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360 results on '"Atlas, E. L."'

1. Chlorine as a primary radical: evaluation of methods to understand its role in initiation of oxidative cycles

Author

Young, C. J, Washenfelder, R. A, Edwards, P. M, Parrish, D. D, Gilman, J. B, Kuster, W. C, Mielke, L. H, Osthoff, H. D, Tsai, C., Pikelnaya, O., Stutz, J., Veres, P. R, Roberts, J. M, Griffith, S., Dusanter, S., Stevens, P. S, Flynn, J., Grossberg, N., Lefer, B., Holloway, J. S, Peischl, J., Ryerson, T. B, Atlas, E. L, Blake, D. R, and Brown, S. S

Subjects
volatile organic-compounds, master chemical mechanism, marine boundary-layer, gas-phase reactions, mcm v3 part, atomic chlorine, tropospheric degradation, los-angeles, cl atom, halocarbon measurements
Published
2014

2. Estimating the climate significance of halogen-driven ozone loss in the tropical marine troposphere

Author

Saiz-Lopez, A., Lamarque, J.-F., Kinnison, D. E, Tilmes, S., Ordonez, C., Orlando, J. J, Conley, A. J, Plane, J. M. C, Mahajan, A. S, Sousa Santos, G., Atlas, E. L, Blake, D. R, Sander, S. P, Schauffler, S., Thompson, A. M, and Brasseur, G.

Subjects
pacific exploratory mission, boundary-layer halogens, vertical-distribution, atlantic-ocean, coastal antarctica, bromine chemistry, doas measurements, iodine chemistry, reunion island, north-atlantic
Published
2012

3. Bromine and iodine chemistry in a global chemistry-climate model: description and evaluation of very short-lived oceanic sources

Author

Ordenez, C., Lamarque, J.-F., Tilmes, S., Kinnison, D. E, Atlas, E. L, Blake, D. R, Sousa Santos, G., Brasseur, G., and Saiz-Lopez, A.

Subjects
marine boundary-layer, pacific exploratory mission, general-circulation model, tropical atlantic-ocean, carbon-dioxide climates, stratospheric br-y, sea-salt aerosol, atmospheric chemistry, methyl-bromide, photochemical production
Published
2012

4. Finding the missing stratospheric Bry: a global modeling study of CHBr3 and CH2Br2

Author

Liang, Q., Stolarski, R. S, Kawa, S. R, Nielsen, J. E, Douglass, A. R, Rodriguez, J. M, Blake, D. R, Atlas, E. L, and Ott, L. E

Subjects
pacific exploratory mission, bromine chemistry, tropical pacific, atlantic-ocean, pem-tropics, transport, bromoform, troposphere, air, halocarbons
Abstract

Recent in situ and satellite measurements suggest a contribution of similar to 5 pptv to stratospheric inorganic bromine from short-lived bromocarbons. We conduct a modeling study of the two most important short-lived bromocarbons, bromoform (CHBr3) and dibromomethane (CH2Br2), with the Goddard Earth Observing System Chemistry Climate Model (GEOS CCM) to account for this missing stratospheric bromine. We derive a 'top-down' emission estimate of CHBr3 and CH2Br2 using airborne measurements in the Pacific and North American troposphere and lower stratosphere obtained during previous NASA aircraft campaigns. Our emission estimate suggests that to reproduce the observed concentrations in the free troposphere, a global oceanic emission of 425 Gg Br yr(-1) for CHBr3 and 57 Gg Br yr(-1) for CH2Br2 is needed, with 60% of emissions from open ocean and 40% from coastal regions. Although our simple emission scheme assumes no seasonal variations, the model reproduces the observed seasonal variations of the short-lived bromocarbons with high concentrations in winter and low concentrations in summer. This indicates that the seasonality of short-lived bromocarbons is largely due to seasonality in their chemical loss and transport. The inclusion of CHBr3 and CH2Br2 contributes similar to 5 pptv bromine throughout the stratosphere. Both the source gases and inorganic bromine produced from source gas degradation (Br-y(VSLS)) in the troposphere are transported into the stratosphere, and are equally important. Inorganic bromine accounts for half (2.5 pptv) of the bromine from the inclusion of CHBr3 and CH2Br2 near the tropical tropopause and its contribution rapidly increases to similar to 100% as altitude increases. More than 85% of the wet scavenging of Br-y(VSLS) occurs in large-scale precipitation below 500 hPa. Our sensitivity study with wet scavenging in convective updrafts switched off suggests that Br-y(VSLS) in the stratosphere is not sensitive to convection. Convective scavenging only accounts for similar to 0.2 pptv (4%) difference in inorganic bromine delivered to the stratosphere.

Published
2010

5. THE CONVECTIVE TRANSPORT OF ACTIVE SPECIES IN THE TROPICS (CONTRAST) EXPERIMENT

Author

Pan, L. L., Atlas, E. L., Salawitch, R. J., Honomichl, S. B., Bresch, J. F., Randel, W. J., Apel, E. C., Hornbrook, R. S., Weinheimer, A. J., Anderson, D. C., Andrews, S. J., Baidar, S., Beaton, S. P., Campos, T. L., Carpenter, L. J., Chen, D., Dix, B., Donets, V., Hall, S. R., Hanisco, T. F., Homeyer, C. R., Huey, L. G., Jensen, J. B., Kaser, L., Kinnison, D. E., Koenig, T. K., Lamarque, J.-F., Liu, C., Luo, J., Luo, Z. J., Montzka, D. D., Nicely, J. M., Pierce, R. B., Riemer, D. D., Robinson, T., Romashkin, P., Saiz-Lopez, A., Schauffler, S., Shieh, O., Stell, M. H., Ullmann, K., Vaughan, G., Volkamer, R., and Wolfe, G.

Published
2017

6. Characterization of volatile organic compounds (VOCs) in Asian and north American pollution plumes during INTEX-B: identification of specific Chinese air mass tracers

Author

Barletta, B., Meinardi, S., Simpson, I. J, Atlas, E. L, Beyersdorf, A. J, Baker, A. K, Blake, N. J, Yang, M., Midyett, J. R, Novak, B. J, McKeachie, R. J, Fuelberg, H. E, Sachse, G. W, Avery, M. A, Campos, T., Weinheimer, A. J, Rowland, F. S, and Blake, D. R

Subjects
carbonyl sulfide, tropospheric ozone, hydrocarbon ratios, dimethyl sulfide, global sources, fast-response, pem-west, pacific, emissions, transport
Abstract

We present results from the Intercontinental Chemical Transport Experiment - Phase B (INTEX-B) aircraft mission conducted in spring 2006. By analyzing the mixing ratios of volatile organic compounds (VOCs) measured during the second part of the field campaign, together with kinematic back trajectories, we were able to identify five plumes originating from China, four plumes from other Asian regions, and three plumes from the United States. To identify specific tracers for the different air masses we characterized their VOC composition and we compared their background levels with those obtained during the 2004 INTEX-A mission. The Chinese and other Asian air masses were significantly enhanced in carbonyl sulfide (OCS) and methyl chloride (CH3Cl), while all CFC replacement compounds were elevated in US plumes, particularly HFC-134a. Although elevated mixing ratios of Halon-1211 were measured in some Chinese plume samples, several measurements at background levels were also observed. After analyzing the VOC distribution and correlations within the Chinese pollution plumes and applying principal component analysis (PCA), we suggest the use of a suite of species, rather than a single gas, as specific tracers of Chinese air masses (namely OCS, CH3Cl, 1,2-dichloroethane, ethyl chloride, and Halon-1211). In an era of constantly changing halocarbon usage patterns, this suite of gases best reflects new emission characteristics from China.

Published
2009

7. Total observed organic carbon (TOOC) in the atmosphere: a synthesis of North American observations

Author

Heald, C. L, Goldstein, A. H, Allan, J. D, Aiken, A. C, Apel, E., Atlas, E. L, Baker, A. K, Bates, T. S, Beyersdorf, A. J, Blake, D. R, Campos, T., Coe, H., Crounse, J. D, DeCarlo, P. F, de Gouw, J. A, Dunlea, E. J, Flocke, F. M, Fried, A., Goldan, P., Griffin, R. J, Herndon, S. C, Holloway, J. S, Holzinger, R., Jimenez, J. L, Junkermann, W., Kuster, W. C, Lewis, A. C, Meinardi, S., Millet, D. B, Onasch, T., Polidori, A., Quinn, P. K, Riemer, D. D, Roberts, J. M, Salcedo, D., Sive, B., Swanson, A. L, Talbot, R., Warneke, C., Weber, R. J, Weibring, P., Wennberg, P. O, Worsnop, D. R, Wittig, A. E, Zhang, R., Zheng, J., and Zheng, W.

Subjects
reaction mass-spectrometry, air-quality, nonmethane hydrocarbons, new-england, in-situ, aerosol, formaldehyde, emissions, troposphere, pittsburgh
Abstract

Measurements of organic carbon compounds in both the gas and particle phases made upwind, over and downwind of North America are synthesized to examine the total observed organic carbon (TOOC) in the atmosphere over this region. These include measurements made aboard the NOAA WP-3 and BAe-146 aircraft, the NOAA research vessel Ronald H. Brown, and at the Thompson Farm and Chebogue Point surface sites during the summer 2004 ICARTT campaign. Both winter and summer 2002 measurements during the Pittsburgh Air Quality Study are also included. Lastly, the spring 2002 observations at Trinidad Head, CA, surface measurements made in March 2006 in Mexico City and coincidentally aboard the C-130 aircraft during the MILAGRO campaign and later during the IMPEX campaign off the northwestern United States are incorporated. Concentrations of TOOC in these datasets span more than two orders of magnitude. The daytime mean TOOC ranges from 4.0 to 456 mu gCm(-3) from the cleanest site (Trinidad Head) to the most polluted (Mexico City). Organic aerosol makes up 3-17% of this mean TOOC, with highest fractions reported over the northeastern United States, where organic aerosol can comprise up to 50% of TOOC. Carbon monoxide concentrations explain 46 to 86% of the variability in TOOC, with highest TOOC/CO slopes in regions with fresh anthropogenic influence, where we also expect the highest degree of mass closure for TOOC. Correlation with isoprene, formaldehyde, methyl vinyl ketone and methacrolein also indicates that biogenic activity contributes substantially to the variability of TOOC, yet these tracers of biogenic oxidation sources do not explain the variability in organic aerosol observed over North America. We highlight the critical need to develop measurement techniques to routinely detect total gas phase VOCs, and to deploy comprehensive suites of TOOC instruments in diverse environments to quantify the ambient evolution of organic carbon from source to sink.

Published
2008

8. Investigating the sources and atmospheric processing of fine particles from Asia and the Northwestern United States measured during INTEX B

Author

Peltier, R. E, Hecobian, A. H, Weber, R. J, Stohl, A., Atlas, E. L, Riemer, D. D, Blake, D. R, Apel, E., Campos, T., and Karl, T.

Subjects
secondary organic aerosol, reaction mass-spectrometry, dispersion model flexpart, chemical-composition, seasonal-variation, oligomer formation, water, emissions, air, troposphere
Abstract

During the National Aeronautics and Space Administration (NASA) Intercontinental Chemical Transport Experiment, Phase B (INTEX-B), in the spring of 2006, airborne measurements were made in the United States Pacific Northwest of the major inorganic ions and the water-soluble organic carbon (WSOC) of submicron (PM1.0) aerosol. An atmospheric trajectory (HYSPLIT) and a Lagrangian particle dispersion model (Flexpart) quantifying source contributions for carbon monoxide (CO) were used to segregate air masses into those of primarily Asian influence (>75% Asian CO) or North American influence (>75% North American CO). Of the measured compounds, fine particle mass mostly consisted of water-soluble organic carbon and sulfate, with median sulfate and WSOC concentrations in two to four times higher, respectively, in North American air masses versus transported Asian air masses. The fraction of WSOC to sulfate in transported Asian air masses was significantly lower than one at altitudes above 3 km due to depleted organic aerosol, opposite to what has been observed closer to Asia and in the northeastern United States, where organic components were at higher concentrations than sulfate in the free troposphere. The observations could be explained by loss of sulfate and organic aerosol by precipitation scavenging, with reformation of mainly sulfate during advection from Asia to North America. In contrast to free tropospheric measurements, for all air masses below approximately 2 km altitude median WSOC-sulfate ratios were consistently between one and two. WSOC sources were investigated by multivariate linear regression analyses of WSOC and volatile organic compounds (VOCs). In Asian air masses, of the WSOC variability that could be explained (49%), most was related to fossil fuel combustion VOCs, compared to North American air masses, where 75% of the WSOC variability was explained through a nearly equal combination of fossil fuel combustion and biogenic VOCs. Distinct WSOC plumes encountered during the experiment were also studied. A plume observed near the California Central Valley at 0.6 km altitude was related to both fossil fuel combustion and biogenic VOCs. Another Central Valley plume observed over Nevada at 3 to 5 km, in a region of cloud detrainment, was mostly related to biogenic VOCs.

Published
2008

10. The Detection of Large HNO 3 -Containing Particles in the Winter Arctic Stratosphere

Author

Fahey, D. W., Gao, R. S., Carslaw, K. S., Kettleborough, J., Popp, P. J., Northway, M. J., Holecek, J. C., Ciciora, S. C., McLaughlin, R. J., Thompson, T. L., Winkler, R. H., Baumgardner, D. G., Gandrud, B., Wennberg, P. O., Dhaniyala, S., McKinney, K., Salawitch, R. J., Bui, T. P., Elkins, J. W., Webster, C. R., Atlas, E. L., Jost, H., Wilson, J. C., Herman, R. L., Kleinböhl, A., and von König, M.

Published
2001

11. Hydrogen Radicals, Nitrogen Radicals, and the Production of O$_3$ in the Upper Troposphere

Author

Wennberg, P. O., Hanisco, T. F., Jaeglé, L., Jacob, D. J., Hintsa, E. J., Lanzendorf, E. J., Anderson, J. G., Keim, E. R., Donnelly, S. G., Del Negro, L. A., Fahey, D. W., McKeen, S. A., Salawitch, R. J., Webster, C. R., May, R. D., Herman, R. L., Proffitt, M. H., Margitan, J. J., Atlas, E. L., Schauffler, S. M., Flocke, F., McElroy, C. T., and Bui, T. P.

Published
1998

12. Organic Aerosol Formation Downwind from the Deepwater Horizon Oil Spill

Author

de Gouw, J. A., Middlebrook, A. M., Warneke, C., Ahmadov, R., Atlas, E. L., Bahreini, R., Blake, D. R., Brock, C. A., Brioude, J., Fahey, D. W., Fehsenfeld, F. C., Holloway, J. S., Le Henaff, M., Lueb, R. A., McKeen, S. A., Meagher, J. F., Murphy, D. M., Paris, C., Parrish, D. D., Perring, A. E., Pollack, I. B., Ravishankara, A. R., Robinson, A. L., Ryerson, T. B., Schwarz, J. P., Spackman, J. R., Srinivasan, A., and Watts, L. A.

Published
2011
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14. Observational evidence for interhemispheric hydroxyl-radical parity

Author

Patra, P. K., Krol, M. C., Montzka, S. A., Arnold, T., Atlas, E. L., Lintner, B. R., and Stephens, B. B.

Subjects
Atmospheric chemistry, Meteorological research, Atmospheric carbon dioxide -- Research, Air pollution -- Chemical properties -- Research, Trichloroethane -- Research, Environmental issues, Science and technology, Zoology and wildlife conservation
Abstract

Observations of methyl chloroform combined with an atmospheric transport model predict a Northern to Southern Hemisphere hydroxyl ratio of slightly less than 1, whereas commonly used atmospheric chemistry models predict ratios 15-45% higher. The north-south distribution of atmospheric OH The hydroxyl radical is an important atmospheric oxidant, but our knowledge of its global distribution remains imprecise, with estimates for the ratio of Northern Hemisphere to Southern Hemisphere hydroxyl radical concentration varying from 0.85 to 1.4. These authors use a three-dimensional chemistry-transport model that has been well validated for interhemispheric transport using sulphur hexafluoride measurements, to obtain an interhemispheric hydroxyl radical ratio of 0.97[plus or minus]0.12. This information can help improve our understanding of the fate of atmospheric pollutants and greenhouse gases. The hydroxyl radical (OH) is a key oxidant involved in the removal of air pollutants and greenhouse gases from the atmosphere.sup.1,2,3. The ratio of Northern Hemispheric to Southern Hemispheric (NH/SH) OH concentration is important for our understanding of emission estimates of atmospheric species such as nitrogen oxides and methane.sup.4,5,6. It remains poorly constrained, however, with a range of estimates from 0.85 to 1.4 (refs 4, 7,8,9,10). Here we determine the NH/SH ratio of OH with the help of methyl chloroform data (a proxy for OH concentrations) and an atmospheric transport model that accurately describes interhemispheric transport and modelled emissions. We find that for the years 2004-2011 the model predicts an annual mean NH-SH gradient of methyl chloroform that is a tight linear function of the modelled NH/SH ratio in annual mean OH. We estimate a NH/SH OH ratio of 0.97 [plus or minus] 0.12 during this time period by optimizing global total emissions and mean OH abundance to fit methyl chloroform data from two surface-measurement networks and aircraft campaigns.sup.11,12,13. Our findings suggest that top-down emission estimates of reactive species such as nitrogen oxides in key emitting countries in the NH that are based on a NH/SH OH ratio larger than 1 may be overestimated., Author(s): P. K. Patra [sup.1] [sup.2] , M. C. Krol [sup.3] , S. A. Montzka [sup.4] , T. Arnold [sup.5] , E. L. Atlas [sup.6] , B. R. Lintner [sup.7] [...]

Published
2014
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19. Finding the Missing Stratospheric Br(sub y): A Global Modeling Study of CHBr3 and CH2Br2

Author

Liang, Q, Stolarski, R. S, Kawa, S. R, Nielsen, J. E, Douglass, A. R, Rodriguez, J. M, Blake, D. R, Atlas, E. L, and Ott, L. E

Subjects
Inorganic, Organic And Physical Chemistry
Abstract

Recent in situ and satellite measurements suggest a contribution of ~5 pptv to stratospheric inorganic bromine from short-lived bromocarbons. We conduct a modeling study of the two most important short-lived bromocarbons, bromoform (CHBr3) and dibromomethane (CH2Br2), with the Goddard Earth Observing System Chemistry Climate Model (GEOS CCM) to account for this missing stratospheric bromine. We derive a "top-down" emission estimate of CHBr3 and CH2Br2 using airborne measurements in the Pacific and North American troposphere and lower stratosphere obtained during previous NASA aircraft campaigns. Our emission estimate suggests that to reproduce the observed concentrations in the free troposphere, a global oceanic emission of 425 Gg Br yr(exp -1) for CHBr3 and 57 Gg Br yr(exp -l) for CH2Br2 is needed, with 60% of emissions from open ocean and 40% from coastal regions. Although our simple emission scheme assumes no seasonal variations, the model reproduces the observed seasonal variations of the short-lived bromocarbons with high concentrations in winter and low concentrations in summer. This indicates that the seasonality of short-lived bromocarbons is largely due to seasonality in their chemical loss and transport. The inclusion of CHBr3 and CH2Br2 contributes ~5 pptv bromine throughout the stratosphere. Both the source gases and inorganic bromine produced from source gas degradation (Br~SLS) in the troposphere are transported into the stratosphere, and are equally important. Inorganic bromine accounts for half (2.5 pptv) of the bromine from the inclusion of CHBr3 and CHzBr2 near the tropical tropopause and its contribution rapidly increases to ~ 100% as altitude increases. More than 85% of the wet scavenging of Br(sub y)(sup VSLS) occurs in large-scale precipitation below 500 hPa. Our sensitivity study with wet scavenging in convective updrafts switched off suggests that Br(sub y)(sup SLS) in the stratosphere is not sensitive to convection. Convective scavenging only accounts for ~0.2 pptv (4%) difference in inorganic bromine delivered to the stratosphere.

Published
2010

20. Measurements of Trace Gases in the Tropical Tropopause Layer

Author

Marcy, T. P, Popp, P. J, Gao, R. S, Fahey, D. W, Ray, E. A, Richard, E. C, Thompson, T. L, Atlas, E. L, Lowenstein, M, Wofsy, S. C, Park, S, Weinstock, E. M, Swartz, W. H, and Mahoney, M. J

Subjects
Meteorology And Climatology
Abstract

A unique dataset of airborne in situ observations of HCl, O3, HNO3, H2O, CO, CO2 and CH3Cl has been made in and near the tropical tropopause layer (TTL). A total of 16 profiles across the tropopause were obtained at latitudes between 10degN and 3degs from the NASA WB-57F high-altitude aircraft flying from Costa Rica. Few in situ measurements of these gases, particularly HCl and HNO3, have been reported for the TTL. The general features of the trace gas vertical profiles are consistent with the concept of the TTL as distinct from the lower troposphere and lower stratosphere. A combination of the tracer profiles and correlations with O3 is used to show that a measurable amount of stratospheric air is mixed into this region. The HCl measurements offer an important constraint on stratospheric mixing into the TTL because once the contribution from halocarbon decomposition is quantified, the remaining HCl (>60% in this study) must have a stratospheric source. Stratospheric HCl in the TTL brings with it a proportional amount of stratospheric O3. Quantifying the sources of O3 in the TTL is important because O3 is particularly effective as a greenhouse gas in the tropopause region.

Published
2008
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21. Total Observed Organic Carbon (TOOC): A Synthesis of North American Observations

Author

Heald, C. L, Goldstein, A. H, Allan, J. D, Aiken, A. C, Apel, E, Atlas, E. L, Baker, A. K, Bates, T. S, Beyersdorf, A. J, Blake, D. R, Campos, T, Coe, H, Crounse, J. D, DeCarlo, P. F, de Gouw, J. A, Dunlea, E. J, Flocke, F. M, Fried, A, Goldan, P, Griffin, R. J, Herndon, S. C, Holloway, J. S, Holzinger, R, Jimenez, J. L, and Junkermann, W

Subjects
Environment Pollution
Abstract

Measurements of organic carbon compounds in both the gas and particle phases made upwind, over and downwind of North America are synthesized to examine the total observed organic carbon (TOOC) in the atmosphere over this region. These include measurements made aboard the NOAA WP-3 and BAe-146 aircraft, the NOAA research vessel Ronald H. Brown, and at the Thompson Farm and Chebogue Point surface sites during the summer 2004 ICARTT campaign. Both winter and summer 2002 measurements during the Pittsburgh Air Quality Study are also included. Lastly, the spring 2002 observations at Trinidad Head, CA, surface measurements made in March 2006 in Mexico City and coincidentally aboard the C-130 aircraft during the MILAGRO campaign and later during the IMPEX campaign off the northwestern United States are incorporated. Concentrations of TOOC in these datasets span more than two orders of magnitude. The daytime mean TOOC ranges from 4.0 to 456 microg C/cubic m from the cleanest site (Trinidad Head) to the most polluted (Mexico City). Organic aerosol makes up 3-17% of this mean TOOC, with highest fractions reported over the northeastern United States, where organic aerosol can comprise up to 50% of TOOC. Carbon monoxide concentrations explain 46 to 86% of the variability in TOOC, with highest TOOC/CO slopes in regions with fresh anthropogenic influence, where we also expect the highest degree of mass closure for TOOC. Correlation with isoprene, formaldehyde, methyl vinyl ketone and methacrolein also indicates that biogenic activity contributes substantially to the variability of TOOC, yet these tracers of biogenic oxidation sources do not explain the variability in organic aerosol observed over North America. We highlight the critical need to develop measurement techniques to routinely detect total gas phase VOCs, and to deploy comprehensive suites of TOOC instruments in diverse environments to quantify the ambient evolution of organic carbon from source to sink.

Published
2007

23. The Detection of Large HNO3-Containing Particles in the Winter Arctic Stratosphere

Author

Fahey, D. W., Gao, R. S., Carslaw, K. S., Kettleborough, J., Popp, P. J., Northway, M. J., Holecek, J. C., Ciciora, S. C., McLaughlin, R. J., Thompson, T. L., Winkler, R. H., Baumgardner, D. G., Gandrud, B., Wennberg, P. O., Dhaniyala, S., McKinney, K., Peter, Th., Salawitch, R. J., Bui, T. P., Elkins, J. W., Webster, C. R., Atlas, E. L., Jost, H., Wilson, J. C., Herman, R. L., Kleinböhl, A., and von König, M.

Published
2001

24. In situ measurements of BrO during AASE II

Author

Avallone, L. M, Toohey, D. W, Schauffler, S. M, Pollock, W. H, Heidt, L. E, Atlas, E. L, and Chan, K. R

Subjects
Meteorology And Climatology
Abstract

BrO measured from the NASA ER-2 during Airborne Arctic Stratospheric Expedition (AASE) II exhibited a mean value (for 20-minute averages) of 5.4 +/- 0.3 pptv, with a standard deviation of 3.1 pptv. Ratios of BrO to available inorganic bromine (Br(sub y)) show only slight increases in polar regions relative to midlatitudes. A comparison between observed latitudinal and diurnal variations of this same ratio and that calculated by photochemical models shows reasonable agreement in behavior, but significant discrepancies in magnitude. It is unclear whether this difference is due to errors in measurements, models or both.

Published
1995
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25. Estimates of total organic and inorganic chlorine in the lower stratosphere from in situ and flask measurements during AASE 2

Author

Woodbridge, E. L, Elkins, J. W, Fahey, D. W, Heidt, L. E, Solomon, S, Baring, T. J, Gilpin, T. M, Pollack, W. H, Schauffler, S. M, and Atlas, E. L

Subjects
Environment Pollution
Abstract

Aircraft sampling has provided extensive in situ and flask measurements of organic chlorine species in the lower stratosphere. The recent Airborne Arctic Stratospheric Expedition 2 (AASE 2) included two independent measurements of organic chlorine species using whole air sample and real-time techniques. From the whole air sample measurements we derive directly the burden of total organic chlorine (CCl(y)) in the lower stratosphere. From the more limited real-time measurements we estimate the CCl(y) burden using mixing ratios and growth rates of the principal CCl(y) species in the troposphere in conjunction with results from a two-dimensional photochemical model. Since stratospheric chlorine is tropospheric in origin and tropospheric mixing ratios are increasing, it is necessary to establish the average age of a stratospheric air parcel to assess its total chlorine (Cl(sub Total)) abundance. Total inorganic chlorine (Cl(y)) in the parcel is then estimated by the simple difference, Cl(y) = Cl(sub Total) - CCl(y). The consistency of the results from these two quite different techniques suggests that we can determine the CCl(y) and Cl(y) in the lower stratosphere with confidence. Such estimates of organic and inorganic chlorine are crucial in evaluating the photochemistry controlling chlorine partitioning and hence ozone loss processes in the lower stratosphere.

Published
1995
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26. BrO and Bry profiles over the Western Pacific : Relevance of Inorganic Bromine Sources and a Bry Minimum in the Aged Tropical Tropopause Layer

Author

Koenig, T. K., Volkamer, R., Baidar, S., Dix, B., Anderson, D. C., Salawitch, R. J., Wales, P. A., Cuevas, C. A., Fernandez, R. P., Saiz-Lopez, A., Evans, M. J., Sherwen, T., Jacob, D. J., Schmidt, J., Kinnison, D., Lamarque, J.-F., Apel, E. C., Bresch, J. C., Campos, T., Flocke, F. M., Honomichl, S. B., Hornbrook, R., Jensen, J. B., Lueb, R., Montzka, D. D., Pan, L. L., Reeves, J. M., Schauffler, S. M., Ullmann, K., Weinheimer, A. J., Atlas, E. L., Donets, V., Navarro, M. A., Riemer, D., Blake, N. J., Huey, L. G., Tanner, D. J., Hanisco, T. F., Wolfe, G. M., Wang, Siyuan, Chen, Dexien, and Hall, Samuel R.

Subjects
purl.org/becyt/ford/1 [https], BrO and Bry, purl.org/becyt/ford/1.5 [https], CONTRAST, Stratospheric Injection, Meteorología y Ciencias Atmosféricas, CIENCIAS NATURALES Y EXACTAS, VSL Chemistry, Ciencias de la Tierra y relacionadas con el Medio Ambiente
Abstract

We report measurements of bromine monoxide (BrO) and use an observationally constrained chemical box-model to infer total gas phase inorganic bromine (Bry) over the tropical Western Pacific Ocean (tWPO) during the CONTRAST field 40 campaign (January – February 2014). The median tropospheric BrO Vertical Column Density (VCD) over the tWPO was measured as 1.6×1013 molec. cm˗2, compared to model predictions of 0.4×1013 in CAM-Chem, 0.9×1013 in GEOS-Chem, and 2.1×1013 in GEOS-Chem with a sea-salt aerosol (SSA) bromine source. The observed BrO and inferred Bry profiles is found to be C-shaped in the troposphere, with local maxima in the marine boundary layer (MBL) and in the upper free troposphere. Neither global model fully captures this profile shape. Between 6 and 13.5 km, the inferred Bry is highly sensitive to 5 assumptions about the rate of heterogeneous bromine recycling (depends on the surface area of ice/aerosols), and the inclusion of a SSA bromine source. A local Bry maximum of 3.6 ppt (2.3-11.1 ppt, 95% CI) is observed between 9.5 and 13.5 km in air masses influenced by recent convective outflow. Unlike BrO, which increases from the convective TTL to the aged TTL, gas phase Bry decreases from the convective TTL to the aged TTL. Analysis of gas phase Bry against multiple tracers (CFC-11, H2O/O3 ratio, and θ) reveals a Bry minimum of 2.7 ppt (2.4-3.0 ppt, 95% CI) in the aged TTL, which is remarkably insensitive 10 to assumptions about heterogeneous chemistry. Bry increases to 6.3 ppt (5.9-6.7 ppt, 95% CI) in the stratospheric middleworld, and 6.9 ppt (6.7-7.1 ppt, 95% CI) in the stratospheric overworld. The local Bry minimum in the aged TTL is qualitatively (but not quantitatively) captured by CAM-chem, and suggests a more complex partitioning of gas phase and aerosol Bry species than previously recognized. Our data provide corroborating evidence that inorganic bromine sources (e.g., SSA derived gas phase Bry) are needed to explain the gas phase Bry budget in the TTL. They are also consistent with observations of significant 15 bromide in UTLS aerosols. The total Bry budget in the TTL is currently not closed, because of the lack of concurrent quantitative measurements of gas phase Bry species (i.e., BrO, HOBr, HBr, etc.) and aerosol bromide. These simultaneous measurements are needed 1) to quantify SSA derived Bry aloft, 2) to test Bry partitioning, and explain the gas phase Bry minimum in the aged TTL, 3) to constrain heterogeneous reaction rates of bromine, and 4) to account for all of the sources of Bry to the lower stratosphere. Fil: Koenig, Theodore K.. State University of Colorado at Boulder; Estados Unidos. Cooperative Institute for Research in Environmental Sciences; Estados Unidos Fil: Volkamer, Rainer. State University of Colorado at Boulder; Estados Unidos. Cooperative Institute for Research in Environmental Sciences; Estados Unidos Fil: Baidar, Sunil. Cooperative Institute for Research in Environmental Sciences; Estados Unidos. State University of Colorado at Boulder; Estados Unidos Fil: Dix, Barbara. State University of Colorado at Boulder; Estados Unidos Fil: Wang, Siyuan. State University of Colorado at Boulder; Estados Unidos. University of Michigan; Estados Unidos Fil: Anderson, Daniel C.. University of Maryland. Department of Atmospheric and Oceanic Science; Estados Unidos Fil: Salawitch, Ross J.. University of Maryland. Department of Atmospheric and Oceanic Science; Estados Unidos Fil: Wales, Pamela A.. University of Maryland. Department of Atmospheric and Oceanic Science; Estados Unidos Fil: Cuevas, Carlos A.. Consejo Superior de Investigaciones Científicas. Instituto de Química Física; España Fil: Fernandez, Rafael Pedro. Universidad Nacional de Cuyo. Facultad de Ciencias Exactas y Naturales; Argentina. Universidad Tecnologica Nacional. Facultad Regional Mendoza. Secretaría de Ciencia, Tecnología y Postgrado; Argentina. Consejo Nacional de Investigaciones Científicas y Técnicas. Centro Científico Tecnológico Conicet - Mendoza; Argentina Fil: Saiz Lopez, Alfonso. Consejo Superior de Investigaciones Científicas. Instituto de Química Física; España Fil: Evans, Mathew J.. University of York; Reino Unido Fil: Sherwen, Tomás. University of York; Reino Unido Fil: Jacob, Daniel J.. Harvard University; Estados Unidos Fil: Schmidt, Johan. Universidad de Copenhagen; Dinamarca Fil: Kinnison, Douglas. National Center for Atmospheric Research; Estados Unidos Fil: Lamarque, Jean François. National Center for Atmospheric Research; Estados Unidos Fil: Apel, Eric C.. National Center for Atmospheric Research; Estados Unidos Fil: Bresch, James C.. National Center for Atmospheric Research; Estados Unidos Fil: Campos, Teresa. National Center for Atmospheric Research; Estados Unidos Fil: Flocke, Frank M.. National Center for Atmospheric Research; Estados Unidos Fil: Hall, Samuel R.. National Center for Atmospheric Research; Estados Unidos Fil: Honomichl, Shawn B.. National Center for Atmospheric Research; Estados Unidos Fil: Hornbrook, Rebecca. National Center for Atmospheric Research; Estados Unidos Fil: Jensen, Jorgen B.. National Center for Atmospheric Research; Estados Unidos Fil: Lueb, Richard. National Center for Atmospheric Research; Estados Unidos Fil: Montzka, Denise D.. National Center for Atmospheric Research; Estados Unidos Fil: Pan, Laura L.. National Center for Atmospheric Research; Estados Unidos Fil: Reeves, J. Michael. National Center for Atmospheric Research; Estados Unidos Fil: Schauffle, Sue M.. National Center for Atmospheric Research; Estados Unidos Fil: Ullmann, Kirk. National Center for Atmospheric Research; Estados Unidos Fil: Weinheimer, Andrew J.. National Center for Atmospheric Research; Estados Unidos Fil: Atlas, Elliot L.. University of Miami; Estados Unidos Fil: Donets, Valeria. University of Miami; Estados Unidos Fil: Maria A. Navarro. University of Miami; Estados Unidos Fil: Riemer, Daniel. University of Miami; Estados Unidos Fil: Blake, Nicola J.. University of California; Estados Unidos Fil: Chen, Dexien. School of Earth & Atmospheric Sciences; Estados Unidos Fil: Huey, L. Gregory. School of Earth & Atmospheric Sciences; Estados Unidos Fil: Tanner, David J.. School of Earth & Atmospheric Sciences; Estados Unidos Fil: Hanisco, Thomas F.. National Aeronautics and Space Administration; Estados Unidos Fil: Wolfe, Glenn M.. University of Maryland; Estados Unidos. National Aeronautics and Space Administration; Estados Unidos

Published
2017

27. Measurements of Halogenated Organic Compounds near the Tropical Tropopause

Author

Schauffler, S. M, Heidt, L. E, Pollock, W. H, Gilpin, T. M, Vedder, J. F, Solomon, S, Leub, R. A, and Atlas, E. L

Subjects
Environment Pollution
Abstract

The amount of organic chlorine and bromine entering the stratosphere have a direct influence on the magnitude of chlorine and bromine catalyzed ozone losses. Twelve organic chlorine species and five organic bromine species were measured from 12 samples collected near the tropopause between 23.8 deg N and 25.3 deg N during AASE 2. The average mixing ratios of total organic chlorine and total organic bromine were 3.50 +/- 0.06 ppbv and 21.1 +/- 0.8 pptv, respectively. CH3Cl represented 15.1% of the total organic chlorine, with CFC 11 (CCl3F) and CFC 12 (CCl2F2) accounting for 22.6% and 28.2%, respectively, with the remaining 34.1% primarily from CCl4, CH3CCl3, and CFC 113 (CCl2FCClF2). CH3Br represented 54% of the total organic bromine. The 95% confidence intervals of the mixing ratios of all but four of the individual compounds were within the range observed in low and mid-latitude midtroposphere samples. The four compounds with significantly lower mixing ratios at the tropopause were CHCl3, CH2Cl2, CH2Br2, and CH3CCl3. The lower mixing ratios may be due to entrainment of southern hemisphere air during vertical transport in the tropical region and/or to exchange of air across the tropopause between the lower stratosphere and upper troposphere.

Published
1993

29. Biogenic halocarbons from the Peruvian upwelling region as tropospheric halogen source.

Author

Hepach, Helmke, Quack, Birgit, Tegtmeier, Susann, Engel, Anja, Bracher, Astrid, Fuhlbrügge, S., Galgani, Luisa, Atlas, E. L., Lampel, Johannes, Frieß, Udo, Krüger, K., Hepach, Helmke, Quack, Birgit, Tegtmeier, Susann, Engel, Anja, Bracher, Astrid, Fuhlbrügge, S., Galgani, Luisa, Atlas, E. L., Lampel, Johannes, Frieß, Udo, and Krüger, K.

Published
2016

30. Can simple models predict large scale surface ocean isoprene concentrations?

Author

Booge, Dennis, Marandino, Christa A., Schlundt, Cathleen, Palmer, P. I., Schlundt, M., Atlas, E. L., Bracher, Astrid, Saltzmann, E. S., Wallace, D. W. R., Booge, Dennis, Marandino, Christa A., Schlundt, Cathleen, Palmer, P. I., Schlundt, M., Atlas, E. L., Bracher, Astrid, Saltzmann, E. S., and Wallace, D. W. R.

Abstract

We use isoprene and related field measurements from three different ocean data sets together with remotely sensed satellite data to model global marine isoprene emissions. We show that using monthly mean satellite-derived chl a concentrations to parameterize isoprene with a constant chl a normalized isoprene production rate underpredicts the measured oceanic isoprene concentration by a mean factor of 19 ± 12. Improving the model by using phytoplankton functional type dependent production values and by decreasing the bacterial degradation rate of isoprene in the water column results in only a slight underestimation (factor 1.7 ± 1.2). We calculate global isoprene emissions of 0.21 Tg C for 2014 using this improved model, which is twice the value calculated using the original model. Nonetheless, the sea-to-air fluxes have to be at least 1 order of magnitude higher to account for measured atmospheric isoprene mixing ratios. These findings suggest that there is at least one missing oceanic source of isoprene and, possibly, other unknown factors in the ocean or atmosphere influencing the atmospheric values. The discrepancy between calculated fluxes and atmospheric observations must be reconciled in order to fully understand the importance of marine-derived isoprene as a precursor to remote marine boundary layer particle formation.

Published
2016

31. A multi-model intercomparison of halogenated very short-lived substances (TransCom-VSLS):linking oceanic emissions and tropospheric transport for a reconciled estimate of the stratospheric source gas injection of bromine

Author

Hossaini, R., Patra, P. K., Leeson, A. A., Krysztofiak, G., Abraham, N. L., Archibald, A. T., Aschmann, J., Atlas, E. L., Belikov, D. A., Bönisch, H., Carpenter, L. J., Dhomse, S., Dorf, M., Engel, A., Feng, W., Fuhlbrügge, S., Griffiths, P. T., Harris, N. R. P., Hommel, R., Keber, T., Krüger, K., Lennartz, S. T., Maksyutov, S., Mantle, H., Mills, G. P., Montzka, S. A., Moore, F., Navarro, M. A., Oram, D. E., Pfeilsticker, K., Pyle, J. A., Quack, B., Saikawa, E., Saiz-Lopez, A., Sala, S., Sinnhuber, B.-M., Taguchi, S., Tegtmeier, S., Lidster, R. T., Ziska, F., Hossaini, R., Patra, P. K., Leeson, A. A., Krysztofiak, G., Abraham, N. L., Archibald, A. T., Aschmann, J., Atlas, E. L., Belikov, D. A., Bönisch, H., Carpenter, L. J., Dhomse, S., Dorf, M., Engel, A., Feng, W., Fuhlbrügge, S., Griffiths, P. T., Harris, N. R. P., Hommel, R., Keber, T., Krüger, K., Lennartz, S. T., Maksyutov, S., Mantle, H., Mills, G. P., Montzka, S. A., Moore, F., Navarro, M. A., Oram, D. E., Pfeilsticker, K., Pyle, J. A., Quack, B., Saikawa, E., Saiz-Lopez, A., Sala, S., Sinnhuber, B.-M., Taguchi, S., Tegtmeier, S., Lidster, R. T., and Ziska, F.

Abstract

The first concerted multi-model intercomparison of halogenated very short-lived substances (VSLS) has been performed, within the framework of the ongoing Atmospheric Tracer Transport Model Intercomparison Project (TransCom). Eleven global models or model variants participated (nine chemical transport models and two chemistry–climate models) by simulating the major natural bromine VSLS, bromoform (CHBr3) and dibromomethane (CH2Br2), over a 20-year period (1993–2012). Except for three model simulations, all others were driven offline by (or nudged to) reanalysed meteorology. The overarching goal of TransCom-VSLS was to provide a reconciled model estimate of the stratospheric source gas injection (SGI) of bromine from these gases, to constrain the current measurement-derived range, and to investigate inter-model differences due to emissions and transport processes. Models ran with standardised idealised chemistry, to isolate differences due to transport, and we investigated the sensitivity of results to a range of VSLS emission inventories. Models were tested in their ability to reproduce the observed seasonal and spatial distribution of VSLS at the surface, using measurements from NOAA's long-term global monitoring network, and in the tropical troposphere, using recent aircraft measurements – including high-altitude observations from the NASA Global Hawk platform. The models generally capture the observed seasonal cycle of surface CHBr3 and CH2Br2 well, with a strong model–measurement correlation (r ≥ 0.7) at most sites. In a given model, the absolute model–measurement agreement at the surface is highly sensitive to the choice of emissions. Large inter-model differences are apparent when using the same emission inventory, highlighting the challenges faced in evaluating such inventories at the global scale. Across the ensemble, most consistency is found within the tropics where most of the models (8 out of 11) achieve best agreement to surface CHBr3 observations usin

Published
2016

32. A multi-model intercomparison of halogenated very short-lived substances (TransCom-VSLS): linking oceanic emissions and tropospheric transport for a reconciled estimate of the stratospheric source gas injection of bromine

Author

Hossaini, R., Patra, P. K., Leeson, A. A., Krysztofiak, G., Abraham, N. L., Andrews, S. J., Archibald, A. T., Aschmann, J., Atlas, E. L., Belikov, D. A., Bönisch, H., Butler, R., Carpenter, L. J., Dhomse, S., Dorf, M., Engel, A., Feng, L., Feng, W., Fuhlbrügge, Steffen, Griffiths, P. T., Harris, N. R. P., Hommel, R., Keber, T., Krüger, Kirstin, Lennartz, Sinnika T., Maksyutov, S., Mantle, H., Mills, G. P., Miller, B., Montzka, S. A., Moore, F., Navarro, M. A., Oram, D. E., Palmer, P. I., Pfeilsticker, K., Pyle, J. A., Quack, Birgit, Robinson, A. D., Saikawa, E., Saiz-Lopez, A., Sala, S., Sinnhuber, B.-M., Taguchi, S., Tegtmeier, Susann, Lidster, R. T., Wilson, C., Ziska, Franziska, Hossaini, R., Patra, P. K., Leeson, A. A., Krysztofiak, G., Abraham, N. L., Andrews, S. J., Archibald, A. T., Aschmann, J., Atlas, E. L., Belikov, D. A., Bönisch, H., Butler, R., Carpenter, L. J., Dhomse, S., Dorf, M., Engel, A., Feng, L., Feng, W., Fuhlbrügge, Steffen, Griffiths, P. T., Harris, N. R. P., Hommel, R., Keber, T., Krüger, Kirstin, Lennartz, Sinnika T., Maksyutov, S., Mantle, H., Mills, G. P., Miller, B., Montzka, S. A., Moore, F., Navarro, M. A., Oram, D. E., Palmer, P. I., Pfeilsticker, K., Pyle, J. A., Quack, Birgit, Robinson, A. D., Saikawa, E., Saiz-Lopez, A., Sala, S., Sinnhuber, B.-M., Taguchi, S., Tegtmeier, Susann, Lidster, R. T., Wilson, C., and Ziska, Franziska

Abstract

The first concerted multi-model intercomparison of halogenated very short-lived substances (VSLS) has been performed, within the framework of the ongoing Atmospheric Tracer Transport Model Intercomparison Project (TransCom). Eleven global models or model variants participated, simulating the major natural bromine VSLS, bromoform (CHBr3) and dibromomethane (CH2Br2), over a 20-year period (1993-2012). The overarching goal of TransCom-VSLS was to provide a reconciled model estimate of the stratospheric source gas injection (SGI) of bromine from these gases, to constrain the current measurement-derived range, and to investigate inter-model differences due to emissions and transport processes.Models ran with standardised idealised chemistry, to isolate differences due to transport, and we investigated the sensitivity of results to a range of VSLS emission inventories. Models were tested in their ability to reproduce the observed seasonal and spatial distribution of VSLS at the surface, using measurements from NOAA’s long-term global monitoring network, and in the tropical troposphere, using recent aircraft measurements - including high altitude observations from the NASA Global Hawk platform. The models generally capture the seasonal cycle of surface CHBr3 and CH2Br2 well, with a strong model-measurement correlation (r ≥ 0.7) and a low sensitivity to the choice of emission inventory, at most sites. In a given model, the absolute model-measurement agreement is highly sensitive to the choice of emissions and inter-model differences are also apparent, even when using the same inventory, highlighting the challenges faced in evaluating such inventories at the global scale. Across the ensemble, most consistency is found within the tropics where most of the models (8 out of 11) achieve optimal agreement to surface CHBr3 observations using the lowest of the three CHBr3 emission inventories tested (similarly, 8 out of 11 models for CH2 Br2). In general, the models are able to rep

Published
2016
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33. A potential marine source for stratospheric sulphur?

Author

Tegtmeier, Susann, Krüger, Kirstin, Marandino, Christa A., Patra, P., Atlas, E. L., Schlundt, Cathleen, Tegtmeier, Susann, Krüger, Kirstin, Marandino, Christa A., Patra, P., Atlas, E. L., and Schlundt, Cathleen

Published
2016

34. A multi-model intercomparison of halogenated very short-lived substances (TransCom-VSLS): linking oceanic emissions and tropospheric transport for a reconciled estimate of the stratospheric source gas injection of bromine

Author

Hossaini, R., primary, Patra, P. K., additional, Leeson, A. A., additional, Krysztofiak, G., additional, Abraham, N. L., additional, Andrews, S. J., additional, Archibald, A. T., additional, Aschmann, J., additional, Atlas, E. L., additional, Belikov, D. A., additional, Bönisch, H., additional, Carpenter, L. J., additional, Dhomse, S., additional, Dorf, M., additional, Engel, A., additional, Feng, W., additional, Fuhlbrügge, S., additional, Griffiths, P. T., additional, Harris, N. R. P., additional, Hommel, R., additional, Keber, T., additional, Krüger, K., additional, Lennartz, S. T., additional, Maksyutov, S., additional, Mantle, H., additional, Mills, G. P., additional, Miller, B., additional, Montzka, S. A., additional, Moore, F., additional, Navarro, M. A., additional, Oram, D. E., additional, Pfeilsticker, K., additional, Pyle, J. A., additional, Quack, B., additional, Robinson, A. D., additional, Saikawa, E., additional, Saiz-Lopez, A., additional, Sala, S., additional, Sinnhuber, B.-M., additional, Taguchi, S., additional, Tegtmeier, S., additional, Lidster, R. T., additional, Wilson, C., additional, and Ziska, F., additional

Published
2016
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36. Halocarbon emissions and sources in the equatorial Atlantic Cold Tongue

Author

Hepach, Helmke, Quack, Birgit, Raimund, Stefan, Fischer, Tim, Atlas, E. L., Bracher, A., Hepach, Helmke, Quack, Birgit, Raimund, Stefan, Fischer, Tim, Atlas, E. L., and Bracher, A.

Abstract

Halocarbons from oceanic sources contribute to halogens in the troposphere, and can be transported into the stratosphere where they take part in ozone depletion. This paper presents distribution and sources in the equatorial Atlantic from June and July 2011 of the four compounds bromoform (CHBr3), dibromomethane (CH2Br2), methyl iodide (CH3I) and diiodomethane (CH2I2). Enhanced biological production during the Atlantic Cold Tongue (ACT) season, indicated by phytoplankton pigment concentrations, led to elevated concentrations of CHBr3 of up to 44.7 and up to 9.2 pmol L−1 for CH2Br2 in surface water, which is comparable to other tropical upwelling systems. While both compounds correlated very well with each other in the surface water, CH2Br2 was often more elevated in greater depth than CHBr3, which showed maxima in the vicinity of the deep chlorophyll maximum. The deeper maximum of CH2Br2 indicates an additional source in comparison to CHBr3 or a slower degradation of CH2Br2. Concentrations of CH3I of up to 12.8 pmol L−1 in the surface water were measured. In contrary to expectations of a predominantly photochemical source in the tropical ocean, its distribution was mostly in agreement with biological parameters, indicating a biological source. CH2I2 was very low in the near surface water with maximum concentrations of only 3.7 pmol L−1. CH2I2 showed distinct maxima in deeper waters similar to CH2Br2. For the first time, diapycnal fluxes of the four halocarbons from the upper thermocline into and out of the mixed layer were determined. These fluxes were low in comparison to the halocarbon sea-to-air fluxes. This indicates that despite the observed maximum concentrations at depth, production in the surface mixed layer is the main oceanic source for all four compounds and one of the main driving factors of their emissions into the atmosphere in the ACT-region. The calculated production rates of the compounds in the mixed layer are 34 ± 65 pmol m−3 h−1 for CHBr3, 10 ± 1

Published
2015
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39. Bimodal distribution of free tropospheric ozone over the tropical western Pacific revealed by airborne observations

Author

Pan, L. L., primary, Honomichl, S. B., additional, Randel, W. J., additional, Apel, E. C., additional, Atlas, E. L., additional, Beaton, S. P., additional, Bresch, J. F., additional, Hornbrook, R., additional, Kinnison, D. E., additional, Lamarque, J.‐F., additional, Saiz‐Lopez, A., additional, Salawitch, R. J., additional, and Weinheimer, A. J., additional

Published
2015
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40. Drivers of diel and regional variations of halocarbon emissions from the tropical North East Atlantic

Author

Hepach, Helmke, Quack, B., Ziska, F., Fuhlbrügge, S, Atlas, E. L., Krüger, K., Peeken, Ilka, Wallace, D. W. R., Hepach, Helmke, Quack, B., Ziska, F., Fuhlbrügge, S, Atlas, E. L., Krüger, K., Peeken, Ilka, and Wallace, D. W. R.

Abstract

Methyl iodide (CH3I), bromoform (CHBr3) and dibromomethane (CH2Br2), which are produced naturally in the oceans, take part in ozone chemistry both in the troposphere and the stratosphere. The significance of oceanic upwelling regions for emissions of these trace gases in the global context is still uncertain although they have been identified as important source regions. To better quantify the role of upwelling areas in current and future climate, this paper analyzes major factors that influenced halocarbon emissions from the tropical North East Atlantic including the Mauritanian upwelling during the DRIVE expedition. Diel and regional variability of oceanic and atmospheric CH3I, CHBr3 and CH2Br2 was determined along with biological and physical parameters at six 24 h-stations. Low oceanic concentrations of CH3I from 0.1–5.4 pmol L−1 were equally distributed throughout the investigation area. CHBr3 and CH2Br2 from 1.0 to 42.4 pmol L−1 and to 9.4 pmol L−1, respectively were measured with maximum concentrations close to the Mauritanian coast. Atmospheric CH3I, CHBr3, and CH2Br2 of up to 3.3, 8.9, and 3.1 ppt, respectively were detected above the upwelling, as well as up to 1.8, 12.8, and 2.2 ppt at the Cape Verdean coast. While diel variability in CH3I emissions could be mainly ascribed to oceanic non-biological production, no main driver was identified for its emissions over the entire study region. In contrast, biological parameters showed the greatest influence on the regional distribution of sea-to-air fluxes of bromocarbons. The diel impact of wind speed on bromocarbon emissions increased with decreasing distance to the coast. The height of the marine atmospheric boundary layer (MABL) influenced halocarbon emissions via its influence on atmospheric mixing ratios. Oceanic and atmospheric halocarbons correlated well in the study region, and in combination with high oceanic CH3I, CHBr3 and CH2Br2 concentrations, local hot spots of atmospheric halocarbons could solel

Published
2014

41. Total Observed Organic Carbon (TOOC): A synthesis of North American observations

Author

Heald, C. L., Goldstein, A. H., Allan, J. D., Aiken, A. C., Apel, E., Atlas, E. L., Baker, A. K., Bates, T. S., Beyersdorf, A. J., Blake, D. R., Campos, T., Coe, H., Crounse, J. D., Decarlo, P. F., De Gouw, J. A., Dunlea, E. J., Flocke, F. M., Fried, A., Goldan, P., Griffin, R. J., Herndon, S. C., Holloway, J. S., Holzinger, R., Jimenez, J. L., Junkermann, W., Kuster, W. C., Lewis, A. C., Meinardi, S., Millet, D. B., Onasch, T., Polidori, A., Quinn, P. K., Riemer, D. D., Roberts, J. M., Salcedo, D., Sive, B., Swanson, A. L., Talbot, R., Warneke, C., Weber, R. J., Weibring, P., Wennberg, P. O., Wittig, A. E., Zhang, R., Zheng, J., Zheng, W., Department of Environmental Science and Policy Management, University of California, School of Earth, Atmospheric and Environmental Sciences, Department of Atmospheric and Oceanic Sciences [Boulder] ( ATOC ), University of Colorado Boulder [Boulder], Cooperative Institute for Research in Environmental Sciences ( CIRES ), University of Colorado Boulder [Boulder]-National Oceanic and Atmospheric Administration ( NOAA ), Atmospheric Chemistry Division [Boulder], National Center for Atmospheric Research [Boulder] ( NCAR ), Marine and Atmospheric Chemistry Division [Miami], Rosenstiel School of Marine and Atmospheric Science ( RSMAS ), University of Miami [Coral Gables]-University of Miami [Coral Gables], Department of Chemistry, NOAA Pacific Marine Environmental Laboratory [Seattle] ( PMEL ), National Oceanic and Atmospheric Administration ( NOAA ), California Institute of Technology ( CALTECH ), ESRL Chemical Sciences Division [Boulder] ( CSD ), NOAA Earth System Research Laboratory ( ESRL ), National Oceanic and Atmospheric Administration ( NOAA ) -National Oceanic and Atmospheric Administration ( NOAA ), Institute for Study of Earth, Oceans and Space, University of New Hampshire ( UNH ), Aerodyne Research Inc., Institute for Marine and Atmospheric Research [Utrecht] ( IMAU ), Utrecht University [Utrecht], Forschungszentrum Karlsruhe, Department of Chemistry [York, UK], University of York [York, UK], Department of Soil, Water and Climate, Department of Civil and Environmental Engineering, University of Southern California ( USC ), Centro de Investigaciones Químicas, Universidad Autónoma del Estado de Morelos, Northrop Grumman Space Technology ( Northrop Grumman Space Technology ), Chemistry Technology Department, School of Earth and Atmospheric Sciences [Atlanta], Georgia Institute of Technology [Atlanta], Department of Civil Engineering, The City College of New York ( CCNY ), City University of New-York [New-York] ( CUNY ) -City University of New-York [New-York] ( CUNY ), Department of Atmospheric Sciences [College Station], Texas A&M University [College Station], Department of Environmental Science, Policy, and Management [Berkeley] (ESPM), University of California [Berkeley], University of California-University of California, School of Earth, Atmospheric and Environmental Sciences [Manchester] (SEAES), University of Manchester [Manchester], Department of Atmospheric and Oceanic Sciences [Boulder] (ATOC), University of Colorado [Boulder], Cooperative Institute for Research in Environmental Sciences (CIRES), University of Colorado [Boulder]-National Oceanic and Atmospheric Administration (NOAA), National Center for Atmospheric Research [Boulder] (NCAR), Rosenstiel School of Marine and Atmospheric Science (RSMAS), NOAA Pacific Marine Environmental Laboratory [Seattle] (PMEL), National Oceanic and Atmospheric Administration (NOAA), California Institute of Technology (CALTECH), ESRL Chemical Sciences Division [Boulder] (CSD), NOAA Earth System Research Laboratory (ESRL), National Oceanic and Atmospheric Administration (NOAA)-National Oceanic and Atmospheric Administration (NOAA), University of New Hampshire (UNH), Institute for Marine and Atmospheric Research [Utrecht] (IMAU), Department of Soil, Water and Climate, University of Minnesota [Twin Cities] (UMN), University of Minnesota System-University of Minnesota System, University of Southern California (USC), Universidad Autonoma del Estado de Morelos (UAEM), Northrop Grumman Space Technology (Northrop Grumman Space Technology), The City College of New York (CCNY), and City University of New York [New York] (CUNY)-City University of New York [New York] (CUNY)

Subjects
[SDU.OCEAN]Sciences of the Universe [physics]/Ocean, Atmosphere, [ SDU.OCEAN ] Sciences of the Universe [physics]/Ocean, Atmosphere, 010504 meteorology & atmospheric sciences, 13. Climate action, 010501 environmental sciences, 01 natural sciences, Caltech Library Services, 0105 earth and related environmental sciences
Abstract

Measurements of organic carbon compounds in both the gas and particle phases measured upwind, over and downwind of North America are synthesized to examine the total observed organic carbon (TOOC) over this region. These include measurements made aboard the NOAA WP-3 and BAe-146 aircraft, the NOAA research vessel Ronald H. Brown, and at the Thompson Farm and Chebogue Point surface sites during the summer 2004 ICARTT campaign. Both winter and summer 2002 measurements during the Pittsburgh Air Quality Study are also included. Lastly, the spring 2002 observations at Trinidad Head, CA, surface measurements made in March 2006 in Mexico City and coincidentally aboard the C-130 aircraft during the MILAGRO campaign and later during the IMPEX campaign off the northwestern United States are incorporated. Concentrations of TOOC in these datasets span more than two orders of magnitude. The daytime mean TOOC ranges from 4.0 to 456 μgC m−3 from the cleanest site (Trinidad Head) to the most polluted (Mexico City). Organic aerosol makes up 3–17% of this mean TOOC, with highest fractions reported over the northeastern United States, where organic aerosol can comprise up to 50% of TOOC. Carbon monoxide concentrations explain 46 to 86% of the variability in TOOC, with highest TOOC/CO slopes in regions with fresh anthropogenic influence, where we also expect the highest degree of mass closure for TOOC. Correlation with isoprene, formaldehyde, methyl vinyl ketene and methacrolein also indicates that biogenic activity contributes substantially to the variability of TOOC, yet these tracers of biogenic oxidation sources do not explain the variability in organic aerosol observed over North America. We highlight the critical need to develop measurement techniques to routinely detect total gas phase VOCs, and to deploy comprehensive suites of TOOC instruments in diverse environments to quantify the ambient evolution of organic carbon from source to sink.

Published
2007

42. The CO2 tracer clock for the Tropical Tropopause Layer

Author

Park, S., Jiménez, R., Daube, B. C., Pfister, L., Conway, T. J., Gottlieb, E. W., Chow, V. Y., Curran, D. J., Matross, D. M., Bright, A., Atlas, E. L., Bui, T. P., Gao, R.-S., Twohy, C. H., Wofsy, S. C., Department of Earth and Planetary Sciences [Cambridge, USA] (EPS), Harvard University [Cambridge], Harvard John A. Paulson School of Engineering and Applied Sciences (SEAS), NASA Ames Research Center (ARC), NOAA Earth System Research Laboratory (ESRL), National Oceanic and Atmospheric Administration (NOAA), Rosenstiel School of Marine and Atmospheric Science (RSMAS), University of Miami [Coral Gables], NOAA Aeronomy Laboratory, Oregon State University (OSU), and EGU, Publication

Subjects
[SDU.OCEAN]Sciences of the Universe [physics]/Ocean, Atmosphere, [SDU.OCEAN] Sciences of the Universe [physics]/Ocean, Atmosphere
Abstract

International audience; Observations of CO2 were made in the upper troposphere and lower stratosphere in the deep tropics in order to determine the patterns of large-scale vertical transport and age of air in the Tropical Tropopause Layer (TTL). Flights aboard the NASA WB-57F aircraft over Central America and adjacent ocean areas took place in January and February, 2004 (Pre-AURA Validation Experiment, Pre-AVE) and 2006 (Costa Rice AVE, CR-AVE), and for the same flight dates of 2006, aboard the Proteus aircraft from the surface to 15 km over Darwin, Australia (Tropical Warm Pool International Cloud Experiment, TWP-ICE). The data demonstrate that the TTL is composed of two layers with distinctive features: (1) the lower TTL, 350?360 K (potential temperature(?); approximately 12?14 km), is subject to inputs of convective outflows, as indicated by layers of variable CO2 concentrations, with air parcels of zero age distributed throughout the layer; (2) the upper TTL, from ?=~360 K to ~390 K (14?18 km), ascends slowly and ages uniformly, as shown by a linear decline in CO2 mixing ratio tightly correlated with altitude, associated with increasing age. This division is confirmed by ensemble trajectory analysis. The CO2 concentration at the level of 360 K was 380.0(±0.2) ppmv, indistinguishable from surface site values in the Intertropical Convergence Zone (ITCZ) for the flight dates. Values declined with altitude to 379.2(±0.2) ppmv at 390 K, implying that air in the upper TTL monotonically ages while ascending. In combination with the winter slope of the CO2 seasonal cycle (+10.8±0.4 ppmv/yr), the vertical gradient of ?0.78 (±0.09) ppmv gives a mean age of 26(±3) days for the air at 390 K and a mean ascent rate of 1.5(±0.3) mm s?1. The TTL near 360 K in the Southern Hemisphere over Australia is very close in CO2 composition to the TTL in the Northern Hemisphere over Costa Rica, with strong contrasts emerging at lower altitudes (2 observed unexpected input from deep convection over Amazônia deep into the TTL. The CO2 data confirm the operation of a highly accurate tracer clock in the TTL that provides a direct measure of the ascent rate of the TTL and of the age of air entering the stratosphere.

Published
2007

44. Dimethylsulphide (DMS) emissions from the West Pacific Ocean: a potential marine source for the stratospheric sulphur layer

Author

Marandino, Christa, Tegtmeier, Susann, Krüger, Kirstin, Zindler, Cathleen, Atlas, E. L., Moore, F., Bange, Hermann W., Marandino, Christa, Tegtmeier, Susann, Krüger, Kirstin, Zindler, Cathleen, Atlas, E. L., Moore, F., and Bange, Hermann W.

Abstract

Sea surface and atmospheric measurements of dimethylsulphide (DMS) were performed during the TransBrom cruise in the western Pacific Ocean between Japan and Australia in October 2009. Air–sea DMS fluxes were computed between 0 and 30 μmol m−2 d−1, which are in agreement with those computed by the current climatology, and peak emissions of marine DMS into the atmosphere were found during the occurrence of tropical storm systems. Atmospheric variability in DMS, however, did not follow that of the computed fluxes and was more related to atmospheric transport processes. The computed emissions were used as input fields for the Lagrangian dispersion model FLEXPART, which was set up with actual meteorological fields from ERA-Interim data and different chemical lifetimes of DMS. A comparison with aircraft in situ data from the adjacent HIPPO2 campaign revealed an overall good agreement between modelled versus observed DMS profiles over the tropical western Pacific Ocean. Based on observed DMS emissions and meteorological fields along the cruise track, the model projected that up to 30 g S per month in the form of DMS, emitted from an area of 6 × 104 m2, can be transported above 17 km. This surprisingly large DMS entrainment into the stratosphere is disproportionate to the regional extent of the area of emissions and mainly due to the high convective activity in this region as simulated by the transport model. Thus, if DMS can cross the tropical tropopause layer (TTL), we suggest that the considerably larger area of the tropical western Pacific Ocean can be a source of sulphur to the stratosphere, which has not been considered as yet.

Published
2013

46. Emission and transport of bromocarbons: from the West Pacific ocean into the stratosphere

Author

Tegtmeier, Susann, Krüger, Kirstin, Quack, Birgit, Atlas, E. L., Pisso, I., Stohl, A., Yang, X., Tegtmeier, Susann, Krüger, Kirstin, Quack, Birgit, Atlas, E. L., Pisso, I., Stohl, A., and Yang, X.

Abstract

Oceanic emissions of halogenated very short-lived substances (VSLS) are expected to contribute significantly to the stratospheric halogen loading and therefore to ozone depletion. The amount of VSLS transported into the stratosphere is estimated based on in-situ observations around the tropical tropopause layer (TTL) and on modeling studies which mostly use prescribed global emission scenarios to reproduce observed atmospheric concentrations. In addition to upper-air VSLS measurements, direct observations of oceanic VSLS emissions are available along ship cruise tracks. Here we use such in-situ observations of VSLS emissions from the West Pacific and tropical Atlantic together with an atmospheric Lagrangian transport model to estimate the direct contribution of bromoform (CHBr3), and dibromomethane (CH2Br2) to the stratospheric bromine loading as well as their ozone depletion potential. Our emission-based estimates of VSLS profiles are compared to upper-air observations and thus link observed oceanic emissions and in situ TTL measurements. This comparison determines how VSLS emissions and transport in the cruise track regions contribute to global upper-air VSLS estimates. The West Pacific emission-based profiles and the global upper-air observations of CHBr3 show a relatively good agreement indicating that emissions from the West Pacific provide an average contribution to the global CHBr3 budget. The tropical Atlantic, although also being a CHBr3 source region, is of less importance for global upper-air CHBr3 estimates as revealed by the small emission-based abundances in the TTL. Western Pacific CH2Br2 emission-based estimates are considerably smaller than upper-air observations as a result of the relatively low sea-to-air flux found in the West Pacific. Together, CHBr3 and CH2Br2 emissions from the West Pacific are projected to contribute to the stratospheric bromine budget with 0.4 pptv Br on average and 2.3 pptv Br for cases of maximum emissions through product

Published
2012
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47. Halogenated VSLS emissions from the Mauritanian upwelling

Author

Hepach, Helmke, Fuhlbruegge, Steffen, Atlas, E. L., Wittke, Franziska, Krüger, Kirstin, Wallace, Douglas W.R., Quack, Birgit, Hepach, Helmke, Fuhlbruegge, Steffen, Atlas, E. L., Wittke, Franziska, Krüger, Kirstin, Wallace, Douglas W.R., and Quack, Birgit

Published
2012

48. Estimating the climate significance of halogen-driven ozone loss in the tropical marine troposphere

Author

Department of Energy (US), National Science Foundation (US), National Center for Atmospheric Research (US), Saiz-Lopez, A., Lamarque, Jean-François, Kinnison, Douglas E., Tilmes, S., Ordóñez, C., Orlando, J. J., Conley, A. J., Plane, John M.C., Mahajan, Anoop S., Sousa Santos, G., Atlas, E. L., Blake, D. R., Sander, S. P., Schauffler, S., Thompson, A. M., Brasseur, Guy, Department of Energy (US), National Science Foundation (US), National Center for Atmospheric Research (US), Saiz-Lopez, A., Lamarque, Jean-François, Kinnison, Douglas E., Tilmes, S., Ordóñez, C., Orlando, J. J., Conley, A. J., Plane, John M.C., Mahajan, Anoop S., Sousa Santos, G., Atlas, E. L., Blake, D. R., Sander, S. P., Schauffler, S., Thompson, A. M., and Brasseur, Guy

Abstract

We have integrated observations of tropospheric ozone, very short-lived (VSL) halocarbons and reactive iodine and bromine species from a wide variety of tropical data sources with the global CAM-Chem chemistry-climate model and offline radiative transfer calculations to compute the contribution of halogen chemistry to ozone loss and associated radiative impact in the tropical marine troposphere. The inclusion of tropospheric halogen chemistry in CAM-Chem leads to an annually averaged depletion of around 10% (∼2.5 Dobson units) of the tropical tropospheric ozone column, with largest effects in the middle to upper troposphere. This depletion contributes approximately-0.10 W m -2 to the radiative flux at the tropical tropopause. This negative flux is of similar magnitude to the ∼0.33 W m∼2 contribution of tropospheric ozone to present-day radiative balance as recently estimated from satellite observations. We find that the implementation of oceanic halogen sources and chemistry in climate models is an important component of the natural background ozone budget and we suggest that it needs to be considered when estimating both preindustrial ozone baseline levels and long term changes in tropospheric ozone. © 2012 Author(s).

Published
2012

50. Assessing the effect of marine isoprene and ship emissions on ozone, using modelling and measurements from the South Atlantic Ocean

Author

Williams, J., Custer, T., Riede, H., Sander, R., Joeckel, P., Hoor, P., Pozzer, A., Wong-zehnpfennig, S., Beygi, Z. Hosaynali, Fischer, H., Gros, V., Colomb, A., Bonsang, B., Yassaa, N., Peeken, I., Atlas, E. L., Waluda, C. M., Van Aardenne, J. A., Lelieveld, J., Williams, J., Custer, T., Riede, H., Sander, R., Joeckel, P., Hoor, P., Pozzer, A., Wong-zehnpfennig, S., Beygi, Z. Hosaynali, Fischer, H., Gros, V., Colomb, A., Bonsang, B., Yassaa, N., Peeken, I., Atlas, E. L., Waluda, C. M., Van Aardenne, J. A., and Lelieveld, J.

Abstract

Ship-borne measurements have been made in air over the remote South Atlantic and Southern Oceans in January-March 2007. This cruise encountered a large-scale natural phytoplankton bloom emitting reactive hydrocarbons (e. g. isoprene); and a high seas squid fishing fleet emitting NOx (NO and NO2). Using an atmospheric chemistry box model constrained by in-situ measurements, it is shown that enhanced ozone production ensues from such juxtaposed marine biogenic and anthropogenic emissions. The relative impact of shipping and phytoplankton emissions on ozone was examined on a global scale using the EMAC model. Ozone in the marine boundary layer was found to be over ten times more sensitive to NOx emissions from ships, than to marine isoprene in the region south of 45 degrees. Although marine isoprene emissions make little impact on the global ozone budget, co-located ship and phytoplankton emissions may explain the increasing ozone reported for the 40-60 degrees S southern Atlantic region.

Published
2010
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