6533b837fe1ef96bd12a1d94
RESEARCH PRODUCT
Water-use efficiency and transpiration across European forests during the Anthropocene
M. Kalela-brundinNicolas ViovyBenjamin PoulterEmilia GutiérrezKatja T. RinneH. MarahMarkus LeuenbergerKerstin TreydteZ. BednarzMark R. LomasEmmi HilasvuoriNiklaus E. ZimmermannPhilippe CiaisJohn S. WaterhouseGerhard H. SchleserDavid FrankStephen SitchElżbieta Szychowska‐kra̧piecLaia Andreu-haylesSamuel LevisAnna PazdurMichael GrabnerTatjana BoettgerGerhard HelleCarmela Miriam D’alessandroMonique PierreHögne JungnerV. R. SwitsurM. FilotMatthias SaurerEloni SonninenPierre FriedlingsteinMarek KrapiecM. SzczepanekC. E. Reynolds-henneOctavi PlanellsValérie DauxFrank BerningerChris HuntingfordLuigi TodaroAnders AhlströmValérie Masson-delmotteJan EsperSławomira PawełczykMarika HauptNeil J. LoaderMartin WeiglMichel StievenardAntonio SaracinoR. Pukienesubject
hiilidioksidiStomatal conductancehiili[SDE.MCG]Environmental Sciences/Global Changesta1171vesiGrowing seasonClimate changeEnvironmental Science (miscellaneous)Atmospheric sciencestree-ringchemistry.chemical_compoundhydrologinen kiertodioxide[SDV.EE.ECO]Life Sciences [q-bio]/Ecology environment/Ecosystems[SDU.STU.GC]Sciences of the Universe [physics]/Earth Sciences/GeochemistrykasvitilmastoWater cycleWater-use efficiency[SDU.ENVI]Sciences of the Universe [physics]/Continental interfaces environmentclimateCO2 fertilizationComputingMilieux_MISCELLANEOUSTranspirationHydrologyilmakehäatmospheric CO2elevated CO2[CHIM.ORGA]Chemical Sciences/Organic chemistryGlobal warmingvarastointi15. Life on land[SDE.ES]Environmental Sciences/Environmental and Societygas-exchangerising CO2chemistry13. Climate actionstomatal conductance[SDU.STU.CL]Sciences of the Universe [physics]/Earth Sciences/Climatology[SDU.STU.ST]Sciences of the Universe [physics]/Earth Sciences/Stratigraphy[SHS.ENVIR]Humanities and Social Sciences/Environmental studiesCarbon dioxideEnvironmental scienceaineiden kiertoSocial Sciences (miscellaneous)carbon-isotope discriminationdescription
Considering the combined effects of CO2 fertilization and climate change drivers on plant physiology leads to a modest increase in simulated European forest transpiration in spite of the effects of CO2-induced stomatal closure. The Earth’s carbon and hydrologic cycles are intimately coupled by gas exchange through plant stomata1,2,3. However, uncertainties in the magnitude4,5,6 and consequences7,8 of the physiological responses9,10 of plants to elevated CO2 in natural environments hinders modelling of terrestrial water cycling and carbon storage11. Here we use annually resolved long-term δ13C tree-ring measurements across a European forest network to reconstruct the physiologically driven response of intercellular CO2 (Ci) caused by atmospheric CO2 (Ca) trends. When removing meteorological signals from the δ13C measurements, we find that trees across Europe regulated gas exchange so that for one ppmv atmospheric CO2 increase, Ci increased by ∼0.76 ppmv, most consistent with moderate control towards a constant Ci/Ca ratio. This response corresponds to twentieth-century intrinsic water-use efficiency (iWUE) increases of 14 ± 10 and 22 ± 6% at broadleaf and coniferous sites, respectively. An ensemble of process-based global vegetation models shows similar CO2 effects on iWUE trends. Yet, when operating these models with climate drivers reintroduced, despite decreased stomatal opening, 5% increases in European forest transpiration are calculated over the twentieth century. This counterintuitive result arises from lengthened growing seasons, enhanced evaporative demand in a warming climate, and increased leaf area, which together oppose effects of CO2-induced stomatal closure. Our study questions changes to the hydrological cycle, such as reductions in transpiration and air humidity, hypothesized to result from plant responses to anthropogenic emissions.
| year | journal | country | edition | language |
|---|---|---|---|---|
| 2015-06-01 |