Vegetation change on mountaintops in northern Sweden : stable vascular‐plant but reordering of lichen and bryophyte communities

Alpine ecosystems harbor remarkably diverse and distinct plant communities that are characteristically limited to harsh, and cold climatic conditions. As a result of thermal limitation to species occurrence, mountainous ecosystems are considered to be particularly sensitive to climate change. Our un...

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Bibliographic Details
Published in:Ecological Research
Main Authors: Hagenberg, Liyenne Wu Chen, Vanneste, Thomas, Opedal, Øystein H., Petlund, Hanne Torsdatter, Björkman, Mats P., Björk, Robert G., Holien, Håkon, Limpens, Juul, Molau, Ulf, Graae, Bente Jessen, De Frenne, Pieter
Format: Article in Journal/Newspaper
Language:English
Published: 2022
Subjects:
Earth and Environmental Sciences
alpine vegetation
climate change impact
ecosystem change
lichens and bryophytes
non-climatic drivers
Northern Sweden
Online Access:https://biblio.ugent.be/publication/01GQHW6X04F8KWPSM6107YYS3T
http://hdl.handle.net/1854/LU-01GQHW6X04F8KWPSM6107YYS3T
https://doi.org/10.1111/1440-1703.12359
https://biblio.ugent.be/publication/01GQHW6X04F8KWPSM6107YYS3T/file/01GQHW7KBM4D6MCYWDKY78ZBPT
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Summary:Alpine ecosystems harbor remarkably diverse and distinct plant communities that are characteristically limited to harsh, and cold climatic conditions. As a result of thermal limitation to species occurrence, mountainous ecosystems are considered to be particularly sensitive to climate change. Our understanding of the impact of climate change is mainly based on vascular plants however, whereas cryptogams (i.e., lichens and bryophytes) are generally neglected or simply considered as one functional group. Here we aimed to improve our understanding of the drivers underlying temporal changes in vegetation of alpine ecosystems. To this end, we repeatedly surveyed the vegetation on four mountain summits along an elevational gradient in northern Sweden spanning a 19-year period. Our results show that the vascular plant communities remained relatively stable throughout the study period, despite fluctuations in terms of ground cover and species richness of shrubs and graminoids. In contrast, both lichens and bryophytes substantially decreased in cover and diversity, leading to alterations in community composition that were unrelated to vascular plant cover. Thermophilization of the vascular plant community was found only on the two intermediate summits. Our findings are only partially consistent with (long-term) climate-change impacts, and we argue that local non-climatic drivers such as herbivory might offset vegetation responses to warming. Hence, we underline the importance of considering local non-climatic drivers when evaluating temporal vegetation change in biologically complex systems.

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