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Birami, Benjamin; Bamberger, Ines; Gast, Andreas; Ruehr, Nadine K (2020): Gas exchange of Aleppo Pine seedlings including emissions of biogenic volatile organic compounds during repeated hetawaves, drought and recovery period [dataset]. PANGAEA, https://doi.org/10.1594/PANGAEA.923768

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Abstract:
The data describes plant gas exchange dynamics (CO2, H2O) together with online proton transfer reaction mass spectrometry measurements of biogenic volatile organic compound emissions of Pinus halepensis seedlings exposed to two similar heatwaves together with drought and a recovery period. Measured in a scientific glasshouse facility at KIT IMK-IFU Garmisch-Partenkirchen, Germany, via an automated chamber setup.
Keyword(s):
BVOC emissions; drought; gas exchange; heatwaves; mortality; Pinus halepensis
Related to:
Birami, Benjamin; Bamberger, Ines; Ghirardo, Andrea; Grote, Rüdiger; Arneth, Almut; Gaona-Colmán, Elizabeth; Nadal-Sala, Daniel; Ruehr, Nadine K (2021): Heatwave frequency and seedling death alter stress-specific emissions of volatile organic compounds in Aleppo pine. Oecologia, https://doi.org/10.1007/s00442-021-04905-y
Birami, Benjamin; Gattmann, Marielle; Heyer, Arnd G; Grote, Rüdiger; Arneth, Almut; Ruehr, Nadine K (2018): Heat Waves Alter Carbon Allocation and Increase Mortality of Aleppo Pine Under Dry Conditions. Frontiers in Forests and Global Change, 1, https://doi.org/10.3389/ffgc.2018.00008
Coverage:
Latitude: 47.475793 * Longitude: 11.062231
Date/Time Start: 2016-04-04T17:36:01 * Date/Time End: 2016-05-30T09:18:43
Event(s):
Aleppo_Pine_seedlings_heat-drought-recovery * Latitude: 47.475793 * Longitude: 11.062231 * Date/Time Start: 2016-04-04T17:36:01 * Date/Time End: 2016-05-30T09:18:43 * Method/Device: Laboratory experiment
Comment:
#0 means "Inf"
Parameter(s):
#NameShort NameUnitPrincipal InvestigatorMethod/DeviceComment
1Day of experimentDOEdayBirami, Benjamin
2DATE/TIMEDate/TimeBirami, BenjaminGeocode
3Water vapour, fluxH2O fluxmmol/m2/sBirami, BenjaminLICOR Gasanalyzer (LI-7000, LI-840), both LI-COR Inc., Lincoln, NE, USA
4Carbon dioxide, fluxCO2 fluxmmol/m2/sBirami, BenjaminLICOR Gasanalyzer (LI-7000, LI-840), both LI-COR Inc., Lincoln, NE, USA
5Temperature, airTTT°CBirami, BenjaminThermocouple (5SC-TTTI-36-2M), Newport Electronics GmbH, Deckenpfronn, Germanyin plant chamber
6Radiation, photosynthetically activePARµmol/m2/sBirami, BenjaminPhotodiode for PAR spectrum (G1118), Hamamatsu Photonics, Hamamatsu, Japanin plant chamber
7Leaf areaLAcm2Birami, BenjaminVisual analysis (photographs)
8Stomatal conductanceStom conductancemmol/m2/sBirami, BenjaminCalculated
9Leaf internal carbon dioxide concentrationCimg/kgBirami, BenjaminCalculated
10Humidity, relativeRH%Birami, BenjaminCalculatedin plant chamber
11Vapour pressure deficitVPDkPaBirami, BenjaminCalculated
12Soil water contentSWC%Birami, BenjaminCalculated from calibrated soil moisture sensors (10HS), Decagon Devices, Inc., WA, USArelative soil water content in plant chamber
13Temperature, soilT soil°CBirami, BenjaminSoil temperature sensor (T107), Campbell Scientific Inc., UT, USAin plant chamber
14PeriodPeriodBirami, Benjamintime period of measurement: 1 before stress, 2 first heat wave, 3 first recovery (dry), 4 second heatwave, 5 second recovery (dry), 6 after stress
15Time of dayTime of dayBirami, Benjamintime of day as number: day=1, night =2
16Day of the yearDOYdayBirami, Benjamin
17Time in hoursTimehBirami, BenjaminHour of day
18Soil water contentSWC%Birami, BenjaminCalculated from calibrated soil moisture sensors (10HS), Decagon Devices, Inc., WA, USArelative soil water content control
19Soil water contentSWC%Birami, BenjaminCalculated from calibrated soil moisture sensors (10HS), Decagon Devices, Inc., WA, USArelative soil water content control-drought
20Soil water contentSWC%Birami, BenjaminCalculated from calibrated soil moisture sensors (10HS), Decagon Devices, Inc., WA, USArelative soil water content heat
21Soil water contentSWC%Birami, BenjaminCalculated from calibrated soil moisture sensors (10HS), Decagon Devices, Inc., WA, USArelative soil water content heat-drought
22Temperature, soilT soil°CBirami, BenjaminSoil temperature sensor (T107), Campbell Scientific Inc., UT, USAcontrol
23Temperature, soilT soil°CBirami, BenjaminSoil temperature sensor (T107), Campbell Scientific Inc., UT, USAcontrol-drought
24Temperature, soilT soil°CBirami, BenjaminSoil temperature sensor (T107), Campbell Scientific Inc., UT, USAheat
25Temperature, soilT soil°CBirami, BenjaminSoil temperature sensor (T107), Campbell Scientific Inc., UT, USAheat-drought
26Radiation, photosynthetically activePARµmol/m2/sBirami, BenjaminHigh-precision PAR sensors (PQS 1), Kipp & Zonen, Delft, the Netherlandsgreenhouse compartment control
27Radiation, photosynthetically activePARµmol/m2/sBirami, BenjaminHigh-precision PAR sensors (PQS 1), Kipp & Zonen, Delft, the Netherlandsgreenhouse compartment heat
28Temperature, airTTT°CBirami, BenjaminAir temperature and relative humidity sensors (CS215), Campbell Scientific Inc., Logan, Utah, US, enclosed in aspirated radiation shields type 43502, Young, Traverse City, MI, USAgreenhouse compartment control
29Temperature, airTTT°CBirami, BenjaminAir temperature and relative humidity sensors (CS215), Campbell Scientific Inc., Logan, Utah, US, enclosed in aspirated radiation shields type 43502, Young, Traverse City, MI, USAgreenhouse compartment heat
30Humidity, relativeRH%Birami, BenjaminAir temperature and relative humidity sensors (CS215), Campbell Scientific Inc., Logan, Utah, US, enclosed in aspirated radiation shields type 43502, Young, Traverse City, MI, USAgreenhouse compartment control
31Humidity, relativeRH%Birami, BenjaminAir temperature and relative humidity sensors (CS215), Campbell Scientific Inc., Logan, Utah, US, enclosed in aspirated radiation shields type 43502, Young, Traverse City, MI, USAgreenhouse compartment heat
32Vapour pressure deficitVPDkPaBirami, BenjaminCalculatedgreenhouse compartment control
33Vapour pressure deficitVPDkPaBirami, BenjaminCalculatedgreenhouse compartment heat
34Flow rateFlow ratel/minBirami, BenjaminMass flow controller (F-201CZ-10K), Bronkhorst, Ruurlo, Netherlandsflow out of the chamber
35Flow rate, molarFlow rate molarmol/sBirami, BenjaminCalculated
36TreatmentTreatBirami, Benjamin
37StatusStatusBirami, Benjamin
38Chamber numberChamber noBirami, Benjamin
39Methanol, fluxCH4O fluxnmol/m2/sBirami, BenjaminProton transfer reaction mass spectrometrym33
40Acetonitrile, fluxC2H3N fluxnmol/m2/sBirami, BenjaminProton transfer reaction mass spectrometrym42
41Acetaldehyde, fluxC2H4O fluxnmol/m2/sBirami, BenjaminProton transfer reaction mass spectrometrym45
42Ethanol, fluxC2H6O fluxnmol/m2/sBirami, BenjaminProton transfer reaction mass spectrometrym47
43Acetone, fluxC3H6O fluxnmol/m2/sBirami, BenjaminProton transfer reaction mass spectrometrym59
44Isoprene, fluxC5H8 fluxnmol/m2/sBirami, BenjaminProton transfer reaction mass spectrometrym69
45Methacrolein + methyl vinyl ketone, fluxMACR+MVK fluxnmol/m2/sBirami, BenjaminProton transfer reaction mass spectrometrym71
46Fragment monoterpenes and fragment leaf wound compounds, fluxFrag monot and frag leaf wound comp fluxnmol/m2/sBirami, BenjaminProton transfer reaction mass spectrometrym81
47Hexenal, fluxC6H10O fluxnmol/m2/sBirami, BenjaminProton transfer reaction mass spectrometrym99, sum of trans and cis
48Monoterpene, fluxMonot fluxnmol/m2/sBirami, BenjaminProton transfer reaction mass spectrometrym137, sum of all monoterpenes
49Methyl salicylate, fluxC8H8O3 fluxnmol/m2/sBirami, BenjaminProton transfer reaction mass spectrometrym153
Change history:
2022-02-07T12:30:00 – All three VPD parameters were corrected. Due to wrong recalculation the value and unit was wrong. A value of e.g. 0.2 hPa was now changed to 2 kPa (= *10 and unit changed to kPa).
License:
Creative Commons Attribution 4.0 International (CC-BY-4.0)
Size:
209691 data points

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