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Nitrogen restricts future sub-Arctic treeline advance in an individual-based dynamic vegetation model

Gustafson, Adrian LU ; Miller, Paul A. LU ; Björk, Robert G. ; Olin, Stefan LU and Smith, Benjamin LU (2021) In Biogeosciences 18(23). p.6329-6347
Abstract

Arctic environmental change induces shifts in high-latitude plant community composition and stature with implications for Arctic carbon cycling and energy exchange. Two major components of change in high-latitude ecosystems are the advancement of trees into tundra and the increased abundance and size of shrubs. How future changes in key climatic and environmental drivers will affect distributions of major ecosystem types is an active area of research. Dynamic vegetation models (DVMs) offer a way to investigate multiple and interacting drivers of vegetation distribution and ecosystem function. We employed the LPJ-GUESS tree-individual-based DVM over the Torneträsk area, a sub-Arctic landscape in northern Sweden. Using a highly resolved... (More)

Arctic environmental change induces shifts in high-latitude plant community composition and stature with implications for Arctic carbon cycling and energy exchange. Two major components of change in high-latitude ecosystems are the advancement of trees into tundra and the increased abundance and size of shrubs. How future changes in key climatic and environmental drivers will affect distributions of major ecosystem types is an active area of research. Dynamic vegetation models (DVMs) offer a way to investigate multiple and interacting drivers of vegetation distribution and ecosystem function. We employed the LPJ-GUESS tree-individual-based DVM over the Torneträsk area, a sub-Arctic landscape in northern Sweden. Using a highly resolved climate dataset to downscale CMIP5 climate data from three global climate models and two 21st-century future scenarios (RCP2.6 and RCP8.5), we investigated future impacts of climate change on these ecosystems. We also performed model experiments where we factorially varied drivers (climate, nitrogen deposition and [CO2]) to disentangle the effects of each on ecosystem properties and functions. Our model predicted that treelines could advance by between 45 and 195 elevational metres by 2100, depending on the scenario. Temperature was a strong driver of vegetation change, with nitrogen availability identified as an important modulator of treeline advance. While increased CO2 fertilisation drove productivity increases, it did not result in range shifts of trees. Treeline advance was realistically simulated without any temperature dependence on growth, but biomass was overestimated. Our finding that nitrogen cycling could modulate treeline advance underlines the importance of representing plant-soil interactions in models to project future Arctic vegetation change.

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author
; ; ; and
organization
publishing date
type
Contribution to journal
publication status
published
subject
in
Biogeosciences
volume
18
issue
23
pages
19 pages
publisher
Copernicus GmbH
external identifiers
  • scopus:85121669421
ISSN
1726-4170
DOI
10.5194/bg-18-6329-2021
project
BioDiv-Support: Scenario-based decision support for policy planning and adaptation to future changes in biodiversity and ecosystem services
language
English
LU publication?
yes
additional info
Publisher Copyright: © Copyright:
id
b1477aca-0b5d-4702-8881-82ee230e674b
date added to LUP
2022-01-28 09:29:43
date last changed
2023-03-08 04:42:18
@article{b1477aca-0b5d-4702-8881-82ee230e674b,
  abstract     = {{<p>Arctic environmental change induces shifts in high-latitude plant community composition and stature with implications for Arctic carbon cycling and energy exchange. Two major components of change in high-latitude ecosystems are the advancement of trees into tundra and the increased abundance and size of shrubs. How future changes in key climatic and environmental drivers will affect distributions of major ecosystem types is an active area of research. Dynamic vegetation models (DVMs) offer a way to investigate multiple and interacting drivers of vegetation distribution and ecosystem function. We employed the LPJ-GUESS tree-individual-based DVM over the Torneträsk area, a sub-Arctic landscape in northern Sweden. Using a highly resolved climate dataset to downscale CMIP5 climate data from three global climate models and two 21st-century future scenarios (RCP2.6 and RCP8.5), we investigated future impacts of climate change on these ecosystems. We also performed model experiments where we factorially varied drivers (climate, nitrogen deposition and [CO2]) to disentangle the effects of each on ecosystem properties and functions. Our model predicted that treelines could advance by between 45 and 195 elevational metres by 2100, depending on the scenario. Temperature was a strong driver of vegetation change, with nitrogen availability identified as an important modulator of treeline advance. While increased CO2 fertilisation drove productivity increases, it did not result in range shifts of trees. Treeline advance was realistically simulated without any temperature dependence on growth, but biomass was overestimated. Our finding that nitrogen cycling could modulate treeline advance underlines the importance of representing plant-soil interactions in models to project future Arctic vegetation change. </p>}},
  author       = {{Gustafson, Adrian and Miller, Paul A. and Björk, Robert G. and Olin, Stefan and Smith, Benjamin}},
  issn         = {{1726-4170}},
  language     = {{eng}},
  month        = {{12}},
  number       = {{23}},
  pages        = {{6329--6347}},
  publisher    = {{Copernicus GmbH}},
  series       = {{Biogeosciences}},
  title        = {{Nitrogen restricts future sub-Arctic treeline advance in an individual-based dynamic vegetation model}},
  url          = {{http://dx.doi.org/10.5194/bg-18-6329-2021}},
  doi          = {{10.5194/bg-18-6329-2021}},
  volume       = {{18}},
  year         = {{2021}},
}