Disjunct eddy covariance measurements of oxygenated volatile organic compounds fluxes from an alfalfa field before and after cutting

Warneke, C.; Luxembourg, S.L.; Gouw, J. A. de; Rinne, Janne; Guenther, Alex; Fall, Ray

doi:10.1029/2001jd000594

Cited by 113 publications

(115 citation statements)

References 39 publications

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“…Normalized isoprene and monoterpene emissions revealed similar responses to the diel course of light intensity in all temperature regimes. Methanol, however, showed emission pulses after the onset of illumination, as has been observed previously for different plant species both in field and laboratory experiments under controlled conditions (Folkers et al, 2008;Warneke et al, 2002;Nemecek-Marshall et al, 1995). Morning pulses of methanol emissions were explained as a consequence of accumulation in extracellular water of the plant's apoplast when stomata are closed during nighttime (Niinemets and Reichstein, 2003).…”

Section: Light-and Temperature-dependent Plant Emissionsmentioning

confidence: 66%

A new plant chamber facility, PLUS, coupled to the atmosphere simulation chamber SAPHIR

Hohaus¹,

Kühn

Andres³

et al. 2016

Atmos. Meas. Tech.

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Abstract. A new PLant chamber Unit for Simulation (PLUS)for use with the atmosphere simulation chamber SAPHIR (Simulation of Atmospheric PHotochemistry In a large Reaction Chamber) has been built and characterized at the Forschungszentrum Jülich GmbH, Germany. The PLUS chamber is an environmentally controlled flow-through plant chamber. Inside PLUS the natural blend of biogenic emissions of trees is mixed with synthetic air and transferred to the SAPHIR chamber, where the atmospheric chemistry and the impact of biogenic volatile organic compounds (BVOCs) can be studied in detail. In PLUS all important environmental parameters (e.g., temperature, photosynthetically active radiation (PAR), soil relative humidity (RH)) are well controlled. The gas exchange volume of 9.32 m 3 which encloses the stem and the leaves of the plants is constructed such that gases are exposed to only fluorinated ethylene propylene (FEP) Teflon film and other Teflon surfaces to minimize any potential losses of BVOCs in the chamber. Solar radiation is simulated using 15 light-emitting diode (LED) panels, which have an emission strength up to 800 µmol m −2 s −1 . Results of the initial characterization experiments are presented in detail. Background concentrations, mixing inside the gas exchange volume, and transfer rate of volatile organic compounds (VOCs) through PLUS under different humidity conditions are explored. Typical plant characteristics such as light-and temperature-dependent BVOC emissions are studied using six Quercus ilex trees and compared to previous studies. Results of an initial ozonolysis experiment of BVOC emissions from Quercus ilex at typical atmospheric concentrations inside SAPHIR are presented to demonstrate a typical experimental setup and the utility of the newly added plant chamber.

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Section: Light-and Temperature-dependent Plant Emissionsmentioning

confidence: 66%

A new plant chamber facility, PLUS, coupled to the atmosphere simulation chamber SAPHIR

Hohaus¹,

Kühn

Andres³

et al. 2016

Atmos. Meas. Tech.

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“…The lower emission rates for tropical broadleaf forests are based on recent measurements indicating lower emissions for these landscapes (Karl et al, 2007;Langford et al, 2010). The few measurements reported for croplands include methanol emission fluxes of alfalfa (Warneke et al, 2002) that are much higher than the forest values, and emission fluxes from ryegrass (Schade and Custer, 2004), that are much lower. Since the MEGAN landcover data do not distinguish between high and low emission crops, the value used for forests is currently used for all crops.…”

Section: T Stavrakou Et Al: Global Methanol Emission Fluxes Deducedmentioning

confidence: 99%

“…These emission factors are based on whole ecosystem net methanol flux measurements reported by 17 studies that characterized various ecosystems including tropical forest (Geron et al, 2002;Karl et al, 2004Karl et al, , 2007Langford et al, 2010), warm conifer forest (Karl et al, 2005), cool temperate conifer forest (Schade and Goldstein, 2001;Baker et al, 2001;Karl et al, 2002), temperate broadleaf forest and plantation (Spirig et al, 2005;Karl et al, 2003a;Jardine et al, 2008), boreal forest (Rinne et al, 2007), croplands (Warneke et al, 2002;Schade and Custer, 2004) and grassland (Kirstine et al, 1998;Fukui and Doskey, 1998;Ruuskanen et al, 2010). Among these studies, Kirstine et al (1998) and Fukui and Doskey (1998) have used whole ecosystem enclosure techniques with gas chromatography analysis to quantify emissions from grasslands, Schade and Goldstein (2001), Baker et al (2001) and Geron et al (2002) used above canopy relaxed eddy accumulation with gas chromatography analysis to measure methanol fluxes above forests, whereas all the other studies used protontransfer reaction mass spectroscopy (PTR-MS) and the eddy covariance, or disjunct eddy covariance, approach (see Karl et al, 2002).…”

Section: The Meganv21 Algorithmmentioning

confidence: 99%

First space-based derivation of the global atmospheric methanol emission fluxes

et al. 2011

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Abstract. This study provides improved methanol emission estimates on the global scale, in particular for the largest methanol source, the terrestrial biosphere, and for biomass burning. To this purpose, one complete year of spaceborne measurements of tropospheric methanol columns retrieved for the first time by the thermal infrared sensor IASI aboard the MetOp satellite are compared with distributions calculated by the IMAGESv2 global chemistry-transport model. Two model simulations are performed using a priori biogenic methanol emissions either from the new MEGANv2.1 emission model, which is fully described in this work and is based on net ecosystem flux measurements, or from a previous parameterization based on net primary production by Jacob et al. (2005). A significantly better model performance in terms of both amplitude and seasonality is achieved through the use of MEGANv2.1 in most world regions, with respect to IASI data, and to surface-and air-based methanol measurements, even though important discrepancies over several regions are still present. As a second step of this study, we combine the MEGANv2.1 and the IASI column abundances over continents in an inverse modelling scheme based on the adjoint of the IMAGESv2 model to generate an improved global methanol emission source. The global optimized source totals 187 Tg yr −1 with a contribution of 100 Tg yr −1 from plants, only slightly lower than the a priori Correspondence to: T. Stavrakou (jenny@aeronomie.be) MEGANv2.1 value of 105 Tg yr −1 . Large decreases with respect to the MEGANv2.1 biogenic source are inferred over Amazonia (up to 55 %) and Indonesia (up to 58 %), whereas more moderate reductions are recorded in the Eastern US (20-25 %) and Central Africa (25-35 %). On the other hand, the biogenic source is found to strongly increase in the arid and semi-arid regions of Central Asia (up to a factor of 5) and Western US (factor of 2), probably due to a source of methanol specific to these ecosystems which is unaccounted for in the MEGANv2.1 inventory. The most significant error reductions achieved by the optimization concern the derived biogenic emissions over the Amazon and over the Former Soviet Union. The robustness of the derived fluxes to changes in convective updraft fluxes, in methanol removal processes, and in the choice of the biogenic a priori inventory is assessed through sensitivity inversions. Detailed comparisons of the model with a number of aircraft and surface observations of methanol, as well as new methanol measurements in Europe and in the Reunion Island show that the satellite-derived methanol emissions improve significantly the agreement with the independent data, giving thus credence to the IASI dataset.

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“…Grasslands cover one quarter of the earth's land surface (Graedel and Crutzen, 1993). Apart from studies concerning the methanol emissions due to harvesting (De Gouw et al, 1999;Karl et al, 2001;Warneke et al, 2002) only few long-term flux studies exist for grassland (Kirstine et al, 1998;Fukui and Doskey, 1998). These are based on chamber measurements characterised by a low time resolution.…”

Section: Introductionmentioning

confidence: 99%

“…In addition, senescing, injuring (e.g. herbivore attacks, cutting) and drying of plant leaves as well as biomass burning are known to be sources of methanol (de Gouw et al, 1999;Warneke et al, 2002;Loreto et al, 2006;Holzinger et al, 1999 and. The major removal processes for methanol are oxidation by OH radicals (in the gas and the aqueous phase; Monod et al, 2000) as well as dry and wet deposition (Heikes et al, 2002;Galbally and Kirstine, 2002;Jacob et al, 2005).…”

Section: Introductionmentioning

confidence: 99%

Methanol exchange between grassland and the atmosphere

et al. 2007

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Abstract. Concentrations and fluxes of methanol were measured above two differently managed grassland fields (intensive and extensive) in central Switzerland during summer 2004. The measurements were performed with a proton-transfer-reaction mass-spectrometer and fluxes were determined by the eddy covariance method. The observed methanol emission showed a distinct diurnal cycle and was strongly correlated with global radiation and water vapour flux. Mean and maximum daily emissions were found to depend on grassland species composition and, for the intensive field, also on the growing state. The extensive field with a more complex species composition had higher emissions than the graminoid-dominated intensive field, both on an area and on a biomass basis. A simple parameterisation depending on the water vapour flux and the leaf area index allowed a satisfying simulation of the temporal variation of methanol emissions over the growing phase. Accumulated carbon losses due to methanol emissions accounted for 0.024 and 0.048% of net primary productivity for the intensive and extensive field, respectively. The integral methanol emissions over the growing periods were more than one order of magnitude higher than the emissions related to cut and drying events.

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Disjunct eddy covariance measurements of oxygenated volatile organic compounds fluxes from an alfalfa field before and after cutting

Cited by 113 publications

References 39 publications

A new plant chamber facility, PLUS, coupled to the atmosphere simulation chamber SAPHIR

A new plant chamber facility, PLUS, coupled to the atmosphere simulation chamber SAPHIR

First space-based derivation of the global atmospheric methanol emission fluxes

Methanol exchange between grassland and the atmosphere

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