More Like this

1. Economic Viability and Emissions of Multimodal Transportation Infrastructure in a Changing Arctic

   https://doi.org/10.1175/WCAS-D-21-0151.1  

   Goldstein, Michael_A; Lynch, Amanda_H; Yan, Ruitian; Veland, Siri; Talleri, William (July 2022, Weather, Climate, and Society)

   Abstract As Arctic open water increases, shipping activity to and from mid- and western Russian Arctic ports to points south has notably increased. A number of Arctic municipalities hope increased vessel traffic will create opportunities to become a major transshipment hub. However, even with more traffic passing these ports, it might still be economically cheaper to offload cargo at a more southern port, which may also result in lower emissions. Ultimately, the question of whether to use a transshipment in the Arctic versus an established major European port is determined by the relative costs (or emissions) of sea versus land travel. This study calculates the relative competitiveness of six Norwegian coastal cities as multimodal hubs for shipments. We quantify the relative prices and CO₂emissions for sea and land travel for routes starting at the Norwegian–Russian sea border with an ultimate destination in central Europe and find that all existing routes are not competitive with routes using the major existing Port of Rotterdam (Netherlands); even with investments in port expansion and modernization, they would be underutilized regardless of an increase in vessel traffic destined for central Europe. We then examine under what relative prices (emissions) these routes become economically viable or result in lower emissions than using existing southern ports. Notably, the cheapest routes generally produce the lowest emissions, and the most expensive routes tend to have the largest emissions. Communities should consider relative competitiveness prior to making large infrastructure investments. While some choices are physically possible, they may not be economically viable. Significance StatementClimate change, while disruptive, can also create new opportunities. Many Arctic cities hope to become a major transshipping hub as declining sea ice opens new shipping routes from western and mid-Russian Arctic ports to European ports. This paper quantifies the relative competitiveness of six Norwegian coastal cities as multimodal transportation hubs and finds that they are uncompetitive with the more southern port in Rotterdam (Netherlands). We also show that the most economically competitive routes have lower direct emissions. Thus, while Arctic ports provide critical services in support of local and regional economic activity, even with year-round Arctic navigation Arctic ports’ development into major transshipment hubs for cargo destined for more distant locations may be neither economically viable nor desirable. 

   more » « less
2. A Convergence Science Approach to Understanding the Changing Arctic

   https://doi.org/10.1029/2023EF004157  

   Ivanov, Valeriy Y; Ungar, Peter S; Ziker, John P; Abdulmanova, Svetlana; Celis, Gerardo; Dixon, Andrew; Ehrich, Dorothee; Fufachev, Ivan; Gilg, Olivier; Heskel, Mary; et al (May 2024, Earth's Future)

   Abstract Science, engineering, and society increasingly require integrative thinking about emerging problems in complex systems, a notion referred to as convergence science. Due to the concurrent pressures of two main stressors—rapid climate change and industrialization, Arctic research demands such a paradigm of scientific inquiry. This perspective represents a synthesis of a vision for its application in Arctic system studies, developed by a group of disciplinary experts consisting of social and earth system scientists, ecologists, and engineers. Our objective is to demonstrate how convergence research questions can be developed via a holistic view of system interactions that are then parsed into material links and concrete inquiries of disciplinary and interdisciplinary nature. We illustrate the application of the convergence science paradigm to several forms of Arctic stressors using the Yamal Peninsula of the Russian Arctic as a representative natural laboratory with a biogeographic gradient from the forest‐tundra ecotone to the high Arctic. 

   more » « less
3. The Russian Maritime Arctic

   Brigham, L.W. (January 2022, The Wilson quarterly)

   The Russian maritime Arctic stretches more than 160 degrees longitude from the Norwegian-Russian border in the west, to the Bering Strait in the east. It is Russia’s vast northern coastline, an open border to the Arctic Ocean, and a marine space that presents both strategic vulnerabilities and economic opportunities. The entire coastal area is arguably undergoing the most profound changes of any region in today’s Arctic. This essay seeks to identify key influential drivers of change, and uncertainties that will plausibly determine the region’s future. 

   more » « less
4. Adaptive Strategies of Indigenous Nenets Reindeer Herders for Climate Change in Yamal

   https://doi.org/10.3167/sib.2024.230304  

   Terekhina, Alexandra; Volkovitskiy, Alexander; Stammler, Florian; Mertens, Karl; Ivanov, Valeriy Y; Orekhov, Pavel; Wren, Colin D; Tian, Boqi; Shen, Xin; Ivanova, Aytalina; et al (December 2024, Sibirica)

   Abstract Nenets reindeer pastoralists of Yamal in the Russian Arctic, successfully deal with rapidly changing climate and natural gas industrialization. We present results from our long-term ethnographic study (2001–present) on the adaptive strategies that Nenets nomadic households have employed over time, their tradeoffs, inherent risks, and social implications of these strategies. While some strategies limit the adaptive flexibility of herding, they simultaneously enable agency that keeps Nenets households on the land—critical for maintaining their nomadism. Rapid climate change in the Arctic, which could lead to increased icing of pastures, makes reindeer herding more vulnerable. We examine meteorological data from Yamal to better understand the climatic trends challenging reindeer nomadism. Our analysis is relevant for policymakers through understanding Nenets adaptation and interactions with ecological processes and institutions. 

   more » « less
5. High‐Latitude Eddy Covariance Temporal Network Design and Optimization

   https://doi.org/10.1029/2024JG008406  

   Pallandt, Martijn_M_T A; Jung, Martin; Arndt, Kyle; Natali, Susan M; Rogers, Brendan M; Virkkala, Anna‐Maria; Göckede, Mathias (October 2024, Journal of Geophysical Research: Biogeosciences)

   Abstract Ecosystems at high latitudes are changing rapidly in response to climate change. To understand changes in carbon fluxes across seasonal to multi‐decadal timescales, long‐term in situ measurements from eddy covariance networks are needed. However, there are large spatiotemporal gaps in the high‐latitude eddy covariance network. Here we used the relative extrapolation error index in machine learning‐based upscaled gross primary production as a measure of network representativeness and as the basis for a network optimization. We show that the relative extrapolation error index has steadily decreased from 2001 to 2020, suggesting diminishing upscaling errors. In experiments where we limit site activity by either setting a maximum duration or by ending measurements at a fixed time those errors increase significantly, in some cases setting the network status back more than a decade. Our experiments also show that with equal site activity across different theoretical network setups, a more spread out design with shorter‐term measurements functions better in terms of larger‐scale representativeness than a network with fewer long‐term towers. We developed a method to select optimized site additions for a network extension, which blends an objective modeling approach with expert knowledge. This method greatly outperforms an unguided network extension and can compensate for suboptimal human choices. For the Canadian Arctic we show several optimization scenarios and find that especially the Canadian high Arctic and north east tundra benefit greatly from addition sites. Overall, it is important to keep sites active and where possible make the extra investment to survey new strategic locations. 

   more » « less