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Exploring Populus phenological response to climate change using observational data and ecosystem modelling

Svystun, Tetiana LU and Jönsson, Anna Maria LU (2022) In Agricultural and Forest Meteorology 314.
Abstract

The length of the growing season for deciduous trees in temperate and boreal forests is determined by the timing of bud burst and autumn senescence. It is generally assumed that a warmer climate leads to a longer growing season due to earlier bud burst and delayed autumn senescence and thereby increased gross primary production (GPP) of forests. In this study, we analysed past (1873–1951) and current (2008–2020) phenological observations on bud burst and senescence from aspen trees (Populus tremula) grown in Sweden. The observations indicated a reduction in temperature sensitivity of bud burst between the time periods, likely associated with warmer winters and reduced exposure to chilling. The phenological observations were used in the... (More)

The length of the growing season for deciduous trees in temperate and boreal forests is determined by the timing of bud burst and autumn senescence. It is generally assumed that a warmer climate leads to a longer growing season due to earlier bud burst and delayed autumn senescence and thereby increased gross primary production (GPP) of forests. In this study, we analysed past (1873–1951) and current (2008–2020) phenological observations on bud burst and senescence from aspen trees (Populus tremula) grown in Sweden. The observations indicated a reduction in temperature sensitivity of bud burst between the time periods, likely associated with warmer winters and reduced exposure to chilling. The phenological observations were used in the evaluation of an ecosystem model. Biases in modelling spring and autumn leaf cover development influenced the seasonal and annual GPP estimates. The overestimation of the modelled GPP was more pronounced in spring than in autumn, reflecting the GPP limitations by leaf cover development in spring, and by daylength and temperature conditions in autumn. Calibration of the spring phenology parameters, using the accumulated temperature sums and chilling days at the observed timing of bud burst, significantly improved model performance compared to the original parameterisation. The calibrated ecosystem model projections representing RCP8.5 suggested 15 days earlier timing of bud burst and enhanced mean annual GPP by the end of the century compared with current climate conditions in Sweden.

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publication status
published
subject
keywords
Ecosystem model, Gross primary production, Growing season length, Leaf cover development, Phenology parameterization, Temperature response
in
Agricultural and Forest Meteorology
volume
314
article number
108766
publisher
Elsevier
external identifiers
  • scopus:85121302346
ISSN
0168-1923
DOI
10.1016/j.agrformet.2021.108766
language
English
LU publication?
yes
additional info
Publisher Copyright: © 2021
id
1564221d-916b-48c3-8f62-6f217ea77457
date added to LUP
2022-01-11 17:24:03
date last changed
2022-04-27 07:06:17
@article{1564221d-916b-48c3-8f62-6f217ea77457,
  abstract     = {{<p>The length of the growing season for deciduous trees in temperate and boreal forests is determined by the timing of bud burst and autumn senescence. It is generally assumed that a warmer climate leads to a longer growing season due to earlier bud burst and delayed autumn senescence and thereby increased gross primary production (GPP) of forests. In this study, we analysed past (1873–1951) and current (2008–2020) phenological observations on bud burst and senescence from aspen trees (Populus tremula) grown in Sweden. The observations indicated a reduction in temperature sensitivity of bud burst between the time periods, likely associated with warmer winters and reduced exposure to chilling. The phenological observations were used in the evaluation of an ecosystem model. Biases in modelling spring and autumn leaf cover development influenced the seasonal and annual GPP estimates. The overestimation of the modelled GPP was more pronounced in spring than in autumn, reflecting the GPP limitations by leaf cover development in spring, and by daylength and temperature conditions in autumn. Calibration of the spring phenology parameters, using the accumulated temperature sums and chilling days at the observed timing of bud burst, significantly improved model performance compared to the original parameterisation. The calibrated ecosystem model projections representing RCP8.5 suggested 15 days earlier timing of bud burst and enhanced mean annual GPP by the end of the century compared with current climate conditions in Sweden.</p>}},
  author       = {{Svystun, Tetiana and Jönsson, Anna Maria}},
  issn         = {{0168-1923}},
  keywords     = {{Ecosystem model; Gross primary production; Growing season length; Leaf cover development; Phenology parameterization; Temperature response}},
  language     = {{eng}},
  month        = {{03}},
  publisher    = {{Elsevier}},
  series       = {{Agricultural and Forest Meteorology}},
  title        = {{Exploring Populus phenological response to climate change using observational data and ecosystem modelling}},
  url          = {{http://dx.doi.org/10.1016/j.agrformet.2021.108766}},
  doi          = {{10.1016/j.agrformet.2021.108766}},
  volume       = {{314}},
  year         = {{2022}},
}