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1. Atmospheric implications of large C2-C5 alkane emissions from the U.S. oil and gas industry.

Author

Tzompa-Sosa, ZA, Henderson, BH, Keller, CA, Travis, K, Mahieu, E, Franco, B, Estes, M, Helmig, D, Fried, A, Richter, D, Weibring, P, Walega, J, Blake, DR, Hannigan, JW, Ortega, I, Conway, S, Strong, K, and Fischer, EV

Subjects
Climate Action, Atmospheric Sciences, Physical Geography and Environmental Geoscience
Abstract

Emissions of C2-C5 alkanes from the U.S. oil and gas sector have changed rapidly over the last decade. We use a nested GEOS-Chem simulation driven by updated 2011NEI emissions with aircraft, surface and column observations to 1) examine spatial patterns in the emissions and observed atmospheric abundances of C2-C5 alkanes over the U.S., and 2) estimate the contribution of emissions from the U.S. oil and gas industry to these patterns. The oil and gas sector in the updated 2011NEI contributes over 80% of the total U.S. emissions of ethane (C2H6) and propane (C3H8), and emissions of these species are largest in the central U.S. Observed mixing ratios of C2-C5 alkanes show enhancements over the central U.S. below 2 km. A nested GEOS-Chem simulation underpredicts observed C3H8 mixing ratios in the boundary layer over several U.S. regions and the relative underprediction is not consistent, suggesting C3H8 emissions should receive more attention moving forward. Our decision to consider only C4-C5 alkane emissions as a single lumped species produces a geographic distribution similar to observations. Due to the increasing importance of oil and gas emissions in the U.S., we recommend continued support of existing long-term measurements of C2-C5 alkanes. We suggest additional monitoring of C2-C5 alkanes downwind of northeastern Colorado, Wyoming and western North Dakota to capture changes in these regions. The atmospheric chemistry modeling community should also evaluate whether chemical mechanisms that lump larger alkanes are sufficient to understand air quality issues in regions with large emissions of these species.

Published
2019

3. Revisiting global fossil fuel and biofuel emissions of ethane

Author

Tzompa‐Sosa, ZA, Mahieu, E, Franco, B, Keller, CA, Turner, AJ, Helmig, D, Fried, A, Richter, D, Weibring, P, Walega, J, Yacovitch, TI, Herndon, SC, Blake, DR, Hase, F, Hannigan, JW, Conway, S, Strong, K, Schneider, M, and Fischer, EV

Subjects
Climate Action, Atmospheric Sciences, Physical Geography and Environmental Geoscience
Abstract

Recent measurements over the Northern Hemisphere indicate that the long-term decline in the atmospheric burden of ethane (C2H6) has ended and the abundance increased dramatically between 2010 and 2014. The rise in C2H6 atmospheric abundances has been attributed to oil and natural gas extraction in North America. Existing global C2H6 emission inventories are based on outdated activity maps that do not account for current oil and natural gas exploitation regions. We present an updated global C2H6 emission inventory based on 2010 satellite-derived CH4 fluxes with adjusted C2H6 emissions over the U.S. from the National Emission Inventory (NEI 2011). We contrast our global 2010 C2H6 emission inventory with one developed for 2001. The C2H6 difference between global anthropogenic emissions is subtle (7.9 versus 7.2 Tg yr-1), but the spatial distribution of the emissions is distinct. In the 2010 C2H6 inventory, fossil fuel sources in the Northern Hemisphere represent half of global C2H6 emissions and 95% of global fossil fuel emissions. Over the U.S., unadjusted NEI 2011 C2H6 emissions produce mixing ratios that are 14-50% of those observed by aircraft observations (2008-2014). When the NEI 2011 C2H6 emission totals are scaled by a factor of 1.4, the Goddard Earth Observing System Chem model largely reproduces a regional suite of observations, with the exception of the central U.S., where it continues to underpredict observed mixing ratios in the lower troposphere. We estimate monthly mean contributions of fossil fuel C2H6 emissions to ozone and peroxyacetyl nitrate surface mixing ratios over North America of ~ 1% and ~8%, respectively.

Published
2017

4. Ubiquitous atmospheric production of organic acids mediated by cloud droplets

Author

Franco, B., Blumenstock, T., Cho, C., Clarisse, L., Clerbaux, C., Coheur, P.-F., De Mazière, M., De Smedt, I., Dorn, H.-P., Emmerichs, T., Fuchs, H., Gkatzelis, G., Griffith, D. W. T., Gromov, S., Hannigan, J. W., Hase, F., Hohaus, T., Jones, N., Kerkweg, A., Kiendler-Scharr, A., Lutsch, E., Mahieu, E., Novelli, A., Ortega, I., Paton-Walsh, C., Pommier, M., Pozzer, A., Reimer, D., Rosanka, S., Sander, R., Schneider, M., Strong, K., Tillmann, R., Van Roozendael, M., Vereecken, L., Vigouroux, C., Wahner, A., and Taraborrelli, D.

Published
2021
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9. Validation of OMPS Suomi NPP and OMPS NOAA‐20 Formaldehyde Total Columns With NDACC FTIR Observations

Author

Kwon, H.‐A., primary, Abad, G. González, additional, Nowlan, C. R., additional, Chong, H., additional, Souri, A. H., additional, Vigouroux, C., additional, Röhling, A., additional, Kivi, R., additional, Makarova, M., additional, Notholt, J., additional, Palm, M., additional, Winkler, H., additional, Té, Y., additional, Sussmann, R., additional, Rettinger, M., additional, Mahieu, E., additional, Strong, K., additional, Lutsch, E., additional, Yamanouchi, S., additional, Nagahama, T., additional, Hannigan, J. W., additional, Zhou, M., additional, Murata, I., additional, Grutter, M., additional, Stremme, W., additional, De Mazière, M., additional, Jones, N., additional, Smale, D., additional, and Morino, I., additional

Published
2023
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14. Exceptional Wildfire Enhancements of PAN, C2H4, CH3OH, and HCOOH Over the Canadian High Arctic During August 2017.

Author

Wizenberg, T., Strong, K., Jones, D. B. A., Lutsch, E., Mahieu, E., Franco, B., and Clarisse, L.

Subjects
WILDFIRE prevention, ATMOSPHERIC carbon monoxide, FOREST fires, SMOKE plumes, WILDFIRES, AIR pollution, PEROXYACETYL nitrate
Abstract

Extreme enhancements in the total columns of carbon monoxide (CO), peroxyacetyl nitrate (PAN), ethylene (C2H4), methanol (CH3OH), and formic acid (HCOOH) were observed over the Canadian high Arctic during the period of 17–22 August 2017 by a ground‐based Fourier transform infrared (FTIR) spectrometer at Eureka, Nunavut (80.05°N, 86.42°W), and by the Infrared Atmospheric Sounding Interferometer (IASI) satellite instruments. These enhancements have been attributed to wildfires in British Columbia (BC) and the Northwest Territories (NWT) of Canada, and represent the largest short‐term perturbations of PAN, C2H4, and HCOOH above ambient concentrations over the 14‐year (2006–2020) Eureka time‐series. Enhancement ratios, emission ratios, and emission factors relative to CO were calculated for all species for both FTIR and IASI observations. The C2H4 and HCOOH emission factors are significantly larger than previous studies, suggesting unusually high emissions from these fires. The wildfire plumes were also simulated using the GEOS‐Chem model. Initial GEOS‐Chem simulations displayed a severe under‐estimation relative to observations for these fire plumes resulting from the injection height scheme of the model. Sensitivity tests highlighted that injection heights of 12.5 km for BC (based on previous studies) and 10 km for the NWT fires yielded the strongest correlations with ground‐based measurements. Applying these injection heights to the model significantly improves the simulated plume transport and agreement with ground‐ and space‐based observations. GEOS‐Chem was also used to estimate the magnitude of secondary in‐plume production of CH3OH and HCOOH; it was found to be an important component (∼18%) of the enhanced HCOOH columns at Eureka. Plain Language Summary: Wildfires are a significant natural source of pollution to the atmosphere. During mid‐August 2017, two extremely large wildfires occurred simultaneously in British Columbia (BC) and the Northwest Territories (NWT) of Canada. These fires produced an exceptional amount of smoke, which was subsequently transported to the Canadian high Arctic region. The atmospheric concentrations of carbon monoxide (CO), peroxyacetyl nitrate (PAN), ethylene (C2H4), methanol (CH3OH), and formic acid (HCOOH) contained within these transported smoke plumes were measured using both a ground‐based infrared spectrometer located at Eureka, Nunavut (80.05°N, 86.42°W) and satellite instruments. The largest concentrations of CO, PAN, C2H4, and HCOOH observed over the 14‐year measurement record (2006–2020) of the ground‐based spectrometer were due to these wildfires. The emissions of these fires were estimated from both the ground‐ and space‐based measurements and were found to be unusually high in comparison to previous studies. The wildfire smoke plumes were also simulated using a chemical transport model, but the model was found to inject the smoke too low into the atmosphere above the fires; after adjustments to the injection scheme were made, the agreement of the model with the measurements was significantly improved. Key Points: The 2017 Canadian wildfires produced the largest PAN, C2H4, and HCOOH column enhancements observed in the high Arctic from 2006 to 2020GEOS‐Chem effectively simulates the observed plume transport, but required modifications to the injection heights of the fire emissionsMid‐latitude wildfires may become an increasingly significant source of reactive VOC species to the high Arctic during the summer months [ABSTRACT FROM AUTHOR]

Published
2023
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15. Vertical Profiles and Transport of Ozone

Author

Bösenberg, Jens, Grabbe, G., Matthias, V., Schaberl, T., De Muer, D., Van Haver, Ph., De Backer, H., Trickl, T., Zander, R., Demoulin, Ph., Mahieu, E., Roland, G., Delbouille, L., Servais, C., Servais, H. G. J., Kley, D., Sträter, W., Borrell, Peter, editor, Borrell, Patricia M., editor, Cvitaš, Tomislav, editor, Kelly, Kerry, editor, Seiler, Wolfgang, editor, and Hov, Øystein, editor

Published
1997
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17. Recent Northern Hemisphere stratospheric HC1 increase due to atmospheric circulation changes

Author

Mahieu, E., Chipperfield, M.P., Notholt, J., Reddmann, T., Anderson, J., Bernath, P.F., Blumenstock, T., Coffey, M.T., Dhomse, S.S., Feng, W., Franco, B., Froidevaux, L., Griffith, D.W.T., Hannigan, J.W., Hase, F., Hossaini, R., Jones, N.B., Morino, I., Murata, I., Nakajima, H., Palm, M., Paton-Walsh, C., Russell, III, J.M., Schneider, M., Servais, C., Smale, D., and Walker, K.A.

Subjects
Northern Hemisphere -- Environmental aspects -- Research, Atmospheric circulation -- Environmental aspects -- Research, Stratospheric circulation -- Environmental aspects -- Research, Environmental issues, Science and technology, Zoology and wildlife conservation
Abstract

The abundance of chlorine in the Earth's atmosphere increased considerably during the 1970s to 1990s, following large emissions of anthropogenic long-lived chlorine-containing source gases, notably the chlorofluorocarbons. The chemical inertness of chlorofluorocarbons allows their transport and mixing throughout the troposphere on a global scale (1), before they reach the stratosphere where they release chlorine atoms that cause ozone depletion (2). The large ozone loss over Antarctica (3) was the key observation that stimulated the definition and signing in 1987 of the Montreal Protocol, an international treaty establishing a schedule to reduce the production of the major chlorine-and bromine-containing halocarbons. Owing to its implementation, the near-surface total chlorine concentration showed a maximum in 1993, followed by a decrease of half a per cent to one per cent per year (4), in line with expectations. Remote-sensing data have revealed a peak in stratospheric chlorine after 1996 (5), then a decrease of close to one per cent per year (6,7), in agreement with the surface observations of the chlorine source gases and model calculations (7). Here we present ground-based and satellite data that show a recent and significant increase, at the 2σ level, in hydrogen chloride (HC1), the main stratospheric chlorine reservoir, starting around 2007 in the lower stratosphere of the Northern Hemisphere, in contrast with the ongoing monotonic decrease of near-surface source gases. Using model simulations, we attribute this trend anomaly to a slowdown in the Northern Hemisphere atmospheric circulation, occurring over several consecutive years, transporting more aged air to the lower stratosphere, and characterized by a larger relative conversion of source gases to HC1. This short-term dynamical variability will also affect other stratospheric tracers and needs to be accounted for when studying the evolution of the stratospheric ozone layer., Decomposition of chlorine-containing source gases in the stratosphere produces HC1, the largest reservoir of chlorine (8,9). Here we investigate recent trends in atmospheric HC1 with observations from eight Network for [...]

Published
2014

19. Stratospheric Fluorine as a Tracer of Circulation Changes: Comparison Between Infrared Remote‐Sensing Observations and Simulations With Five Modern Reanalyses

Author

Prignon, M., primary, Chabrillat, S., additional, Friedrich, M., additional, Smale, D., additional, Strahan, S. E., additional, Bernath, P. F., additional, Chipperfield, M. P., additional, Dhomse, S. S., additional, Feng, W., additional, Minganti, D., additional, Servais, C., additional, and Mahieu, E., additional

Published
2021
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20. Stratospheric Fluorine as a Tracer of Circulation Changes: Comparison Between Infrared Remote-Sensing Observations and Simulations With Five Modern Reanalyses

Author

Prignon, M., Chabrillat, S., Friedrich, M., Smale, D., Strahan, S. E., Bernath, P. F., Chipperfield, M. P., Dhomse, S. S., Feng, W., Minganti, D., Servais, C., Mahieu, E., Prignon, M., Chabrillat, S., Friedrich, M., Smale, D., Strahan, S. E., Bernath, P. F., Chipperfield, M. P., Dhomse, S. S., Feng, W., Minganti, D., Servais, C., and Mahieu, E.

Abstract

Using multidecadal time series of ground-based and satellite Fourier transform infrared measurements of inorganic fluorine (i.e., total fluorine resident in stratospheric fluorine reservoirs), we investigate stratospheric circulation changes over the past 20 years. The representation of these changes in five modern reanalyses is further analyzed through chemical-transport model (CTM) simulations. From the observations but also from all reanalyses, we show that the inorganic fluorine is accumulating less rapidly in the Southern Hemisphere than in the Northern Hemisphere during the 21st century. Comparisons with a study evaluating the age-of-air of these reanalyses using the same CTM allow us to link this hemispheric asymmetry to changes in the Brewer-Dobson circulation (BDC), with the age-of-air of the Southern Hemisphere getting younger relative to that of the Northern Hemisphere. Large differences in simulated total columns and absolute trend values are, nevertheless, depicted between our simulations driven by the five reanalyses. Superimposed on this multidecadal change, we, furthermore, confirm a 5–7-year variability of the BDC that was first described in a recent study analyzing long-term time series of hydrogen chloride (HCl) and nitric acid (HNO3). It is important to stress that our results, based on observations and meteorological reanalyses, are in contrast with the projections of chemistry-climate models in response to the coupled increase of greenhouse gases and decrease of ozone-depleting substances, calling for further investigations and the continuation of long-term observations.

Published
2021
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23. A statistical analysis of time trends in atmospheric ethane

Author

Friedrich, M. (Marina), Beutner, E. (Eric), Reuvers, H. (Hanno), Smeekes, S. (Stephan), Urbain, J.-P. (Jean-Pierre), Bader, W. (Whitney), Franco, B. (Bruno), Lejeune, B. (Bernard), Mahieu, E. (Emmanuel), Friedrich, M. (Marina), Beutner, E. (Eric), Reuvers, H. (Hanno), Smeekes, S. (Stephan), Urbain, J.-P. (Jean-Pierre), Bader, W. (Whitney), Franco, B. (Bruno), Lejeune, B. (Bernard), and Mahieu, E. (Emmanuel)

Abstract

Ethane is the most abundant non-methane hydrocarbon in the Earth’s atmosphere and an important precursor of tropospheric ozone through various chemical pathways. Ethane is also an indirect greenhouse gas (global warming potential), influencing the atmospheric lifetime of methane through the consumption of the hydroxyl radical (OH). Understanding the development of trends and identifying trend reversals in atmospheric ethane is therefore crucial. Our dataset consists of four series of daily ethane columns. As with many other decadal time series, our data are characterized by autocorrelation, heteroskedasticity, and seasonal effects. Additionally, missing observations due to instrument failure or unfavorable measurement conditions are common in such series. The goal of this paper is therefore to analyze trends in atmospheric ethane with statistical tools that correctly address these data features. We present selected methods designed for the analysis of time trends and trend reversals. We consider bootstrap inference on broken linear trends and smoothly varying nonlinear trends. In particular, for the broken trend model, we propose a bootstrap method for inference on the break location and the corresponding changes in slope. For the smooth trend model, we construct simultaneous confidence bands around the nonparametrically estimated trend. Our autoregressive wild bootstrap approach, combined with a seasonal filter, is able to handle all issues mentioned above (we provide R code for all proposed methods on https://www.stephansmeekes.nl/code.).

Published
2020
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25. Spaceborne Measurements of Formic and Acetic Acids: A Global View of the Regional Sources

Author

Franco, Bruno, Clarisse, L, Stavrakou, T, Müller, J, Taraborrelli, D, Hadji-Lazaro, J, Hannigan, J, Hase, Frank, Hurtmans, D, Jones, Nicholas B, Lutsch, E, Mahieu, E, Ortega, I, Schneider, Michael, Strong, Kimberly, Vigouroux, C, Clerbaux, C, Coheur, P, Franco, Bruno, Clarisse, L, Stavrakou, T, Müller, J, Taraborrelli, D, Hadji-Lazaro, J, Hannigan, J, Hase, Frank, Hurtmans, D, Jones, Nicholas B, Lutsch, E, Mahieu, E, Ortega, I, Schneider, Michael, Strong, Kimberly, Vigouroux, C, Clerbaux, C, and Coheur, P

Abstract

©2020. American Geophysical Union. All Rights Reserved. Formic (HCOOH) and acetic acids (CH3COOH) are the most abundant carboxylic acids in the Earth's atmosphere and key compounds to aqueous-phase chemistry. Here we present the first distributions of CH3COOH retrieved from the 2007–2018 satellite observations of the nadir-looking infrared atmospheric sounding interferometer (IASI), using a neural network-based retrieval approach. A joint analysis with the IASI HCOOH product reveals that the two species exhibit similar distributions, seasonality, and atmospheric burden, pointing to major common sources. We show that their abundance is highly correlated to isoprene and monoterpenes emissions, as well as to biomass burning. Over Africa, evidence is provided that residual smoldering combustion might be a major driver of the HCOOH and CH3COOH seasonality. Earlier seasonal enhancement of HCOOH at Northern Hemisphere middle and high latitudes and late seasonal secondary peaks of CH3COOH in the tropics suggest that sources and production pathways specific to each species are also at play.

Published
2020

26. Spaceborne Measurements of Formic and Acetic Acids: A Global View of the Regional Sources

Author

Franco, B., primary, Clarisse, L., additional, Stavrakou, T., additional, Müller, J.‐F., additional, Taraborrelli, D., additional, Hadji‐Lazaro, J., additional, Hannigan, J. W., additional, Hase, F., additional, Hurtmans, D., additional, Jones, N., additional, Lutsch, E., additional, Mahieu, E., additional, Ortega, I., additional, Schneider, M., additional, Strong, K., additional, Vigouroux, C., additional, Clerbaux, C., additional, and Coheur, P.‐F., additional

Published
2020
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36. Atmospheric Implications of Large C 2 ‐C 5 Alkane Emissions From the U.S. Oil and Gas Industry

Author

Tzompa‐Sosa, Z. A., primary, Henderson, B. H., additional, Keller, C. A., additional, Travis, K., additional, Mahieu, E., additional, Franco, B., additional, Estes, M., additional, Helmig, D., additional, Fried, A., additional, Richter, D., additional, Weibring, P., additional, Walega, J., additional, Blake, D. R., additional, Hannigan, J. W., additional, Ortega, I., additional, Conway, S., additional, Strong, K., additional, and Fischer, E. V., additional

Published
2019
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37. Polar Stratospheric Descent of NO(y) and CO and Arctic Denitrification During Winter 1992-1993

Author

Rinsland, C. P, Salawitch, R. J, Gunson, M. R, Solomon, S, Zander, R, Mahieu, E, Goldman, A, Newchurch, M. J, Irion, F. W, and Chang, A. Y

Subjects
Environment Pollution
Abstract

Observations inside the November 1994 Antarctic stratospheric vortex and inside the April 1993 remnant Arctic stratospheric vortex by the Atmospheric Trace Molecule Spectroscopy (ATMOS) Fourier transform spectrometer are reported. In both instances, elevated volume mixing ratios (VMRS) of carbon monoxide (CO) were measured. A peak Antarctic CO VMR of 60 ppbv (where 1 ppbv = 10(exp -9) per unit Volume) was measured at a potential temperature of 710 K (about 27 km), about 1 km below the altitude of a pocket of elevated NO(y) (total reactive nitrogen) at a deep minimum in N2O (<5 ppbv). The Arctic observations also show a region of elevated vortex CO with a peak VMR of 90 ppbv it 630-670 K (-25 km) but no corresponding enhancement in NO(sub y) perhaps because of stronger dynamical activity in the northern hemisphere polar winter and/or interannual variability in the production of mesospheric or lower thermospheric NO. By comparing vortex and extravortex observations of NO(y) obtained at the same N2O VMR, Arctic vortex denitrification of 5 +/- 2 ppbv at 470 K (at approximately 18 km) is inferred. We show that our conclusion of substantial Arctic winter 1992-1993 denitrification is robust by comparing our extravortex observations with previous polar measurements obtained over a wide range of winter conditions. Correlations of NO(y) with N2O measured at the same potential temperature by ATMOS in the Arctic vortex and at midlatitudes on board the ER-2 aircraft several weeks later lie along the same mixing line. The result demonstrates the consistency of the two data sets and confirms that the ER-2 sampled fragments of the denitrified Arctic vortex following its breakup. An analysis of the ATMOS Arctic measurements of total hydrogen shows no evidence for significant dehydration inside the vortex.

Published
1999
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39. ATMOS/ATLAS 3 Infrared Profile Measurements of Clouds in the Tropical and Subtropical Upper Troposphere

Author

Rinsland, C. P, Gunson, M. R, Wang, P.-H, Arduini, R. F, Baum, B. A, Minnis, P, Goldman, A, Abrams, M. C, Zander, R, Mahieu, E, Salawitch, R. J, Michelsen, H. A, Irion, F. W, and Newchurch, M. J

Subjects
Geophysics
Abstract

Vertical profiles of infrared cirrus extinction have been derived from tropical and subtropical upper tropospheric solar occultation spectra. The measurements were recorded by the Atmospheric Trace Molecule Spectroscopy (ATMOS) Fourier transform spectrometer during the Atmospheric Laboratory for Applications and Sciences (ATLAS) 3 shuttle flight in November 1994. The presence of large numbers of small ice crystals is inferred from the appearance of broad extinction features in the 8-12 micron region. These features were observed near the tropopause and at lower altitudes. Vertical profiles of the ice extinction (/km) in microwindows at 831, 957, and 1204/cm have been retrieved from the spectra and analyzed with a model for randomly oriented spheroidal ice crystals. An area-equivalent spherical radius of 6 microns is estimated from the smallest ice crystals observed in the 8-12 gm region. Direct penetration of clouds into the lower stratosphere is inferred from observations of cloud extinction extending from the upper troposphere to 50 mbar (20 km altitude). Cloud extinction between 3 and 5 microns shows very little wavelength dependence, at least for the cases observed by the ATMOS instrument in the tropics and subtropics during ATLAS 3.

Published
1998

40. Atmos/Atlas 3 Infrared Profile Measurements of Trace Gases in The November 1994 Tropical and Subtropical Upper Troposphere

Author

Rinsland, C. P, Gunson, M. R, Wang, P.-H, Arduini, R. F, Baum, B. A, Minnis, P, Goldman, A, Abrams, M. C, Zander, R, Mahieu, E, Salawitch, R. J, Michelsen, H. A, Irion, F. W, and Newchurch, M. J

Subjects
Geophysics
Abstract

Vertical mixing ratio profiles of four relatively long-lives gases, HCN, C2H2, CO, and C2H6, have been retrieved from 0.01/cm resolution infrared solar occultation spectra recorded between latitudes of 5.3degN and 31.4degN. The observations were obtained by the Atmospheric Trace Molecule Spectroscopy (ATMOS) Fourier transform spectrometer during the Atmospheric Laboratory for Applications and Science (ATLAS) 3 shuttle flight, 3-12 November 1994. Elevated mixing ratios below the tropopause were measured for these gases during several of the occultations. The positive correlations obtained between the simultaneously measured mixing ratios suggest that the enhancements are likely the result of surface emissions, most likely biomass burning and/or urban industrial activities, followed by common injection via deep convective transport of the gases to the upper troposphere. The elevated levels of HCN may account for at least part of the "missing NO," in the upper troposphere. Comparisons of the observations with values measured during a recent aircraft campaign are presented.

Published
1998
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41. The Atmospheric Trace Molecule Spectroscopy (ATMOS) Experiment: Deployment on the ATLAS Space Shuttle Missions

Author

Gunson, M. R, Abbas, M. M, Abrams, M. C, Allen, M, Brown, L. R, Brown, T. L, Chang, A. Y, Goldman, A, Irion, F. W, Lowes, L. L, Mahieu, E, Manney, G. L, Michelsen, H. A, Newchurch, M. J, Rinsland, C. P, Salawitch, R. J, Stiller, G. P, Toon, G. C, Yung, Y. L, and Zander, R

Subjects
Meteorology And Climatology
Abstract

The ATMOS Fourier transform spectrometer was flown for a fourth time on the Space Shuttle as part of the ATLAS-3 instrument payload in November 1994. More than 190 sunrise and sunset occultation events provided measurements of more than 30 atmospheric trace gases at latitudes 3 - 49 deg N and 65 - 72 deg S, including observations both inside and outside the Antarctic polar vortex. The instrument configuration, data retrieval methodology, and mission background are described to place in context analyses of ATMOS data presented in this issue.

Published
1996
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42. Trends of OCS, HCN, SF6, CHClF2 (HCFC-22) in the Lower Stratosphere from 1985 and 1994 Atmospheric Trace Molecule Spectroscopy Experiment Measurements Near 30 deg. North Latitude

Author

Rinsland, C. P, Mahieu, E, Zander, R, Gunson, M. R, Salawitch, R. J, Chang, A. Y, Goldman, A, Abrams, M. C, Abbas, M. M, Newchurch, M. J, and Irion, F. W

Subjects
Environment Pollution
Abstract

Volume mixing ratio (VMR) profiles of OCS, HCN, SF6, and CHClF2 (HCFC-22) have been measured near 30 deg N latitude by the Atmospheric Trace Molecule Spectroscopy Fourier transform spectrometer during shuttle flights on 29 April - 6 May 1985 and 3-2 November 1994. The change in the concentration of each molecule in the lower stratosphere has been derived for this 9 1/2-year period by comparing measurements between potential temperatures of 395 to 800 K (approximately 17 to 30 km altitude) relative to simultaneously measured values of the long-lived tracer N2O. Exponential rates of increase inferred for 1985-to 1994 from these comparisons are (0.1 plus or minus 0.4)% yr(exp-1) for OCS, (1.0 plus or minus 1.0)% yr(exp-1) for HCN, (8.0 +/- 0.7)% yr(exp-1) for SF6, and (8.0 +/- 1.0)% yr(exp-1) for CHClF2 (HCFC-22), 1 sigma. The lack of an appreciable trend for OCS suggests the background (i.e. nonvolcanic) source of stratospheric aerosol was the same during the two periods. These results are compared with trends reported in the literature.

Published
1996

43. Increase of Stratospheric Carbon Tetrafluoride (CF4) Based on ATMOS Observations from Space

Author

Zander, R, Solomon, S, Mahieu, E, Goldman, A, Rinsland, C. P, Gunson, M. R, Abrams, M. C, Chang, A. Y, Michelsen, H. A, Newchurch, M. J, and Stiller, G. P

Subjects
Environment Pollution
Abstract

Stratospheric volume mixing ratio profiles of carbon tetrafluoride, CF4, obtained with the Atmospheric Trace Molecule Spectroscopy (ATMOS) instrument during the ATLAS (Atmospheric Laboratory for Applications and Science) -3 mission of 1994 are reported. Overall the profiles are nearly constant over the altitude range 20 to 50 km, indicative of the very long lifetime of CF4 in the atmosphere. In comparison to the stratospheric values of CF4 inferred from the ATMOS/Spacelab 3 mission of 1985, the 1994 concentrations are consistent with an exponential increase of (1.6 +/- 0.6)% yr(exp -1). This increase is discussed with regard to previous results and likely sources of CF4 at the ground. Further, it is shown that simultaneous measurements of N2O and CF4 provide a means of constraining the lower limit of the atmospheric lifetime of CF4 at least 2,300 years, two sigma.

Published
1996

44. ATMOS/ATLAS-3 Measurements of Stratospheric Chlorine and Reactive Nitrogen Partitioning Inside and Outside the November 1994 Antarctic Vortex

Author

Rinsland, C. P, Gunson, M. R, Salawitch, R. J, Michelsen, H. A, Zander, R, Newchurch, M. J, Abbas, M. M, Abrams, M. C, Manney, G. L, Chang, A. Y, Irion, F. W, Goldman, A, and Mahieu, E

Subjects
Environment Pollution
Abstract

Partitioning between HCl and ClONO2 and among the main components of the reactive nitrogen family (NO, NO2, HNO3, ClONO2, N2O5, and HO2NO2) has been studied inside and outside the Antarctic stratospheric vortex based on ATMOS profiles measured at sunrise during the 3-12 November 1994 ATLAS-3 Shuttle mission. Elevated mixing ratios of HCl in the lower stratosphere with a peak of approximately 2.9 ppbv (10(exp -9) parts per volume) were measured inside the vortex near 500 K potential temperature (approximately 19 km). Maximum ClONO2 mixing ratios of approximately 1.2, approximately 1.4, and approximately 0.9 ppbv near 700 K (approximately 25 km) were measured inside, at the edge, and outside the vortex, respectively. Model calculations reproduce the higher levels of HCl and NO(x) (NO + NO2) inside the lower stratospheric vortex both driven by photochemical processes initiated by low O3. The high HCl at low O3 results from chemical production of HC1 via the reaction of enhanced Cl with CH4, limited production of ClONO2, and the descent of inorganic chlorine from higher altitudes.

Published
1996

49. The Atmospheric Trace Molecule Spectroscopy (ATMOS) Experiment: Deployment on the ATLAS Space Shuttle Missions

Author

Zander, R, Yung, Y. L, Toon, G. C, Stiller, G. P, Salawitch, R. J, Rinsland, C. P, Newchurch, M. J, Michelsen, H. A, Manney, G. L, Mahieu, E, Lowes, L. L, Irion, F. W, Goldman, A, Chang, A. Y, Brown, T. L, Brown, L. R, Allen, M, Abrams, M. C, Abbas, M. M, and Gunson, M. R

Abstract

The ATMOS Fourier transform spectrometer was flown for a fourth time on the Space Shuttle as part of the ATLAS-3 instrument payload in November 1994. More than 190 sunrise and sunset occultation events provided measurements of more than 30 atmospheric trace gases at latitudes 3-49N and 65-72S, including observations both inside and outside the Antarctic polar vortex.

Published
1996

50. Increase in Levels of Stratospheric Chlorine and Fluorine Loading between 1985 and 1992

Author

Gunson, M. R, Abrams, M. C, Lowes, L. L, Mahieu, E, Zander, R, Rinsland, C. P, Ko, M. K. W, Sze, N. D, and Weisenstein, D. K

Subjects
Environment Pollution
Abstract

Mixing ratios of 3.44 ppbv (parts per billion by volume) and 1.23 ppbv for HCl and HF above 50 km, surrogates for total chlorine and fluorine, have been measured by the Atmospheric Trace Molecule Spectroscopy (ATMOS) experiment on a March 1992 flight of the Space Shuttle. Compared to the measured values obtained on a 1985 flight, these correspond to a 37% and 62% increase for HCl and HF, respectively. The derived trend in HCl (approx. 0.13 ppbv per year) is in good agreement with the model-predicted increase in chlorine loading of 0.13 ppbv per year, and with the measured trends in HCl total column abundance from reported ground-based observations. The main source of this change can be attributed to the release of man-made chlorofluorocarbons (CFC's) and hydro-chloro-fluoro-carbons (HCFC's). This new value for HCl represents an upper limit to the inorganic chlorine concentration in the stratosphere available for participation in photochemical processes which destroy ozone.

Published
1994
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