Sap flow and leaf gas exchange response to a drought and heatwave in urban green spaces in a Nordic city

Urban vegetation plays a role in offsetting urban CO2 emissions, mitigating heat through tree transpiration and shading, and acting as deposition surfaces for pollutants. The frequent occurrence of heatwaves and of concurrent drought conditions significantly disrupts the processes of urban trees, pa...

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Bibliographic Details
Published in:Biogeosciences 2023-11, Vol.20 (21), p.4455-4475
Main Authors: Ahongshangbam, Joyson, Kulmala, Liisa, Soininen, Jesse, Frühauf, Yasmin, Karvinen, Esko, Salmon, Yann, Lintunen, Anna, Karvonen, Anni, Järvi, Leena
Format: Article
Language:English
Subjects:
Carbon
Carbon dioxide
Carbon dioxide emissions
Cities
Climate change
Cooling
Drought
Drought conditions
Drought periods
Droughts
Dry periods
Ecosystem services
Emissions
Evapotranspiration
Flux density
Forests
Gas exchange
Green infrastructure
Heat
Heat waves
Heatwaves
Leaves
Mayors
Moisture content
Open spaces
Photosynthesis
Plant species
Pollutant deposition
Sap
Shading
Soil water
Stomata
Stomatal conductance
Streets
Summer
Temperature
Transpiration
Trees
Urban areas
Urban planning
Vapor pressure
Vapour pressure
Vegetation
Water availability
Water shortages
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Summary:Urban vegetation plays a role in offsetting urban CO2 emissions, mitigating heat through tree transpiration and shading, and acting as deposition surfaces for pollutants. The frequent occurrence of heatwaves and of concurrent drought conditions significantly disrupts the processes of urban trees, particularly their photosynthesis and transpiration rates. Despite the pivotal role of urban tree functioning in delivering essential ecosystem services, the precise nature of their response remains uncertain. We conducted sap flux density (Js) and leaf gas exchange measurements of four tree species (Tilia cordata, Tilia × europaea, Betula pendula, and Malus spp.) located in different urban green areas (Park, Street, Forest, and Orchard) in Helsinki, Finland. Measurements were made over two contrasting summers 2020 and 2021. Summer 2021 experienced a local heatwave and drought, whereas summer 2020 was more typical of Helsinki. In this study, we aimed to understand the responses of urban tree transpiration (measured with sap flux density) and leaf gas exchange to heatwave and drought conditions, and we examined the main environmental drivers controlling the tree transpiration rate during these periods. We observed varying responses of Js during the heatwave period at the four urban sites. When comparing the heatwave and no heatwave periods, a 35 %–67 % increase in Js was observed at the Park, Forest, and Orchard locations, whereas no significant change was seen at the Street site. Our results also showed that Js was higher (31 %–63 %) at all sites under drought conditions compared with non-dry periods. The higher Js values during the heatwave and dry periods were mainly driven by the high atmospheric demand for evapotranspiration, represented by the high vapor pressure deficit (VPD), suggesting that the trees were not experiencing severe enough heat or drought stress that stomatal control would have decreased transpiration. Accordingly, photosynthetic potential (Amax), stomatal conductance (gs), and transpiration (E) at the leaf level did not change during heatwave and drought periods, excluding the Park site where a significant reduction in gs was seen. VPD explained 55 %–69 % of the variation in the daily mean Js during heatwave and drought periods at all sites. At the Forest site, the increase in Js saturated after a certain VPD level, likely due to low soil water availability during these hot and dry periods. Overall, the heat and drought conditions were untypi
ISSN:1726-4189
1726-4170
1726-4189
DOI:10.5194/bg-20-4455-2023