Patchy field sampling biases understanding of climate change impacts across the Arctic

Metcalfe, Daniel B.; Hermans, Thirze D. G.; Ahlstrand, Jenny; Becker, Michael; Berggren, Martin; Björk, Robert G.; Björkman, Mats; Blok, Daan; Chaudhary, Nitin; Chisholm, Chelsea; Classen, Aimée T.; Hasselquist, Niles J.; Jonsson, Micael; Kristensen, J. A.; Kumordzi, Bright B.; Lee, Hanna; Mayor, Jordan R.; Prevéy, Janet S.; Pantazatou, Karolina; Rousk, Johannes; Sponseller, Ryan A.; Sundqvist, Maja K.; Tang, Jing; Uddling, Johan; Wallin, Göran; Zhang, Wenxing; Ahlström, Anders; Tenenbaum, David E.; Abdi, Abdulhakim M.

doi:10.1038/s41559-018-0612-5

Cited by 128 publications

(108 citation statements)

References 23 publications

Supporting

Mentioning

105

Contrasting

Order By: Relevance

“…However, the Arctic is large and diverse, with variation in permafrost extent and soil C storage (Hugelius et al, ), as well as regional differences in vegetation structure and growth trends (Huang et al, ), which together underpin largely unknown variability in stream biogeochemistry and aquatic ecosystem dynamics. Thus, multiple Arctic regions may respond uniquely to global change, and this variability needs to be captured in future studies, given current focus on few Arctic areas (Metcalfe et al, ). Regardless, owing to the importance of the Arctic C feedback on climate change (Schuur et al, ) and the dependence of stream respiration to discharge and C supply (Demars, ), we suggest to include stream metabolism and its response to environmental change (e.g.…”

Section: Discussionmentioning

confidence: 99%

Stream metabolism controls diel patterns and evasion of CO₂ in Arctic streams

Rocher-Ros

Sponseller

Bergström

et al. 2019

Global Change Biology

Self Cite

View full text Add to dashboard Cite

Streams play an important role in the global carbon (C) cycle, accounting for a large portion of CO2 evaded from inland waters despite their small areal coverage. However, the relative importance of different terrestrial and aquatic processes driving CO2 production and evasion from streams remains poorly understood. In this study, we measured O2 and CO2 continuously in streams draining tundra‐dominated catchments in northern Sweden, during the summers of 2015 and 2016. From this, we estimated daily metabolic rates and CO2 evasion simultaneously and thus provide insight into the role of stream metabolism as a driver of C dynamics in Arctic streams. Our results show that aquatic biological processes regulate CO2 concentrations and evasion at multiple timescales. Photosynthesis caused CO2 concentrations to decrease by as much as 900 ppm during the day, with the magnitude of this diel variation being strongest at the low‐turbulence streams. Diel patterns in CO2 concentrations in turn influenced evasion, with up to 45% higher rates at night. Throughout the summer, CO2 evasion was sustained by aquatic ecosystem respiration, which was one order of magnitude higher than gross primary production. Furthermore, in most cases, the contribution of stream respiration exceeded CO2 evasion, suggesting that some stream reaches serve as net sources of CO2, thus creating longitudinal heterogeneity in C production and loss within this stream network. Overall, our results provide the first link between stream metabolism and CO2 evasion in the Arctic and demonstrate that stream metabolic processes are key drivers of the transformation and fate of terrestrial organic matter exported from these landscapes.

show abstract

Section: Discussionmentioning

confidence: 99%

Stream metabolism controls diel patterns and evasion of CO₂ in Arctic streams

Rocher-Ros

Sponseller

Bergström

et al. 2019

Global Change Biology

Self Cite

View full text Add to dashboard Cite

show abstract

“…While some biomes are proportionally well sampled, even within those biomes, the study sites are sometimes clustered around single locations, calling into question how generalizable those results are for an entire region, especially in regions where the climate is changing rapidly (Metcalfe et al. ).…”

Section: Discussionmentioning

confidence: 99%

“…"global" climate change impacts found a severe geographic bias and noted that generalizing results from temperate areas to the globe is problematic because tropical species may be expected to respond differently to climate change than temperate species (Feeley et al 2017). While some biomes are proportionally well sampled, even within those biomes, the study sites are sometimes clustered around single locations, calling into question how generalizable those results are for an entire region, especially in regions where the climate is changing rapidly (Metcalfe et al 2018).…”

Section: Discussionmentioning

confidence: 99%

Uneven global distribution of food web studies under climate change

et al. 2019

Self Cite

View full text Add to dashboard Cite

Trophic interactions within food webs affect species distributions, coexistence, and provision of ecosystem services but can be strongly impacted by climatic changes. Understanding these impacts is therefore essential for managing ecosystems and sustaining human well‐being. Here, we conducted a global synthesis of terrestrial, marine, and freshwater studies to identify key gaps in our knowledge of climate change impacts on food webs and determine whether the areas currently studied are those most likely to be impacted by climate change. We found research suffers from a strong geographic bias, with only 3.5% of studies occurring in the tropics. Importantly, the distribution of sites sampled under projected climate changes was biased—areas with decreases or large increases in precipitation and areas with low magnitudes of temperature change were under‐represented. Our results suggest that understanding of climate change impacts on food webs could be broadened by considering more than two trophic levels, responses in addition to species abundance and biomass, impacts of a wider suite of climatic variables, and tropical ecosystems. Most importantly, to enable better forecasts of biodiversity responses to climate change, we identify critically under‐represented geographic regions and climatic conditions which should be prioritized in future research.

show abstract

“…Here, we use a quantitative framework based on multivariate statistical modeling to present the current state of sampling across environmental science disciplines in the Arctic. We utilize an existing database of field studies across the Arctic that was developed by Metcalfe et al (2018). We build upon this earlier work with a more comprehensive and detailed investigation of how locations and citations within different disciplines are distributed across Arctic topographical, soil and vegetation conditions, and provide recommendations for potential new study areas in different disciplines.…”

Section: Introductionmentioning

confidence: 99%

Identifying multidisciplinary research gaps across Arctic terrestrial gradients

Virkkala

Abdi

Luoto

et al. 2019

Environ. Res. Lett.

Self Cite

View full text Add to dashboard Cite

Global warming is driving environmental change in the Arctic. However, our current understanding of this change varies strongly among different environmental disciplines and is limited by the number and distribution of field sampling locations. Here, we use a quantitative framework based on multivariate statistical modeling to present the current state of sampling across environmental disciplines in the Arctic. We utilize an existing database of georeferenced Arctic field studies to investigate how sampling locations and citations of disciplines are distributed across Arctic topographical, soil and vegetation conditions, and highlight critical regions for potential new research areas in different disciplines. Continuous permafrost landscapes, and the northernmost Arctic bioclimatic zones are studied and cited the least in relation to their extent in many disciplines. We show that the clusters of sampling locations and citations are not uniform across disciplines. Sampling locations in Botany and Biogeochemistry cover environmental gradients the best, and Microbiology, Meteorology, Geosciences And Geographic Information Systems/remote Sensing/Modeling have the worst coverage. We conclude that across all disciplines, more research is needed particularly in the Canadian Arctic Archipelago, northern Greenland, central and eastern Siberia, and in some disciplines, in Canadian mainland, central Alaska, western Siberia and northern Taimyr region. We provide detailed maps of potential new sampling locations for each environmental discipline that consider multiple variables simultaneously. These results will help prioritize future research efforts, thus increasing our knowledge about the Arctic environmental change.

show abstract

Patchy field sampling biases understanding of climate change impacts across the Arctic

Cited by 128 publications

References 23 publications

Stream metabolism controls diel patterns and evasion of CO₂ in Arctic streams

Stream metabolism controls diel patterns and evasion of CO₂ in Arctic streams

Uneven global distribution of food web studies under climate change

Identifying multidisciplinary research gaps across Arctic terrestrial gradients

Contact Info

Product

Resources

About

Patchy field sampling biases understanding of climate change impacts across the Arctic

Cited by 128 publications

References 23 publications

Stream metabolism controls diel patterns and evasion of CO2 in Arctic streams

Stream metabolism controls diel patterns and evasion of CO2 in Arctic streams

Uneven global distribution of food web studies under climate change

Identifying multidisciplinary research gaps across Arctic terrestrial gradients

Contact Info

Product

Resources

About

Stream metabolism controls diel patterns and evasion of CO₂ in Arctic streams

Stream metabolism controls diel patterns and evasion of CO₂ in Arctic streams