Variability in Tree-ring Width and NDVI Responses to Climate at a Landscape Level

Inter-annual climatically driven growth variability of above-ground biomass compartments (for example, tree stems and foliage) controls the intensity of carbon sequestration into forest ecosystems. However, understanding the differences between the climatic response of stem and foliage at the landsc...

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Bibliographic Details
Published in:Ecosystems (New York) 2023-08, Vol.26 (5), p.1144-1157
Main Authors: Mašek, Jiří, Tumajer, Jan, Lange, Jelena, Kaczka, Ryszard, Fišer, Petr, Treml, Václav
Format: Article
Language:English
Subjects:
Biomass
Biomedical and Life Sciences
Carbon sequestration
Climate change
Climatic changes
Compartments
Dendrochronology
Dendroclimatology
Earth resources technology satellites
Ecology
Ecosystems
Environmental Management
Foliage
Forest ecosystems
Geoecology/Natural Processes
Hydrology/Water Resources
Landsat
Landscape
Leaves
Life Sciences
Moisture effects
Normalized difference vegetative index
Pine trees
Plant Sciences
Remote sensing
Stems
Terrestrial ecosystems
Topography
Tree rings
Variability
Zoology
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Summary:Inter-annual climatically driven growth variability of above-ground biomass compartments (for example, tree stems and foliage) controls the intensity of carbon sequestration into forest ecosystems. However, understanding the differences between the climatic response of stem and foliage at the landscape level is limited. In this study, we examined the climate-growth response of stem and leaf biomass and their relationship for Pinus sylvestris (PISY) and Picea abies (PCAB) in topographically complex landscapes. We used tree-ring width chronologies and time series of the normalized difference vegetation index (NDVI) derived from high-resolution Landsat scenes as proxies for stem and leaf biomass, respectively. We then compared growth variability and climate-growth relationships of both biomass proxies between topographical categories. Our results show that the responses of tree rings to climate differ significantly from those found in NDVI, with the stronger climatic signal observed in tree rings. Topography had distinct but species-specific effects: At moisture-limited PISY stands, stem biomass (tree rings) was strongly topographically driven, and leaf biomass (NDVI) was relatively insensitive to topographic variability. In landscapes close to the climatic optimum of PCAB, the relationship between stem and leaf biomass was weak, and their correlations with climate were often inverse, with no significant effects of topography. Different climatic signals from NDVI and tree rings suggest that the response of canopy and stem growth to climate change might be decoupled. Furthermore, our results hint toward different prioritizations of biomass allocation in trees under stressful conditions which might change allometric relationships between individual tree compartments in the long term.
ISSN:1432-9840
1435-0629
DOI:10.1007/s10021-023-00822-8