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The role of dispersal limitation in the forest biome shifts of Europe in the last 18,000 years

Zani, Deborah LU ; Lischke, Heike and Lehsten, Veiko LU (2024) In Journal of Biogeography
Abstract

Aim: How the ability of plants to move towards newly favourable habitats (dispersal limitation) impacts the change of biome distribution and transition under fast climate warming is still debated. Analysing vegetation change in the past may help to clarify the relative importance of underlying ecological processes such as climate, biotic interactions, and dispersal. In this study, we investigated how dispersal limitation affected the distribution of European forests in the last 18,000 years. Location: Southern and Central Europe. Taxon: Spermatophyta. Methods: Using the LPJ-GM 2.0 model (an extension of LPJ-GUESS), we simulated European vegetation from the end of the Last Glacial Maximum (18.5 ka) to the current time (0 ka). Using biome... (More)

Aim: How the ability of plants to move towards newly favourable habitats (dispersal limitation) impacts the change of biome distribution and transition under fast climate warming is still debated. Analysing vegetation change in the past may help to clarify the relative importance of underlying ecological processes such as climate, biotic interactions, and dispersal. In this study, we investigated how dispersal limitation affected the distribution of European forests in the last 18,000 years. Location: Southern and Central Europe. Taxon: Spermatophyta. Methods: Using the LPJ-GM 2.0 model (an extension of LPJ-GUESS), we simulated European vegetation from the end of the Last Glacial Maximum (18.5 ka) to the current time (0 ka). Using biome reconstructions from pollen data as reference, we compared the performance of two dispersal modes: with no migration constraints or seed limitation (free dispersal mode), and with plant establishment depending on seed dynamics and dispersal (dispersal limitation mode). Results: The model run, including migration processes, was better at capturing the post-glacial expansion of European temperate forests (and the longer persistence of boreal forests) than the setting assuming free dispersal, especially during periods of rapid warming. This suggests that a number of (temperate) tree taxa experienced delayed occupancy of climatically suitable habitats due to a limited dispersal capacity, i.e., post-glacial migration lags. Main Conclusions: Our results show that including migration processes in model simulations allows for more realistic reconstructions of forest patterns under rapid climate change, with consequences for future projections of carbon sequestration and climate reconstructions with vegetation feedback, assisted migration and forest conservation.

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author
; and
organization
publishing date
type
Contribution to journal
publication status
epub
subject
keywords
biomization, dispersal limitation, Europe, LPJ-GUESS, migration, paleoclimate, paleovegetation, pollen, vegetation change
in
Journal of Biogeography
publisher
Wiley-Blackwell
external identifiers
  • scopus:85189534334
ISSN
0305-0270
DOI
10.1111/jbi.14836
language
English
LU publication?
yes
id
8d9778b0-e49a-4481-bcdf-75274bb702b5
date added to LUP
2024-04-22 15:46:34
date last changed
2024-04-22 15:47:41
@article{8d9778b0-e49a-4481-bcdf-75274bb702b5,
  abstract     = {{<p>Aim: How the ability of plants to move towards newly favourable habitats (dispersal limitation) impacts the change of biome distribution and transition under fast climate warming is still debated. Analysing vegetation change in the past may help to clarify the relative importance of underlying ecological processes such as climate, biotic interactions, and dispersal. In this study, we investigated how dispersal limitation affected the distribution of European forests in the last 18,000 years. Location: Southern and Central Europe. Taxon: Spermatophyta. Methods: Using the LPJ-GM 2.0 model (an extension of LPJ-GUESS), we simulated European vegetation from the end of the Last Glacial Maximum (18.5 ka) to the current time (0 ka). Using biome reconstructions from pollen data as reference, we compared the performance of two dispersal modes: with no migration constraints or seed limitation (free dispersal mode), and with plant establishment depending on seed dynamics and dispersal (dispersal limitation mode). Results: The model run, including migration processes, was better at capturing the post-glacial expansion of European temperate forests (and the longer persistence of boreal forests) than the setting assuming free dispersal, especially during periods of rapid warming. This suggests that a number of (temperate) tree taxa experienced delayed occupancy of climatically suitable habitats due to a limited dispersal capacity, i.e., post-glacial migration lags. Main Conclusions: Our results show that including migration processes in model simulations allows for more realistic reconstructions of forest patterns under rapid climate change, with consequences for future projections of carbon sequestration and climate reconstructions with vegetation feedback, assisted migration and forest conservation.</p>}},
  author       = {{Zani, Deborah and Lischke, Heike and Lehsten, Veiko}},
  issn         = {{0305-0270}},
  keywords     = {{biomization; dispersal limitation; Europe; LPJ-GUESS; migration; paleoclimate; paleovegetation; pollen; vegetation change}},
  language     = {{eng}},
  publisher    = {{Wiley-Blackwell}},
  series       = {{Journal of Biogeography}},
  title        = {{The role of dispersal limitation in the forest biome shifts of Europe in the last 18,000 years}},
  url          = {{http://dx.doi.org/10.1111/jbi.14836}},
  doi          = {{10.1111/jbi.14836}},
  year         = {{2024}},
}