The role of the ocean in the global atmospheric budget of acetone

Fischer, Emily V.; Jacob, Daniel; Millet, Dylan B.; Yantosca, Robert M.; Mao, J.

doi:10.1029/2011gl050086

Cited by 124 publications

(238 citation statements)

References 71 publications

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“…Specifically, Blitz et al (2004) measured the quantum yields to be substantially lower than previously reported. Those findings imply an increased acetone lifetime, and reverse the relative importance of photolysis and OH oxidation as acetone sinks (Fischer et al, 2012). They also modify the importance of acetone as a precursor of HO x and PAN (Arnold et al, 2005), leading to less PAN in the Northern Hemisphere (especially in the upper troposphere), but more PAN in parts of the Southern Hemisphere.…”

Section: Introductionmentioning

confidence: 96%

“…Other terrestrial sources include biomass burning (Simpson et al, 2011) and direct anthropogenic emissions (Goldan et al, 1995;Goldstein and Schade, 2000;de Gouw et al, 2005). Globally, the oceans appear to be both a gross source and a gross sink for atmospheric acetone (Fischer et al, 2012); however, the magnitude and variability of the corresponding net flux is quite uncertain (de Reus et al, 2003;Williams et al, 2004;Lewis et al, 2005;Marandino et al, 2005;Sinha et al, 2007;Taddei et al, 2009;Fischer et al, 2012;Read et al, 2012;Sjostedt et al, 2012). Along with gross oceanic uptake, sinks of atmospheric acetone include photochemical oxidation by OH, photolysis, and deposition to land (Chatfield et al, 1987;McKeen et al, 1997;Gierczak et al, 1998;Blitz et al, 2004;Karl et al, 2010).…”

Section: Introductionmentioning

confidence: 99%

“…Along with gross oceanic uptake, sinks of atmospheric acetone include photochemical oxidation by OH, photolysis, and deposition to land (Chatfield et al, 1987;McKeen et al, 1997;Gierczak et al, 1998;Blitz et al, 2004;Karl et al, 2010). The mean tropospheric lifetime of acetone is estimated to be between 14 and 35 days (Jacob et al, 2002;Arnold et al, 2005;Fischer et al, 2012).…”

Section: Introductionmentioning

confidence: 99%

“…It affects atmospheric chemistry as an important source of hydrogen oxide radicals (HO x = OH + HO 2 ) in the upper troposphere (Jaeglé et al, 1997(Jaeglé et al, , 2001McKeen et al, 1997;Wennberg et al, 1998;Folkins and Chatfield, 2000;Arnold et al, 2005), and as a precursor of peroxyacetyl nitrate (PAN, CH 3 C(O)OONO 2 ), which is a key reservoir for nitrogen oxides (NO x = NO Acetone is emitted by terrestrial vegetation as a by-product of plant metabolic processes, such as cyanogenesis and acetoacetate decarboxylation Jardine et al, 2010), and during plant decay (de Gouw et al, 1999;Warneke et al, 1999). Recent estimates of the resulting biogenic flux to the atmosphere have ranged between 20 and 194 Tg a −1 (Singh et al, 2000(Singh et al, , 2004Jacob et al, 2002;Potter et al, 2003;Arnold et al, 2005;Lathière et al, 2006;Elias et al, 2011;Fischer et al, 2012;Guenther et al, 2012). The other principal source of atmospheric acetone is thought to be photochemical oxidation of precursor VOCs, including the predominantly anthropogenic 2-methyl alkanes (propane, isobutane, isopentane) as well as the biogenic 2-methyl-3-buten-2-ol (MBO) and monoterpenes (Alvarado et al, 1999;Reissell et al, 1999).…”

Section: Introductionmentioning

confidence: 99%

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North American acetone sources determined from tall tower measurements and inverse modeling

Millet

Kim

et al. 2013

Atmos. Chem. Phys.

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We apply a full year of continuous atmospheric acetone measurements from the University of Minnesota tall tower Trace Gas Observatory (KCMP tall tower; 244 m a.g.l.), with a 0.5° × 0.667° GEOS-Chem nested grid simulation to develop quantitative new constraints on seasonal acetone sources over North America. Biogenic acetone emissions in the model are computed based on the MEGANv2.1 inventory. An inverse analysis of the tall tower observations implies a 37% underestimate of emissions from broadleaf trees, shrubs, and herbaceous plants, and an offsetting 40% overestimate of emissions from needleleaf trees plus secondary production from biogenic precursors. The overall result is a small (16%) model underestimate of the total primary + secondary biogenic acetone source in North America. Our analysis shows that North American primary + secondary anthropogenic acetone sources in the model (based on the EPA NEI 2005 inventory) are accurate to within approximately 20%. An optimized GEOS-Chem simulation incorporating the above findings captures 70% of the variance (R = 0.83) in the hourly measurements at the KCMP tall tower, with minimal bias. The resulting North American acetone source is 11 Tg a⁻¹, including both primary emissions (5.5 Tg a⁻¹) and secondary production (5.5 Tg a⁻¹), and with roughly equal contributions from anthropogenic and biogenic sources. The North American acetone source alone is nearly as large as the total continental volatile organic compound (VOC) source from fossil fuel combustion. Using our optimized source estimates as a baseline, we evaluate the sensitivity of atmospheric acetone and peroxyacetyl nitrate (PAN) to shifts in natural and anthropogenic acetone sources over North America. Increased biogenic acetone emissions due to surface warming are likely to provide a significant offset to any future decrease in anthropogenic acetone emissions, particularly during summer

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Section: Introductionmentioning

confidence: 96%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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North American acetone sources determined from tall tower measurements and inverse modeling

Millet

Kim

et al. 2013

Atmos. Chem. Phys.

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“…Photolysis rates use the FAST-JX scheme (Bian and Prather, 2002;Mao et al, 2010), with acetone photolysis rates updated by Fischer et al (2012). Stratospheric chemistry is based on LINOZ McLinden et al (2000) for O 3 and a linearised mechanism for other species as described by Murray et al (2012).…”

Section: Global Modelmentioning

confidence: 99%

Impacts of bromine and iodine chemistry on tropospheric OH and HO<sub>2</sub>: comparing observations with box and global model perspectives

et al. 2018

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Abstract. The chemistry of the halogen species bromine and iodine has a range of impacts on tropospheric composition, and can affect oxidising capacity in a number of ways. However, recent studies disagree on the overall sign of the impacts of halogens on the oxidising capacity of the troposphere. We present simulations of OH and HO 2 radicals for comparison with observations made in the remote tropical ocean boundary layer during the Seasonal Oxidant Study at the Cape Verde Atmospheric Observatory in 2009. We use both a constrained box model, using detailed chemistry derived from the Master Chemical Mechanism (v3.2), and the three-dimensional global chemistry transport model GEOSChem. Both model approaches reproduce the diurnal trends in OH and HO 2 . Absolute observed concentrations are well reproduced by the box model but are overpredicted by the global model, potentially owing to incomplete consideration of oceanic sourced radical sinks. The two models, however, differ in the impacts of halogen chemistry. In the box model, halogen chemistry acts to increase OH concentrations (by 9.8 % at midday at the Cape Verde Atmospheric Observatory), while the global model exhibits a small increase in OH at the Cape Verde Atmospheric Observatory (by 0.6 % at midday) but overall shows a decrease in the global annual mass-weighted mean OH of 4.5 %. These differences reflect the variety of timescales through which the halogens impact the chemical system. On short timescales, photolysis of HOBr and HOI, produced by reactions of HO 2 with BrO and IO, respectively, increases the OH concentration. On longer timescales, halogen-catalysed ozone destruction cycles lead to lower primary production of OH radicals through ozone photolysis, and thus to lower OH concentrations. The global model includes more of the longer timescale responses than the constrained box model, and overall the global impact of the longer timescale response (reduced primary production due to lower O 3 concentrations) overwhelms the shorter timescale response (enhanced cycling from HO 2 to OH), and thus the global OH concentration decreases. The Earth system contains many such responses on a large range of timescales. This work highlights the care that needs to be taken to understand the full impact of any one process on the system as a whole.

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Air‐sea exchange of methanol and acetone during HiWinGS: Estimation of air phase, water phase gas transfer velocities

Yang

Blomquist

2014

JGR Oceans

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The air-sea fluxes of methanol and acetone were measured concurrently using a protontransfer-reaction mass spectrometer (PTR-MS) with the eddy covariance (EC) technique during the High Wind Gas Exchange Study (HiWinGS) in 2013. The seawater concentrations of these compounds were also measured twice daily with the same PTR-MS coupled to a membrane inlet. Dissolved concentrations near the surface ranged from 7 to 28 nM for methanol and from 3 to 9 nM for acetone. Both gases were consistently transported from the atmosphere to the ocean as a result of their low sea surface saturations. The largest influxes were observed in regions of high atmospheric concentrations and strong winds (up to 25 m s 21 ). Comparison of the total air-sea transfer velocity of these two gases (K a ), along with the in situ sensible heat transfer rate, allows us to constrain the individual gas transfer velocity in the air phase (k a ) and water phase (k w ). Among existing parameterizations, the scaling of k a from the COARE model is the most consistent with our observations. The k w we estimated is comparable to the tangential (shear driven) transfer velocity previously determined from measurements of dimethyl sulfide. Lastly, we estimate the wet deposition of methanol and acetone in our study region and evaluate the lifetimes of these compounds in the surface ocean and lower atmosphere with respect to total (dry plus wet) atmospheric deposition.

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The role of the ocean in the global atmospheric budget of acetone

Cited by 124 publications

References 71 publications

North American acetone sources determined from tall tower measurements and inverse modeling

North American acetone sources determined from tall tower measurements and inverse modeling

Impacts of bromine and iodine chemistry on tropospheric OH and HO<sub>2</sub>: comparing observations with box and global model perspectives

Air‐sea exchange of methanol and acetone during HiWinGS: Estimation of air phase, water phase gas transfer velocities

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The role of the ocean in the global atmospheric budget of acetone

Cited by 124 publications

References 71 publications

North American acetone sources determined from tall tower measurements and inverse modeling

North American acetone sources determined from tall tower measurements and inverse modeling

Impacts of bromine and iodine chemistry on tropospheric OH and HO&lt;sub&gt;2&lt;/sub&gt;: comparing observations with box and global model perspectives

Air‐sea exchange of methanol and acetone during HiWinGS: Estimation of air phase, water phase gas transfer velocities

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About

Impacts of bromine and iodine chemistry on tropospheric OH and HO<sub>2</sub>: comparing observations with box and global model perspectives