Annual ring growth of a widespread high arctic shrub reflects past fluctuations in community-level plant biomass

Mathilde Le Moullec (Corresponding Author), Agata Buchwal, René Wal, Lisa Sandal, Brage Bremset Hansen

Research output: Contribution to journalArticle

4 Citations (Scopus)

Abstract

Abstract Long time series of primary production are rarely available, restricting our mechanistic understanding of vegetation and ecosystem dynamics under climate change. Dendrochronological tools are increasingly used instead, particularly in the Arctic?the world?s most rapidly warming biome. Yet, high-latitude plant species are subject to strong energy allocation trade-offs, and whether annual allocations to secondary growth (e.g. ?tree-rings?) actually reflect primary production above-ground remains unknown. Taking advantage of a unique ground-based monitoring time series of annual vascular plant biomass in high Arctic Svalbard (78°N), we evaluated how well retrospective ring growth of the widespread dwarf shrub Salix polaris represents above-ground biomass production of vascular plants. Using a balanced design in permanent plots for plant biomass monitoring, we collected 30 S. polaris shrubs across five sites in each of two habitats. We established annual ring growth time series using linear mixed-effects models and related them to weather records and 13 years of above-ground biomass production in six habitats. Annual ring growth was positively correlated with above-ground biomass production of both S. polaris (r = 0.56) and the vascular plant community as a whole (r = 0.70). As for above-ground biomass, summer temperature was the main driver of ring growth, with this ecological signal becoming particularly clear when accounting for plant, site and habitat heterogeneity. The results suggest that ring growth measurements performed on this abundant shrub can be used to track fluctuations in past vascular plant production of high arctic tundra. Synthesis. Dendrochronological tools are increasingly used on arctic shrubs to enhance our understanding of vegetation dynamics in the world?s most rapidly warming biome. Fundamental to such applications is the assumption that annual differences in ring growth reflect between-year variation in above-ground biomass production. We showed that ring growth indeed was a robust proxy for the annual above-ground productivity of both the focal shrub and the vascular plant community as a whole. Despite the challenges of constructing ring growth chronologies from irregularly growing arctic shrubs, our findings confirm that shrub dendrochronology can open new opportunities for community-dynamic studies, including in remote places where annual field sampling is difficult to achieve.
Original languageEnglish
Pages (from-to)436-451
Number of pages16
JournalJournal of Ecology
Volume107
Issue number1
Early online date14 Aug 2018
DOIs
Publication statusPublished - Jan 2019

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growth rings
Arctic region
shrub
shrubs
aboveground biomass
vascular plant
biomass
vascular plants
biomass production
time series analysis
vegetation dynamics
time series
biome
primary production
ecosystems
primary productivity
plant community
plant communities
habitat
warming

Keywords

  • dendrochronology
  • permanent plots
  • plant population and community dynamics
  • polar willow
  • Salix polaris
  • secondary growth
  • Svalbard
  • temperature
  • tundra ecosystem
  • vegetation production

ASJC Scopus subject areas

  • Ecology, Evolution, Behavior and Systematics
  • Plant Science
  • Ecology

Cite this

Annual ring growth of a widespread high arctic shrub reflects past fluctuations in community-level plant biomass. / Le Moullec, Mathilde (Corresponding Author); Buchwal, Agata; Wal, René; Sandal, Lisa; Hansen, Brage Bremset.

In: Journal of Ecology, Vol. 107, No. 1, 01.2019, p. 436-451.

Research output: Contribution to journalArticle

Le Moullec, Mathilde ; Buchwal, Agata ; Wal, René ; Sandal, Lisa ; Hansen, Brage Bremset. / Annual ring growth of a widespread high arctic shrub reflects past fluctuations in community-level plant biomass. In: Journal of Ecology. 2019 ; Vol. 107, No. 1. pp. 436-451.
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