Observational constraints on the global atmospheric budget of ethanol

Naik, Vaishali; Fiore, Arlene M.; Horowitz, Larry W.; Singh, H. B.; Wiedinmyer, Christine; Guenther, Alex; Gouw, J. A. de; Millet, Dylan B.; Goldan, P. D.; Kuster, W. C.; Goldstein, Allen H.

doi:10.5194/acp-10-5361-2010

Cited by 59 publications

(61 citation statements)

References 39 publications

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“…This experiment also supports the results of other ambrosia beetle monitoring trials which have been conducted only a few times in Europe (Markalas & Kalapanida 1997;Bouget & Noblecourt 2005). Several studies suggest that ethanol is produced from fermentative processes when trees respond to a number of environmental stresses including flooding, drought, or high levels of pollutant gases (Kimmerer & Kozlowski 1982;Naik et al 2010). Low oxygen conditions arising in stressed trees can also lead to ethanol production and subsequent attack by bark and ambrosia beetles (Miller & Rabaglia 2009).…”

Section: Discussionsupporting

confidence: 75%

“…Several studies suggest that ethanol is produced from fermentative processes in trees in response to various environmental stresses including flooding, drought, or high levels of pollutant gases (Kimmerer & Kozlowski 1982;Montgomery & Wargo 1983;Naik et al 2010). The attraction of ambrosia beetles to ethanol is related to their preference for woody material that has sufficiently aged to allow anaerobic respiration to generate ethanol within the tissues (Graham 1968;Cade et al 1970;Moeck 1970;Lindelöw et al 1993;Miller & Rabaglia 2009).…”

Section: Introductionmentioning

confidence: 99%

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Attraction of ambrosia beetles to ethanol baited traps in a Slovakian oak forest

et al. 2014

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The attractiveness of ultra high release ethanol lures to ambrosia beetles in Slovakian oak forests was tested from 2010 to 2012. A total of 24,705 specimens were captured during this three year period with Xyleborinus saxesenii (Ratzeburg, 1837) representing 49.28% (12,174 specimens) of the total. Other dominant species captured in the traps were Anisandrus dispar (F., 1792) (27.84%), Xyleborus monographus (F., 1792) (9.72%) and Trypodendron signatum (F., 1792) (6.04%). During this experiment, Xylosandrus germanus (Blandford, 1894) was detected for the first time in Slovakia with an increase in capture each year (19, 40 and 77 specimens, respectively). Flight period for ambrosia beetles in Slovakia occurs from the beginning of April through the end of September. This is the first time that ethanol baited traps were deployed in Slovakian oak forests and the lures were an effective tool for monitoring native and non-native ambrosia beetles.

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Section: Discussionsupporting

confidence: 75%

Section: Introductionmentioning

confidence: 99%

Attraction of ambrosia beetles to ethanol baited traps in a Slovakian oak forest

et al. 2014

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“…The average aerodynamic temperature T z 0 was estimated using a method described by Nemitz et al (2009) as…”

Section: Meteorological and Trace Gas Datamentioning

confidence: 99%

“…b Lifetime in the boundary layer according to Paulot et al (2011). c Atmospheric lifetime according to Naik et al (2010). d Tropospheric lifetime according to Jacob et al (2002).…”

Section: Voc Depositionmentioning

confidence: 99%

Characterization of total ecosystem-scale biogenic VOC exchange at a Mediterranean oak–hornbeam forest

et al. 2016

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Abstract. Recently, the number and amount of biogenically emitted volatile organic compounds (VOCs) has been discussed in great detail. Depending on the ecosystem, the published number varies between a dozen and several hundred compounds. We present ecosystem exchange fluxes from a mixed oak-hornbeam forest in the Po Valley, Italy. The fluxes were measured by a proton transfer reaction-timeof-flight (PTR-ToF) mass spectrometer and calculated using the eddy covariance (EC) method. Detectable fluxes were observed for up to 29 compounds, dominated by isoprene, which comprised over 60 % of the total upward flux (on a molar basis). The daily average of the total VOC upward flux was 10.4 nmol m −2 s −1 . Methanol had the highest concentration and accounted for the largest downward flux. Methanol seemed to be deposited to dew, as the downward flux happened in the early morning, right after the calculated surface temperature came closest to the calculated dew point temperature.We estimated that up to 30 % of the upward flux of methyl vinyl ketone (MVK) and methacrolein (MACR) originated from atmospheric oxidation of isoprene. A comparison between two methods for the flux detection (manual and automated) was made. Their respective advantages and disadvantages were discussed and the differences in their results shown. Both provide comparable results.

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“…Vehicle ethanol emissions may affect the acid‐generating capacity of atmospheric waters and the oxidizing capacity of the atmosphere through reactions with the hydroxyl radical [ Kieber et al , ]. Ethanol reaction with the hydroxyl radical increases acetaldehyde concentration which in turn increases the concentration of the secondary pollutant peroxyacetyl nitrate, both of which are linked to smog and ozone formation [ Naik et al , ; Hubbard et al , ; Salvo and Geiger , ; Suarez‐bertoa et al , ]. Recent changes in ethanol fuel generation have been rapid with the U.S. and Brazil increasing their production by ~3 and ~1.5 times, respectively, in the last decade [ Renewable Fuels Association (RFA) , ].…”

Section: Introductionmentioning

confidence: 99%

Removal of atmospheric ethanol by wet deposition

Felix

Willey

Thomas

et al. 2017

Global Biogeochemical Cycles

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The global wet deposition flux of ethanol is estimated to be 2.4 ± 1.6 Tg/yr with a conservative range of 0.2–4.6 Tg/yr based upon analyses of 219 wet deposition samples collected at 12 locations globally. This estimate calculated by using observed wet deposition ethanol concentrations is in agreement with previous models (1.4–5 Tg/yr) predicting the wet deposition sink using Henry's law coefficients and atmospheric ethanol concentrations. Wet deposition is estimated to remove between 6 and 17% of the total ethanol emitted to the atmosphere on an annual basis. The concentration of ethanol in marine rain (25 ± 6 nM) is an order of magnitude less than in the majority of terrestrial rains (345 ± 280 nM). Terrestrial rain samples collected in locations impacted by high local sources of biofuel usage and locations downwind from ethanol distilleries were an order of magnitude higher in ethanol concentration (3090 ± 448 nM) compared to rain collected in terrestrial locations not impacted by these sources. These results indicate that wet deposition of ethanol is heavily influenced by local sources. Results of this study are important because they suggest that as biofuel production and usage increase, the concentration of ethanol in the atmosphere will increase as well the wet deposition flux. Additional research constraining the sources, sinks, and atmospheric impacts of ethanol is necessary to better assist in the debate as whether or not to increase consumption of the alcohol as a biofuel.

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Observational constraints on the global atmospheric budget of ethanol

Cited by 59 publications

References 39 publications

Attraction of ambrosia beetles to ethanol baited traps in a Slovakian oak forest

Attraction of ambrosia beetles to ethanol baited traps in a Slovakian oak forest

Characterization of total ecosystem-scale biogenic VOC exchange at a Mediterranean oak–hornbeam forest

Removal of atmospheric ethanol by wet deposition

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