Temperature and Tree Size Explain the Mean Time to Fall of Dead Standing Trees across Large Scales
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Temperature and Tree Size Explain the Mean Time to Fall of Dead Standing Trees across Large Scales. / Gärtner, Antje; Jönsson, Anna Maria; Metcalfe, Daniel B.; Pugh, Thomas A.M.; Tagesson, Torbern; Ahlström, Anders.
In: Forests, Vol. 14, No. 5, 1017, 2023.Research output: Contribution to journal › Journal article › Research › peer-review
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TY - JOUR
T1 - Temperature and Tree Size Explain the Mean Time to Fall of Dead Standing Trees across Large Scales
AU - Gärtner, Antje
AU - Jönsson, Anna Maria
AU - Metcalfe, Daniel B.
AU - Pugh, Thomas A.M.
AU - Tagesson, Torbern
AU - Ahlström, Anders
N1 - Publisher Copyright: © 2023 by the authors.
PY - 2023
Y1 - 2023
N2 - Dead standing trees (DSTs) generally decompose slower than wood in contact with the forest floor. In many regions, DSTs are being created at an increasing rate due to accelerating tree mortality caused by climate change. Therefore, factors determining DST fall are crucial for predicting dead wood turnover time but remain poorly constrained. Here, we conduct a re-analysis of published DST fall data to provide standardized information on the mean time to fall (MTF) of DSTs across biomes. We used multiple linear regression to test covariates considered important for DST fall, while controlling for mortality and management effects. DSTs of species killed by fire, insects and other causes stood on average for 48, 13 and 19 years, but MTF calculations were sensitive to how tree size was accounted for. Species’ MTFs differed significantly between DSTs killed by fire and other causes, between coniferous and broadleaved plant functional types (PFTs) and between managed and unmanaged sites, but management did not explain MTFs when we distinguished by mortality cause. Mean annual temperature (MAT) negatively affected MTFs, whereas larger tree size or being coniferous caused DSTs to stand longer. The most important explanatory variables were MAT and tree size, with minor contributions of management and plant functional type depending on mortality cause. Our results provide a basis to improve the representation of dead wood decomposition in carbon cycle assessments.
AB - Dead standing trees (DSTs) generally decompose slower than wood in contact with the forest floor. In many regions, DSTs are being created at an increasing rate due to accelerating tree mortality caused by climate change. Therefore, factors determining DST fall are crucial for predicting dead wood turnover time but remain poorly constrained. Here, we conduct a re-analysis of published DST fall data to provide standardized information on the mean time to fall (MTF) of DSTs across biomes. We used multiple linear regression to test covariates considered important for DST fall, while controlling for mortality and management effects. DSTs of species killed by fire, insects and other causes stood on average for 48, 13 and 19 years, but MTF calculations were sensitive to how tree size was accounted for. Species’ MTFs differed significantly between DSTs killed by fire and other causes, between coniferous and broadleaved plant functional types (PFTs) and between managed and unmanaged sites, but management did not explain MTFs when we distinguished by mortality cause. Mean annual temperature (MAT) negatively affected MTFs, whereas larger tree size or being coniferous caused DSTs to stand longer. The most important explanatory variables were MAT and tree size, with minor contributions of management and plant functional type depending on mortality cause. Our results provide a basis to improve the representation of dead wood decomposition in carbon cycle assessments.
KW - literature review
KW - re-analysis
KW - snag fall
KW - standing dead wood
KW - woody decomposition
U2 - 10.3390/f14051017
DO - 10.3390/f14051017
M3 - Journal article
AN - SCOPUS:85160696452
VL - 14
JO - Forests
JF - Forests
SN - 1999-4907
IS - 5
M1 - 1017
ER -
ID: 357515751