Your search keyword '"Svenning, Martin"' showing total 6 results

1. Temporal changes in the relative abundance of anadromous Arctic charr, brown trout, and Atlantic salmon in northern Europe: Do they reflect changing climates?

Author

Svenning, Martin‐A., primary, Falkegård, Morten, additional, Dempson, J. Brian, additional, Power, Michael, additional, Bårdsen, Bård‐Jørgen, additional, Guðbergsson, Gudni, additional, and Fauchald, Per, additional

Published

2021

2. Temporal changes in the relative abundance of anadromous Arctic charr, brown trout, and Atlantic salmon in northern Europe: Do they reflect changing climates?

Author

Svenning, Martin‐A., Falkegård, Morten, Dempson, J. Brian, Power, Michael, Bårdsen, Bård‐Jørgen, Guðbergsson, Gudni, and Fauchald, Per

Subjects

*ARCTIC char, *BROWN trout, *FRESHWATER fishes, *ATLANTIC salmon, *CLIMATE change, *ATMOSPHERIC temperature, *SALMONIDAE, *FISHERIES

Abstract

Warming temperatures resulting from climate change may alter the distribution and abundance of many freshwater fish species, especially those in northern latitudes. Owing to interspecific differences in temperature adaptations and tolerances, warming may lead to changes in the fish community as a result of shifts in the abundance of co‐existing species.We investigated how increased temperatures have potentially affected the abundance and catch composition of anadromous salmonids in northern Europe. We used national angling catch statistics over a period of several decades (1993–2018) as a proxy of relative annual abundance of adult Atlantic salmon (Salmo salar), brown trout (Salmo trutta), and Arctic charr (Salvelinus alpinus) in water courses in Iceland and in northern Norway. These are the only locations in the world where the three species coexist naturally as anadromous forms, and where they are distributed across latitudinal gradients characterised by varying temperatures.Interpolated data on average annual air temperatures proximate to the study rivers increased 1–1.7°C in northern Norway and 1.0–1.5°C in Iceland during the 26‐year study period.While the overall total number of fish caught has remained relatively stable during the period of study, gradual climate warming has been accompanied by a marked change in the catch composition of the three species in both countries. Increased temperatures were related to a decreased proportion of Arctic charr and an increased proportion of brown trout, while no temperature effect was found for Atlantic salmon. Controlling for the difference between fluvial and lacustrine systems, brown trout has begun to replace Arctic charr in all regions, whereas the relative catch of Atlantic salmon has been stable.Interpretation of angling data can facilitate understanding of longer‐term trends in catch data and provide insights into possible underlying changes in fish species and alert managers to shifts in abundance that might be mitigated by management actions. However, care must be taken to avoid the confounding effects that changes in fisheries management measures, angler preferences, and effort might have on the metrics of relative change used to make inferences about long‐term trends. [ABSTRACT FROM AUTHOR]

Published

2022

3. Multitrophic biodiversity patterns and environmental descriptors of sub‐Arctic lakes in northern Europe.

Author

Lau, Danny C. P., Christoffersen, Kirsten S., Erkinaro, Jaakko, Hayden, Brian, Heino, Jani, Hellsten, Seppo, Holmgren, Kerstin, Kahilainen, Kimmo K., Kahlert, Maria, Karjalainen, Satu Maaria, Karlsson, Jan, Forsström, Laura, Lento, Jennifer, Mjelde, Marit, Ruuhijärvi, Jukka, Sandøy, Steinar, Schartau, Ann Kristin, Svenning, Martin‐A., Vrede, Tobias, and Goedkoop, Willem

Subjects

DIATOMS, MACROPHYTES, BIODIVERSITY, LAKES, FISH diversity, BIODIVERSITY monitoring, FOOD chains, LAKE management

Abstract

Arctic and sub‐Arctic lakes in northern Europe are increasingly threatened by climate change, which can affect their biodiversity directly by shifting thermal and hydrological regimes, and indirectly by altering landscape processes and catchment vegetation. Most previous studies of northern lake biodiversity responses to environmental changes have focused on only a single organismal group. Investigations at whole‐lake scales that integrate different habitats and trophic levels are currently rare, but highly necessary for future lake monitoring and management.We analysed spatial biodiversity patterns of 74 sub‐Arctic lakes in Norway, Sweden, Finland, and the Faroe Islands with monitoring data for at least three biological focal ecosystem components (FECs)—benthic diatoms, macrophytes, phytoplankton, littoral benthic macroinvertebrates, zooplankton, and fish—that covered both pelagic and benthic habitats and multiple trophic levels.We calculated the richnessrelative (i.e. taxon richness of a FEC in the lake divided by the total richness of that FEC in all 74 lakes) and the biodiversity metrics (i.e. taxon richness, inverse Simpson index (diversity), and taxon evenness) of individual FECs using presence–absence and abundance data, respectively. We then investigated whether the FEC richnessrelative and biodiversity metrics were correlated with lake abiotic and geospatial variables. We hypothesised that (1) individual FECs would be more diverse in a warmer and wetter climate (e.g. at lower latitudes and/or elevations), and in hydrobasins with greater forest cover that could enhance the supply of terrestrial organic matter and nutrients that stimulated lake productivity; and (2) patterns in FEC responses would be coupled among trophic levels.Results from redundancy analyses showed that the richnessrelative of phytoplankton, macrophytes, and fish decreased, but those of the intermediate trophic levels (i.e. macroinvertebrates and zooplankton) increased with decreasing latitude and/or elevation. Fish richnessrelative and diversity increased with increasing temporal variation in climate (temperature and/or precipitation), ambient nutrient concentrations (e.g. total nitrogen) in lakes, and woody vegetation (e.g. taiga forest) cover in hydrobasins, whereas taxon richness of macroinvertebrates and zooplankton decreased with increasing temporal variation in climate.The similar patterns detected for richnessrelative of fish, macrophytes, and phytoplankton could be caused by similar responses to the environmental descriptors, and/or the beneficial effects of macrophytes as habitat structure. By creating habitat, macrophytes may increase fish diversity and production, which in turn may promote higher densities and probably more diverse assemblages of phytoplankton through trophic cascades. Lakes with greater fish richnessrelative tended to have greater average richnessrelative among FECs, suggesting that fish are a potential indicator for overall lake biodiversity.Overall, the biodiversity patterns observed along the environmental gradients were trophic‐level specific, indicating that an integrated food‐web perspective may lead to a more holistic understanding of ecosystem biodiversity in future monitoring and management of high‐latitude lakes. In future, monitoring should also focus on collecting more abundance data for fish and lower trophic levels in both benthic and pelagic habitats. This may require more concentrated sampling effort on fewer lakes at smaller spatial scales, while continuing to sample lakes distributed along environmental gradients. [ABSTRACT FROM AUTHOR]

Published

2022

4. Circumpolar patterns of Arctic freshwater fish biodiversity: A baseline for monitoring.

Author

Laske, Sarah M., Amundsen, Per‐Arne, Christoffersen, Kirsten S., Erkinaro, Jaakko, Guðbergsson, Guðni, Hayden, Brian, Heino, Jani, Holmgren, Kerstin, Kahilainen, Kimmo K., Lento, Jennifer, Orell, Panu, Östergren, Johan, Power, Michael, Rafikov, Ruslan, Romakkaniemi, Atso, Svenning, Martin‐A., Swanson, Heidi, Whitman, Matthew, and Zimmerman, Christian E.

Subjects

FRESHWATER biodiversity, BIODIVERSITY monitoring, COLONIZATION (Ecology), BIOLOGICAL extinction, SPECIES diversity, ARCTIC char, FRESHWATER fishes

Abstract

Climate change, biological invasions, and anthropogenic disturbance pose a threat to the biodiversity and function of Arctic freshwater ecosystems. Understanding potential changes in fish species distribution and richness is necessary, given the great importance of fish to the function of freshwater ecosystems and as a resource to humans. However, information gaps limit large‐scale studies and our ability to determine patterns and trends in space and time. This study takes the first step in determining circumpolar patterns of fish species richness and composition, which provides a baseline to improve both monitoring and conservation of Arctic freshwater biodiversity.Information on species presence/absence was gathered from the Circumpolar Biodiversity Monitoring Program's Freshwater Database and used to examine patterns of freshwater fish γ‐, α‐, and β‐diversity across 234° of longitude in the Arctic. The metrics of diversity provided information on species richness and composition across hydrobasins, ecoregions, and Arctic zones.Circumpolar patterns of fish species biodiversity varied with latitude, isolation, and coarse ecoregion characteristics; patterns were consistent with historic and contemporary barriers to colonisation and environmental characteristics. Gamma‐diversity was lower in the high Arctic compared to lower latitude zones, but α‐diversity did not decrease with increasing latitude below 71°N, reflecting glacial history. Alpha‐diversity was reduced to a single species, Arctic charr Salvelinus alpinus, in ecoregions above 71°N, where γ‐diversity was the lowest. Beta‐diversity indicated little variation in the composition and richness of species across the High Arctic; at lower latitudes, ecoregions contained more species, although species composition turned over across large spatial extents.In an analysis of five ecoregions in the circumpolar Arctic, physical isolation, and ecoregion area and topography were identified as strong drivers of γ‐, α‐, and β‐diversity. Physical isolation reduced the γ‐ and α‐diversity, and changes in β‐diversity between adjacent locations were due mainly to losses in species richness, rather than due to differences in species composition. Heterogeneity of habitats, environmental gradients, and geographic distance probably contributed to patterns of fish dissimilarity within and across ecoregions.This study presents the first analysis of large‐scale patterns of freshwater fish biodiversity in the circumpolar Arctic. However, information gaps in space, time, and among taxonomic groups remain. Future inclusion of extensive archive and new data will allow future studies to test for changes and drivers of the observed patterns of biodiversity. This is important given the potential impacts of ongoing and accelerating climate change, land use, and biotic exchange on Arctic fish biodiversity. [ABSTRACT FROM AUTHOR]

Published

2022

5. Multitrophic biodiversity patterns and environmental descriptors of sub‐Arctic lakes in northern Europe

Author

Lau, Danny C. P., primary, Christoffersen, Kirsten S., additional, Erkinaro, Jaakko, additional, Hayden, Brian, additional, Heino, Jani, additional, Hellsten, Seppo, additional, Holmgren, Kerstin, additional, Kahilainen, Kimmo K., additional, Kahlert, Maria, additional, Karjalainen, Satu Maaria, additional, Karlsson, Jan, additional, Forsström, Laura, additional, Lento, Jennifer, additional, Mjelde, Marit, additional, Ruuhijärvi, Jukka, additional, Sandøy, Steinar, additional, Schartau, Ann Kristin, additional, Svenning, Martin‐A., additional, Vrede, Tobias, additional, and Goedkoop, Willem, additional

Published

2020

6. Circumpolar patterns of Arctic freshwater fish biodiversity: A baseline for monitoring

Author

Laske, Sarah M., primary, Amundsen, Per‐Arne, additional, Christoffersen, Kirsten S., additional, Erkinaro, Jaakko, additional, Guðbergsson, Guðni, additional, Hayden, Brian, additional, Heino, Jani, additional, Holmgren, Kerstin, additional, Kahilainen, Kimmo K., additional, Lento, Jennifer, additional, Orell, Panu, additional, Östergren, Johan, additional, Power, Michael, additional, Rafikov, Ruslan, additional, Romakkaniemi, Atso, additional, Svenning, Martin‐A., additional, Swanson, Heidi, additional, Whitman, Matthew, additional, and Zimmerman, Christian E., additional

Published

2019