Central European 2018 hot drought shifts scots pine forest to its tipping point

The occurrence of hot drought, i.e. low water availability and simultaneous high air temperature, represents a severe threat to ecosystems. Here, we investigated how the 2018 hot drought in Central Europe caused a tipping point in tree and ecosystem functioning in a Scots pine (Pinus sylvestris L.)...

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Bibliographic Details
Published in:Plant biology (Stuttgart, Germany) Germany), 2022-12, Vol.24 (7), p.1186-1197
Main Authors: Haberstroh, S., Werner, C., Grün, M., Kreuzwieser, J., Seifert, T., Schindler, D., Christen, A.
Format: Article
Language:English
Subjects:
Air temperature
Assimilation
BVOC
Carbon
Carbon sources
Coniferous forests
Defoliation
Drought
Ecosystem recovery
Ecosystems
Emissions
Environmental impact
Forests
leaf water potential
Mortality
NDVI
Net ecosystem exchange
Normalized difference vegetative index
Organic compounds
Pine
Pine needles
Pine trees
Pinus sylvestris
Recovery
Trees
Vegetation
VOCs
Volatile organic compounds
Water availability
Water potential
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Summary:The occurrence of hot drought, i.e. low water availability and simultaneous high air temperature, represents a severe threat to ecosystems. Here, we investigated how the 2018 hot drought in Central Europe caused a tipping point in tree and ecosystem functioning in a Scots pine (Pinus sylvestris L.) forest in southwest Germany. Measurements of stress indicators, such as needle water potential, carbon assimilation and volatile organic compound (VOC) emissions, of dominant P. sylvestris trees were deployed to evaluate tree functioning during hot drought. Ecosystem impact and recovery were assessed as ecosystem carbon exchange, normalized difference vegetation index (NDVI) from satellite data and tree mortality data. During summer 2018, needle water potentials of trees dropped to minimum values of −7.5 ± 0.2 MPa, which implied severe hydraulic impairment of P. sylvestris. Likewise, carbon assimilation and VOC emissions strongly declined after mid‐July. Decreasing NDVI values from August 2018 onwards were detected, along with severe defoliation in P. sylvestris, impairing ecosystem carbon flux recovery in 2019, shifting the forest into a year‐round carbon source. A total of 47% of all monitored trees (n = 368) died by September 2020. NDVI recovered to pre‐2018 levels in 2019, likely caused by emerging broadleaved understorey species. The 2018 hot drought had severe negative impacts on P. sylvestris. The co‐occurrence of unfavourable site‐specific conditions with recurrent severe droughts resulted in accelerated mortality. Thus, the 2018 hot drought pushed the P. sylvestris stand towards its tipping point, with a subsequent vegetation shift to a broadleaf‐dominated forest. The 2018 hot drought severely impaired hydraulic functionality in a Scots Pine forest, causing accelerated tree mortality rates, which ultimately led to a tipping point for the ecosystem.
ISSN:1435-8603
1438-8677
DOI:10.1111/plb.13455