Abstract
Accelerating warming and associated loss of sea ice are expected to promote the expansion of coastal marine forests (macrophytes) along the massive Arctic coastlines. Yet, this region has received much less attention compared to other global oceans. The available future projections of Arctic macrophytes are still limited to few species and regions, and mostly focused at lower latitude ranges, thus precluding well-informed IPCC impact assessments, conservation and management. Here we aim to quantify potential distributional changes of Arctic intertidal and subtidal brown macroalgae and eelgrass by the year 2100, relative to present. We estimate habitat suitability by means of species distribution modeling, considering changes in seawater temperature, salinity, nutrients and sea ice cover under two greenhouse gas emission scenarios, one consistent with the Paris Agreement (RCP 2.6) and the other representing limited mitigation strategies (RCP 8.5). As data on substrate conditions do not exist, the models were restricted to the depth range supporting Arctic macrophytes (down to 5 m for eelgrass and 30 m for brown macroalgae). Models projected major expansions of Arctic macrophytes between 69,940 and 123,360 km2, depending on the climate scenario, with polar distribution limits shifting northwards by up to 1.5 latitude degrees at 21.81 km per decade. Such expansions in response to changing climate will likely elicit major changes in biodiversity and ecosystem functions in the future Arctic. Expansions are, however, less intense than those already realized over the past century, indicating an overall slowing down despite accelerated warming as habitats become increasingly occupied.
Highlights
The Arctic Ocean is the epicenter of global climate change, warming at three times the global average rate (IPCC, 2021)
Sea ice and maximum temperature were important in explaining the distribution of Arctic macrophytes, TABLE 1 | Performance of the machine learning algorithms Adaptive Boosting (AdaBoost) and Boosted Regression Trees (BRT) inferred with cross-validation (CV) and the final predictive ensemble for pan-Arctic intertidal and subtidal brown macroalgae, and eelgrass biomes
Our study forecasts that the ongoing expansion of Arctic marine macrophytes with climate change (Krause-Jensen et al, 2020) will proceed throughout the twenty-first century under both RCP2.6 and RCP8.5 scenarios, with variability across the Pan-Arctic region
Summary
The Arctic Ocean is the epicenter of global climate change, warming at three times the global average rate (IPCC, 2021). Species distribution models, challenged by limited observation records, coarse resolution of environmental layers and lack of information on substrate in the Arctic, estimated a current (2000–2017) potential distribution area of brown macroalgae in the Arctic of 655,000 km (140,000 km intertidal, 515,000 km subtidal, with some overlap between the two). These areas represent an increase of about 45% for subtidal and 8% for intertidal macroalgae since 1940–1950, with poleward migration rates of biogeographic limits averaging between 18 and 23 km per decade (Krause-Jensen et al, 2020)
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