematically compared the performances of four different MAPLE workflow designs on two HPC systems. Our experimental results on resource utilization, total time to completion, and overhead of the candidate designs suggest that the design of an optimal workflow largely depends on the HPC system architecture and underlying service-unit accounting model. 

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