Your search keyword '"Nicola J. Blake"' showing total 59 results

1. An investigation of petrochemical emissions during KORUS-AQ: Ozone production, reactive nitrogen evolution, and aerosol production

Author

Young Ro Lee, L. Gregory Huey, David J. Tanner, Masayuki Takeuchi, Hang Qu, Xiaoxi Liu, Nga Lee Ng, James H. Crawford, Alan Fried, Dirk Richter, Isobel J. Simpson, Donald R. Blake, Nicola J. Blake, Simone Meinardi, Saewung Kim, Glenn S. Diskin, Joshua P. Digangi, Yonghoon Choi, Sally E. Pusede, Paul O. Wennberg, Michelle J. Kim, John D. Crounse, Alex P. Teng, Ronald C. Cohen, Paul S. Romer, William Brune, Armin Wisthaler, Tomas Mikoviny, Jose L. Jimenez, Pedro Campuzano-Jost, Benjamin A. Nault, Andrew Weinheimer, Samuel R. Hall, and Kirk Ullmann

Subjects

Atmospheric Science, Environmental Engineering, Ecology, Geology, Geotechnical Engineering and Engineering Geology, Oceanography

Abstract

Emissions and secondary photochemical products from the Daesan petrochemical complex (DPCC), on the west coast of South Korea, were measured from the NASA DC-8 research aircraft during the Korea-United States Air Quality campaign in 2016. The chemical evolution of petrochemical emissions was examined utilizing near-source and downwind plume transects. Small alkenes, such as ethene (C2H4), propene (C3H6), and 1,3-butadiene (C4H6), dominated the hydroxyl (OH) radical reactivity near the source region. The oxidation of these alkenes in the petrochemical plumes led to efficient conversion of nitrogen oxides (NOx) to nitric acid (HNO3), peroxycarboxylic nitric anhydrides (PANs), and alkyl nitrates (ANs), where the sum of the speciated reactive nitrogen contributes more than 80% of NOy within a few hours. Large enhancements of short-lived NOx oxidation products, such as hydroxy nitrates (HNs) and peroxyacrylic nitric anhydride, were observed, in conjunction with high ozone levels of up to 250 ppb, which are attributed to oxidation of alkenes such as 1,3-butadiene. Instantaneous ozone production rates, P(O3), near and downwind of the DPCC ranged from 9 to 24 ppb h−1, which were higher than those over Seoul. Ozone production efficiencies ranged from 6 to 10 downwind of the DPCC and were lower than 10 over Seoul. The contributions of alkenes to the instantaneous secondary organic aerosol (SOA) production rate, P(SOA), were estimated to be comparable to those of more common SOA precursors such as aromatics at intermediate distances from the DPCC. A model case study constrained to an extensive set of observations provided a diagnostic of petrochemical plume chemistry. The simulated plume chemistry reproduced the observed evolution of ozone and short-lived reactive nitrogen compounds, such as PANs and HNs as well as the rate and efficiency of ozone production. The simulated peroxy nitrates (PNs) budget included large contributions (approximately 30%) from unmeasured PNs including peroxyhydroxyacetic nitric anhydride and peroxybenzoic nitric anhydride. The large, predicted levels of these PAN compounds suggest their potential importance in chemical evolution of petrochemical plumes. One unique feature of the DPCC plumes is the substantial contribution of 1,3-butadiene to ozone and potentially SOA production. This work suggests that reductions in small alkene, especially 1,3-butadiene, emissions from the DPCC should be a priority for reducing downwind ozone.

Published

2022

2. Airborne formaldehyde and volatile organic compound measurements over the Daesan petrochemical complex on Korea’s northwest coast during the Korea-United States Air Quality study

Author

Minwoo Park, Michelle J. Kim, Petter Weibring, Tomas Mikoviny, Ryan Bennett, Christoph Knote, James H. Crawford, Michael Shook, Jong Ho Kim, Alex P. Teng, Jinseok Kim, S. Hughes, Simone Meinardi, James Walega, Jung Hun Woo, Marta A. Fenn, Johnathan W. Hair, John D. Crounse, Kyung-Eun Min, Dirk Richter, Seokhan Jeong, Barbara Barletta, Greg Huey, David B. Tanner, G. Diskin, Alan Fried, William H. Brune, Nicola J. Blake, Donald R. Blake, Rokjin J. Park, Melissa Yang-Martin, Isobel J. Simpson, Armin Wisthaler, John D. W. Barrick, and Paul O. Wennberg

Subjects

chemistry.chemical_classification, Atmospheric Science, Environmental Engineering, 010504 meteorology & atmospheric sciences, Ecology, Formaldehyde, Geology, 010501 environmental sciences, Geotechnical Engineering and Engineering Geology, Oceanography, 01 natural sciences, chemistry.chemical_compound, Petrochemical, chemistry, Environmental chemistry, Environmental science, Volatile organic compound, ddc:610, Air quality index, 0105 earth and related environmental sciences

Abstract

The U.S. National Aeronautics and Space Administration in partnership with Korea’s National Institute of Environmental Research embarked on the Korea-United States Air Quality (KORUS-AQ) study to address air quality issues over the Korean peninsula. Underestimation of volatile organic compound (VOC) emissions from various large facilities on South Korea’s northwest coast may contribute to this problem, and this study focuses on quantifying top-down emissions of formaldehyde (CH2O) and VOCs from the largest of these facilities, the Daesan petrochemical complex, and comparisons with the latest emission inventories. To accomplish this and additional goals discussed herein, this study employed a number of measurements acquired during KORUS-AQ onboard the NASA DC-8 aircraft during three Daesan overflights on June 2, 3, and 5, 2016, in conjunction with a mass balance approach. The measurements included fast airborne measurements of CH2O and ethane from an infrared spectrometer, additional fast measurements from other instruments, and a suite of 33 VOC measurements acquired by the whole air sampler. The mass balance approach resulted in consistent top-down yearly Daesan VOC emission flux estimates, which averaged (61 ± 14) × 103 MT/year for the 33 VOC compounds, a factor of 2.9 ± 0.6 (±1.0) higher than the bottom-up inventory value. The top-down Daesan emission estimate for CH2O and its four primary precursors averaged a factor of 4.3 ± 1.5 (± 1.9) times higher than the bottom-up inventory value. The uncertainty values in parentheses reflect upper limits for total uncertainty estimates. The resulting averaged top-down Daesan emission estimate for sulfur dioxide (SO2) yielded a ratio of 0.81–1.0 times the bottom-up SO2 inventory, and this provides an important cross-check on the accuracy of our mass balance analysis.

Published

2020

3. Characterization, sources and reactivity of volatile organic compounds (VOCs) in Seoul and surrounding regions during KORUS-AQ

Author

Alan Fried, Christoph Knote, Benjamin Gaubert, Jinseok Kim, Paul O. Wennberg, Donald R. Blake, S. Hughes, J. Schroeder, Glenn S. Diskin, Nicola J. Blake, David A. Peterson, Jung-Hun Woo, Yu Wang, Jerome Barre, Lauren T. Fleming, Hai Guo, Armin Wisthaler, Younha Kim, Isobel J. Simpson, Lewei Zeng, Louisa K. Emmons, Barbara Barletta, James H. Crawford, Simone Meinardi, Michelle J. Kim, Tomas Mikoviny, and Sally E. Pusede

Subjects

Atmospheric Science, Environmental Engineering, Ozone, 010504 meteorology & atmospheric sciences, Air pollution, korea, 010501 environmental sciences, VOCs, Seoul, Korea, KORUS-AQ, Source apportionment, OH reactivity, Oceanography, medicine.disease_cause, 01 natural sciences, Ethylbenzene, oh reactivity, chemistry.chemical_compound, medicine, ddc:550, Benzene, Air quality index, Isoprene, lcsh:Environmental sciences, 0105 earth and related environmental sciences, Carbonyl sulfide, lcsh:GE1-350, Ecology, Geology, source apportionment, korus-aq, Geotechnical Engineering and Engineering Geology, Toluene, chemistry, Environmental chemistry, Environmental science, seoul, vocs

Abstract

The Korea-United States Air Quality Study (KORUS-AQ) took place in spring 2016 to better understand air pollution in Korea. In support of KORUS-AQ, 2554 whole air samples (WAS) were collected aboard the NASA DC-8 research aircraft and analyzed for 82 C1–C10 volatile organic compounds (VOCs) using multi-column gas chromatography. Together with fast-response measurements from other groups, the air samples were used to characterize the VOC composition in Seoul and surrounding regions, determine which VOCs are major ozone precursors in Seoul, and identify the sources of these reactive VOCs. (1) The WAS VOCs showed distinct signatures depending on their source origins. Air collected over Seoul had abundant ethane, propane, toluene and n-butane while plumes from the Daesan petrochemical complex were rich in ethene, C2–C6 alkanes and benzene. Carbonyl sulfide (COS), CFC-113, CFC-114, carbon tetrachloride (CCl4) and 1,2-dichloroethane were good tracers of air originating from China. CFC-11 was also elevated in air from China but was surprisingly more elevated in air over Seoul. (2) Methanol, isoprene, toluene, xylenes and ethene were strong individual contributors to OH reactivity in Seoul. However methanol contributed less to ozone formation based on photochemical box modeling, which better accounts for radical chemistry. (3) Positive Matrix Factorization (PMF) and other techniques indicated a mix of VOC source influences in Seoul, including solvents, traffic, biogenic, and long-range transport. The solvent and traffic sources were roughly equal using PMF, and the solvents source was stronger in the KORUS-AQ emission inventory. Based on PMF, ethene and propene were primarily associated with traffic, and toluene, ethylbenzene and xylenes with solvents, especially non-paint solvents for toluene and paint solvents for ethylbenzene and xylenes. This suggests that VOC control strategies in Seoul could continue to target vehicle exhaust and paint solvents, with additional regulations to limit the VOC content in a variety of non-paint solvents.

Published

2020

4. Observation-based modeling of ozone chemistry in the Seoul metropolitan area during the Korea-United States Air Quality Study (KORUS-AQ)

Author

Alan Fried, Joshua P. DiGangi, James H. Crawford, Paul O. Wennberg, Joonyoung Ahn, Glenn S. Diskin, David J. Tanner, Greg Huey, Armin Wisthaler, Nicola J. Blake, Kirk Ullmann, Denise D. Montzka, Donald R. Blake, S. Hughes, Samuel R. Hall, Gao Chen, Sally E. Pusede, Yonghoon Choi, Lim-Seok Chang, Simone Meinardi, James Walega, Andrew J. Weinheimer, Michelle J. Kim, Tomas Mikoviny, and J. Schroeder

Subjects

Atmospheric Science, Environmental Engineering, Ozone, 010504 meteorology & atmospheric sciences, Population, korea, 010501 environmental sciences, Oceanography, Atmospheric sciences, 01 natural sciences, chemistry.chemical_compound, Air quality, Photochemistry, Korea, Seoul, education, Ozone chemistry, Air quality index, lcsh:Environmental sciences, NOx, Isoprene, 0105 earth and related environmental sciences, lcsh:GE1-350, education.field_of_study, photochemistry, Ecology, Geology, Geotechnical Engineering and Engineering Geology, air quality, Metropolitan area, Trace gas, ozone, chemistry, seoul

Abstract

The Seoul Metropolitan Area (SMA) has a population of 24 million and frequently experiences unhealthy levels of ozone (O3). In this work, measurements taken during the Korea-United States Air Quality Study (KORUS-AQ, 2016) are used to explore regional gradients in O3 and its chemical precursors, and an observationally-constrained 0-D photochemical box model is used to quantify key aspects of O3 production including its sensitivity to precursor gases. Box model performance was evaluated by comparing modeled concentrations of select secondary species to airborne measurements. These comparisons indicate that the steady state assumption used in 0-D box models cannot describe select intermediate species, highlighting the importance of having a broad suite of trace gases as model constraints. When fully constrained, aggregated statistics of modeled O3 production rates agreed with observed changes in O3, indicating that the box model was able to represent the majority of O3 chemistry. Comparison of airborne observations between urban Seoul and a downwind receptor site reveal a positive gradient in O3 coinciding with a negative gradient in NOx, no gradient in CH2O, and a slight positive gradient in modeled rates of O3 production. Together, these observations indicate a radical-limited (VOC-limited) O3 production environment in the SMA. Zero-out simulations identified C7+ aromatics as the dominant VOC contributors to O3 production, with isoprene and anthropogenic alkenes making smaller but appreciable contributions. Simulations of model sensitivity to decreases in NOx produced results that were not spatially uniform, with large increases in O3 production predicted for urban Seoul and decreases in O3 production predicted for far-outlying areas. The policy implications of this work are clear: Effective O3 mitigation strategies in the SMA must focus on reducing local emissions of C7+ aromatics, while reductions in NOx emissions may increase O3 in some areas but generally decrease the regional extent of O3 exposure.

Published

2020

5. The O2/N2 Ratio and CO2 Airborne Southern Ocean Study

Author

Kaylan Randolph, Rebecca S. Hornbrook, A. Watt, Matthew C. Long, Kathryn McKain, Eric A. Kort, Joanna Gordon Casey, Michelle M. Gierach, Matthew Hayman, Bo Cai Gao, James F. Bresch, Britton B. Stephens, Minghui Diao, Robert O. Green, Eric C. Apel, Mackenzie L. Smith, Ralph F. Keeling, Ernesto Diaz, Jørgen Jensen, Eric J. Morgan, Valeria Donets, Jonathan D. Bent, Greg Stossmeister, Katherine Smith, Bruce C. Daube, Martín S. Hoecker-Martínez, Bryan Rainwater, Elliot Atlas, Colm Sweeney, Scott H. Nolte, Alan J. Hills, Ian B. McCubbin, Rong Rong Li, S. Schauffler, Darin W. Toohey, Jordan G. Powers, Mike Reeves, Nicola J. Blake, Stuart Beaton, Jeff Stith, Heidi M. Dierssen, Shawn B. Honomichl, and Justin M. Haag

Subjects

Atmospheric Science, Carbon dioxide in Earth's atmosphere, 010504 meteorology & atmospheric sciences, Global warming, Co2 flux, 010502 geochemistry & geophysics, 01 natural sciences, Earth system science, chemistry.chemical_compound, Oceanography, chemistry, Geologic time scale, Ocean color, Climatology, Carbon dioxide, Environmental science, Natural variability, 0105 earth and related environmental sciences

Abstract

The Southern Ocean plays a critical role in the global climate system by mediating atmosphere–ocean partitioning of heat and carbon dioxide. However, Earth system models are demonstrably deficient in the Southern Ocean, leading to large uncertainties in future air–sea CO2 flux projections under climate warming and incomplete interpretations of natural variability on interannual to geologic time scales. Here, we describe a recent aircraft observational campaign, the O2/N2 Ratio and CO2 Airborne Southern Ocean (ORCAS) study, which collected measurements over the Southern Ocean during January and February 2016. The primary research objective of the ORCAS campaign was to improve observational constraints on the seasonal exchange of atmospheric carbon dioxide and oxygen with the Southern Ocean. The campaign also included measurements of anthropogenic and marine biogenic reactive gases; high-resolution, hyperspectral ocean color imaging of the ocean surface; and microphysical data relevant for understanding and modeling cloud processes. In each of these components of the ORCAS project, the campaign has significantly expanded the amount of observational data available for this remote region. Ongoing research based on these observations will contribute to advancing our understanding of this climatically important system across a range of topics including carbon cycling, atmospheric chemistry and transport, and cloud physics. This article presents an overview of the scientific and methodological aspects of the ORCAS project and highlights early findings.

Published

2018

6. Constraints from observations and modeling on atmosphere-surface exchange of mercury in eastern North America

Author

Amanda Giang, Daniel A. Jaffe, Christopher A. Cantrell, Shaojie Song, Bin Yuan, Lynne E. Gratz, Viral Shah, Andrew J. Weinheimer, Gary D. Conley, Winston T. Luke, Thomas M. Holsen, Rebecca S. Hornbrook, J. L. Ambrose, Mark S. Castro, Robert W. Talbot, Eric C. Apel, Lyatt Jaeglé, Roy L. Mauldin, Noelle E. Selin, Lisa Kaser, Nicola J. Blake, Department of Physics, Massachusetts Institute of Technology. Department of Earth, Atmospheric, and Planetary Sciences, Massachusetts Institute of Technology. Institute for Data, Systems, and Society, Song, Shaojie, and Selin, Noelle E

Subjects

Atmospheric Science, Environmental Engineering, 010504 meteorology & atmospheric sciences, Chemical transport model, Hg emission, chemistry.chemical_element, Northwest Atlantic, 010501 environmental sciences, Oceanography, 01 natural sciences, 114 Physical sciences, Sink (geography), aircraft campaign, Flux (metallurgy), lcsh:Environmental sciences, 1172 Environmental sciences, 0105 earth and related environmental sciences, lcsh:GE1-350, geography, geography.geographical_feature_category, Ecology, Geology, 15. Life on land, Geotechnical Engineering and Engineering Geology, Nitrogen, Mercury (element), Aerosol, chemistry, 13. Climate action, Climatology, Atmospheric chemistry, Terrestrial ecosystem

Abstract

Atmosphere–surface exchange of mercury, although a critical component of its global cycle, is currently poorly constrained. Here we use the GEOS-Chem chemical transport model to interpret atmospheric Hg0 (gaseous elemental mercury) data collected during the 2013 summer Nitrogen, Oxidants, Mercury and Aerosol Distributions, Sources and Sinks (NOMADSS) aircraft campaign as well as ground- and ship-based observations in terms of their constraints on the atmosphere–surface exchange of Hg0 over eastern North America. Model–observation comparison suggests that the Northwest Atlantic may be a net source of Hg0, with high evasion fluxes in summer (our best sensitivity simulation shows an average oceanic Hg0 flux of 3.3 ng m-2 h-1 over the Northwest Atlantic), while the terrestrial ecosystem in the summer of the eastern United States is likely a net sink of Hg0 (our best sensitivity simulation shows an average terrestrial Hg0 flux of -0.6 ng m-2 h-1 over the eastern United States). The inferred high Hg0 fluxes from the Northwest Atlantic may result from high wet deposition fluxes of oxidized Hg, which are in turn related to high precipitation rates in this region. We also find that increasing simulated terrestrial fluxes of Hg0 in spring compared to other seasons can better reproduce observed seasonal variability of Hg0 concentration at ground-based sites in eastern North America.

Published

2016

7. Factors controlling tropospheric O3, OH, NOxand SO2over the tropical Pacific during PEM-Tropics B

Author

Donald R. Blake, Shaw Chen Liu, Douglas D. Davis, Nicola J. Blake, Richard E. Shetter, Glen W. Sachse, Melody A. Avery, Eillot L. Atlas, David Tan, William H. Brune, Paul H. Wine, Brian G. Heikes, Robert W. Talbot, Hanwant B. Singh, Scott T. Sandholm, and Yuhang Wang

Subjects

Convection, Atmospheric Science, Ozone, Ecology, Paleontology, Soil Science, Forestry, Aquatic Science, Oceanography, Atmospheric sciences, Troposphere, chemistry.chemical_compound, Geophysics, Altitude, chemistry, Space and Planetary Science, Geochemistry and Petrology, Earth and Planetary Sciences (miscellaneous), Environmental science, Nitrogen oxide, Outflow, Scavenging, NOx, Earth-Surface Processes, Water Science and Technology

Abstract

Observations over the tropical Pacific during the Pacific Exploratory Mission (PEM)-Tropics B experiment (March-April 1999) are analyzed. Concentrations of CO and long-lived nonmethane hydrocarbons in the region are significantly enhanced due to transport of pollutants from northern industrial continents. This pollutant import also enhances moderately O3 concentrations but not NOx concentrations. It therefore tends to depress OH concentrations over the tropical Pacific. These effects contrast to the large enhancements of O3 and NOx concentrations and the moderate increase of OH concentrations due to biomass burning outflow during the PEM-Tropics A experiment (September-October 1996). Observed CH3I concentrations, as in PEM-Tropics A, indicate that convective mass outflux in the middle and upper troposphere is largely independent of altitude over the tropical Pacific. Constraining a one-dimensional model with CH3I observations yields a 10-day timescale for convective turnover of the free troposphere, a factor of 2 faster than during PEM-Tropics A. Model simulated HO2, CH2O, H2O2, and CH3OOH concentrations are generally in agreement with observations. However, simulated OH concentrations are lower (∼25%) than observations above 6 km. Whereas models tend to overestimate previous field measurements, simulated HNO3 concentrations during PEM-Tropics B are too low (a factor of 2–4 below 6 km) compared to observations. Budget analyses indicate that chemical production of O3 accounts for only 50% of chemical loss; significant transport of O3 into the region appears to take place within the tropics. Convective transport Of CH3OOH enhances the production of HOx and O3 in the upper troposphere, but this effect is offset by HOx loss due to the scavenging of H2O2. Convective transport and scavenging of reactive nitrogen species imply a necessary source of 0.4–1 Tg yr−1 of NOx in the free troposphere (above 4 km) over the tropics. A large fraction of the source could be from marine lightning. Oxidation of DMS transported by convection from the boundary layer could explain the observed free tropospheric SO2 concentrations over the tropical Pacific. This source of DMS due to convection, however, would imply in the model free tropospheric concentrations much higher than observed. The model overestimate cannot be reconciled using recent kinetics measurements of the DMS-OH adduct reaction at low pressures and temperatures and may reflect enhanced OH oxidation of DMS during convection.

Published

2001

8. Marine latitude/altitude OH distributions: Comparison of Pacific Ocean observations with models

Author

Daniel O'Sullivan, Richard E. Shetter, G. Chen, Barry Lefer, Ian Faloona, G. W. Sachse, Nicola J. Blake, William H. Brune, Brian G. Heikes, Donald R. Blake, Scott T. Sandholm, Melody A. Avery, Bruce E. Anderson, Yuhang Wang, David B. Tanner, Christopher A. Cantrell, Stephanie A. Vay, L. Mauldin, Fred L. Eisele, Brian A. Ridley, James Walega, Mary Anne Carroll, Denise D. Montzka, G. Grodzinsky, D. Tan, James H. Crawford, F. E. Grahek, J. Snow, and Douglas D. Davis

Subjects

Atmospheric Science, Box model, Ecology, Paleontology, Soil Science, Sampling (statistics), Forestry, Subtropics, Aquatic Science, Oceanography, Pacific ocean, Pacific basin, Latitude, Geophysics, Altitude, Space and Planetary Science, Geochemistry and Petrology, Tropical marine climate, Climatology, Earth and Planetary Sciences (miscellaneous), Environmental science, Earth-Surface Processes, Water Science and Technology

Abstract

Reported here are tropical/subtropical Pacific basin OH observational data presented in a latitude/altitude geographical grid. They cover two seasons of the year (spring and fall) that reflect the timing of NASA's PEM-Tropics A (1996) and B (1999) field programs. Two different OH sensors were used to collect these data, and each instrument was mounted on a different aircraft platform (i.e., NASA's P-3B and DC-8). Collectively, these chemical snapshots of the central Pacific have revealed several interesting trends. Only modest decreases (factors of 2 to 3) were found in the levels of OH with increasing altitude (0–12 km). Similarly, only modest variations were found (factors of 1.5 to 3.5) when the data were examined as a function of latitude (30°N to 30°S). Using simultaneously recorded data for CO, O3, H2O, NO, and NMHCs, comparisons with current models were also carried out. For three out of four data subsets, the results revealed a high level of correspondence. On average, the box model results agreed with the observations within a factor of 1.5. The comparison with the three-dimensional model results was found to be only slightly worse. Overall, these results suggest that current model mechanisms capture the major photochemical processes controlling OH quite well and thus provide a reasonably good representation of OH levels for tropical marine environments. They also indicate that the two OH sensors employed during the PEM-Tropics B study generally saw similar OH levels when sampling a similar tropical marine environment. However, a modest altitude bias appears to exist between these instruments. More rigorous instrument intercomparison activity would therefore seem to be justified. Further comparisons of model predictions with observations are also recommended for nontropical marine environments as well as those involving highly elevated levels of reactive non-methane hydrocarbons.

Published

2001

9. Tropospheric reactive odd nitrogen over the South Pacific in austral springtime

Author

Eric Scheuer, Frank Flocke, Elliot Atlas, Robert W. Talbot, Scott T. Sandholm, J. D. Bradshaw, Donald R. Blake, Jack E. Dibb, Nicola J. Blake, and Hanwant B. Singh

Subjects

Atmospheric Science, Reactive nitrogen, Soil Science, chemistry.chemical_element, Aquatic Science, Oceanography, Troposphere, chemistry.chemical_compound, Geochemistry and Petrology, Earth and Planetary Sciences (miscellaneous), Mixing ratio, Earth-Surface Processes, Water Science and Technology, Peroxyacetyl nitrate, Ecology, Paleontology, Forestry, Nitrogen, Plume, Geophysics, Deposition (aerosol physics), chemistry, Space and Planetary Science, Climatology, Environmental science, Nitrogen oxide

Abstract

The distribution of reactive nitrogen species over the South Pacific during austral springtime appears to be dominated by biomass burning emissions and possibly lightning and stratospheric inputs. The absence of robust correlations of reactive nitrogen species with source-specific tracers (e.g., C2H2 [combustion], CH3Cl [biomass burning], C2Cl4 [industrial], 210Pb [continental], and 7Be [stratospheric]) suggests significant aging and processing of the sampled air parcels due to losses by surface deposition, OH attack, and dilution processes. Classification of the air parcels based on CO enhancements indicates that the greatest influence was found in plumes at 3–8 km altitude in the distributions of HNO3 and peroxyacetyl nitrate (PAN). Here mixing ratios of these species reached 600 parts per trillion by volume (pptv), values surprisingly large for a location several thousand kilometers removed from the nearest continental areas. The mixing ratio of total reactive nitrogen (the NOy sum), operationally defined in this paper as measured (NO + HNO3 + PAN + CH3ONO2 + C2H5ONO2) + modeled (NO2), had a median value of 285 pptv within these plumes compared with 120 pptv in nonplume air parcels. Particle NO−3 was not included in this analysis of the NOy sum due to its 10- to 15-min sampling time resolution, but, in general, it was

Published

2000

10. A case study of transport of tropical marine boundary layer and lower tropospheric air masses to the northern midlatitude upper troposphere

Author

J. Snow, Marian B. Clayton, Hanwant B. Singh, Nicola J. Blake, Gerald L. Gregory, Donald R. Blake, Glen W. Sachse, William B. Grant, Edward V. Browell, Marta A. Fenn, Henry E. Fuelberg, Brian G. Heikes, Robert W. Talbot, Carolyn F. Butler, and John R. Hannan

Subjects

Atmospheric Science, Ecology, Planetary boundary layer, Paleontology, Soil Science, Forestry, Aquatic Science, Oceanography, Troposphere, Geophysics, Space and Planetary Science, Geochemistry and Petrology, Potential vorticity, Climatology, Middle latitudes, Earth and Planetary Sciences (miscellaneous), Environmental science, Storm track, Tropopause, Stratosphere, Air mass, Earth-Surface Processes, Water Science and Technology

Abstract

Low-ozone (

Published

2000

11. Nonmethane hydrocarbon measurements in the North Atlantic Flight Corridor during the Subsonic Assessment Ozone and Nitrogen Oxide Experiment

Author

G. W. Sachse, Donald R. Blake, Stephanie A. Vay, Anne M. Thompson, Isobel J. Simpson, Nicola J. Blake, Tai-Yih Chen, F. S. Rowland, Jimena P. Lopez, Yutaka Kondo, Bruce E. Anderson, Barkley C. Sive, and Henry E. Fuelberg

Subjects

Atmospheric Science, business.product_category, Ozone, Meteorology, Air pollution, Soil Science, Aquatic Science, Oceanography, medicine.disease_cause, Atmospheric sciences, Airplane, Troposphere, chemistry.chemical_compound, Geochemistry and Petrology, Earth and Planetary Sciences (miscellaneous), medicine, Mixing ratio, Stratosphere, Earth-Surface Processes, Water Science and Technology, Ecology, Paleontology, Exhaust gas, Forestry, Geophysics, chemistry, Space and Planetary Science, Environmental science, Nitrogen oxide, business

Abstract

Mixing ratios of nonmethane hydrocarbons (NMHCs) were not enhanced in whole air samples collected within the North Atlantic Flight Corridor (NAFC) during the fall of 1997. The investigation was conducted aboard NASA's DC-8 research aircraft, as part of the Subsonic Assessment (SASS) Ozone and Nitrogen Oxide Experiment (SONEX). NMHC enhancements were not detected within the general organized tracking system of the NAFC, nor during two tail chases of the DC-8's own exhaust. Because positive evidence of aircraft emissions was demonstrated by enhancements in both nitrogen oxides and condensation nuclei during SONEX, the NMHC results suggest that the commercial air traffic fleet operating in the North Atlantic region does not contribute at all or contributes negligibly to NMHCs in the NAFC.

Published

2000

12. Aircraft measurements of the latitudinal, vertical, and seasonal variations of NMHCs, methyl nitrate, methyl halides, and DMS during the First Aerosol Characterization Experiment (ACE 1)

Author

Oliver W. Wingenter, Frank Flocke, F. Sherwood Rowland, Elliot Atlas, Alan R. Bandy, Joyce M. Harris, Barkley C. Sive, Donald C. Thornton, Chang Hee Kang, Donald R. Blake, and Nicola J. Blake

Subjects

Atmospheric Science, Soil Science, Aquatic Science, Oceanography, Atmospheric sciences, Troposphere, chemistry.chemical_compound, Geochemistry and Petrology, Earth and Planetary Sciences (miscellaneous), Mixing ratio, Earth-Surface Processes, Water Science and Technology, Ecology, Northern Hemisphere, Paleontology, Forestry, Trace gas, Geophysics, chemistry, Space and Planetary Science, Middle latitudes, Environmental science, Dimethyl sulfide, Methyl nitrate, Methyl iodide

Abstract

Canister sampling for the determination of atmospheric mixing ratios of nonmethane hydrocarbons (NMHCs), selected halocarbons, and methyl nitrate was conducted aboard the National Center for Atmospheric Research (NCAR) C-130 aircraft over the Pacific and Southern Oceans as part of the First Aerosol Characterization Experiment (ACE 1) during November and December 1995. A latitudinal profile, flown from 76°N to 60°S, revealed latitudinal gradients for most trace gases. NMHC and halocarbon gases with predominantly anthropogenic sources, including ethane, ethyne, and tetrachloroethene, exhibited significantly higher mixing ratios in the northern hemisphere at all altitudes. Methyl chloride exhibited its lowest mixing ratios at the highest northern hemisphere latitudes, and the distributions of methyl nitrate and methyl iodide were consistent with tropical and subtropical oceanic sources. Layers containing continental air characteristic of aged biomass burning emissions were observed above about 3 km over the remote southern Pacific and near New Zealand between approximately 19°S and 43°S. These plumes originated from the west, possibly from fires in southern Africa. The month-long intensive investigation of the clean marine southern midlatitude troposphere south of Australia revealed decreases in the mixing ratios of ethane, ethyne, propane, and tetrachloroethene, consistent with their seasonal mixing ratio cycle. By contrast, increases in the average marine boundary layer concentrations of methyl iodide, methyl nitrate, and dimethyl sulfide (DMS) were observed as the season progressed to summer conditions. These increases were most appreciable in the region south of 44°S over Southern Ocean waters characterized as subantarctic and polar, indicating a seasonal increase in oceanic productivity for these gases.

Published

1999

13. Tropospheric hydroxyl and atomic chlorine concentrations, and mixing timescales determined from hydrocarbon and halocarbon measurements made over the Southern Ocean

Author

Frank Flocke, Donald R. Blake, F. Sherwood Rowland, Elliot Atlas, Nicola J. Blake, Barkley C. Sive, and Oliver W. Wingenter

Subjects

Atmospheric Science, Planetary boundary layer, Soil Science, chemistry.chemical_element, Aquatic Science, Oceanography, Atmospheric sciences, Troposphere, chemistry.chemical_compound, Geochemistry and Petrology, Earth and Planetary Sciences (miscellaneous), Chlorine, Biomass burning, Chemical composition, Earth-Surface Processes, Water Science and Technology, Hydrology, chemistry.chemical_classification, Ecology, Paleontology, Forestry, Halocarbon, Aerosol, Geophysics, Hydrocarbon, chemistry, Space and Planetary Science, Environmental science

Abstract

Author(s): Wingenter, OW; Blake, DR; Blake, NJ; Sive, BC; Rowland, FS; Atlas, E; Flocke, F | Abstract: During the First Aerosol Characterization Experiment (ACE 1) field campaign, 1419 whole air samples were collected over the Southern Ocean, of which approximately 700 samples were collected in the marine boundary layer (MBL), 300 samples were taken in the free troposphere (FT), and the remainder were collected in the buffer layer (BuL), the layer between the MBL and FT. Concentrations of tetrachloroethene, ethane, ethyne, and propane decayed over the 24 day duration of the intensive portion of the field campaign, which began November 18, 1995. This decline was consistent with what is known about seasonal increase of HO and the seasonal decrease in biomass burning. Using a simple empirical model, the best fit to the observations was obtained when the average [HO] was 6.1 ± 0.3 × 105 HO cm-3, and an average [Cl] of 720 ± 100 Cl cm-3. The corresponding exchange times were 14 ± 2 days between the MBL and FT, and 49 +40/-13 days between the MBL in the intensive campaign region and the MBL region to the north (nMBL). Copyright 1999 by the American Geophysical Union.

Published

1999

14. Influence of southern hemispheric biomass burning on midtropospheric distributions of nonmethane hydrocarbons and selected halocarbons over the remote South Pacific

Author

George M. Albercook, Jimena P. Lopez, Bruce E. Anderson, Mary Anne Carroll, Oliver W. Wingenter, F. Sherwood Rowland, Barkley C. Sive, Gerald L. Gregory, Nicola J. Blake, Isobel J. Simpson, Donald R. Blake, Glen W. Sachse, Henry E. Fuelberg, and Lisa M. McKenzie

Subjects

Pollution, Atmospheric Science, media_common.quotation_subject, Air pollution, Soil Science, Aquatic Science, Oceanography, Spatial distribution, medicine.disease_cause, Pacific ocean, Troposphere, Geochemistry and Petrology, Earth and Planetary Sciences (miscellaneous), medicine, Biomass burning, Earth-Surface Processes, Water Science and Technology, media_common, Ecology, Paleontology, Forestry, Aerosol, Trace gas, Geophysics, Space and Planetary Science, Environmental science

Abstract

Author(s): Blake, NJ; Blake, DR; Wingenter, OW; Sive, BC; McKenzie, LM; Lopez, JP; Simpson, IJ; Fuelberg, HE; Sachse, GW; Anderson, BE; Gregory, GL; Carroll, MA; Albercook, GM; Rowland, FS | Abstract: Aircraft measurements of nonmethane hydrocarbons (NMHCs) and halocarbons were made over the remote South Pacific Ocean during late August-early October 1996 for NASA's Global Tropospheric Experiment (GTE) Pacific Exploratory Mission-Tropics A (PEM-Tropics A). This paper discusses the large-scale spatial distributions of selected trace gases encountered during PEM-Tropics A. The PEM-Tropics A observations are compared to measurements made over the southwestern pacific in early November 1995 as part of Aerosol Characterization Experiment (ACE 1). Continental pollution in the form of layers containing elevated levels of O3 was observed during a majority of PEM-Tropics flights, as well as during several ACE 1 flights. The chemical composition of these air masses indicates that they were not fresh and were derived from nonurban combustion sources. The substantial impact of biomass burning on the vertical structure of the South Pacific troposphere is discussed. Copyright 1999 by the American Geophysical Union.

Published

1999

15. On the origin of tropospheric ozone and NOxover the tropical South Pacific

Author

Daniel J. Jacob, Hanwant B. Singh, Jennifer A. Logan, Elliot Atlas, Nicola J. Blake, Robert W. Talbot, Gerald L. Gregory, Frank Flocke, Marta A. Fenn, Scott T. Sandholm, Glen W. Sachse, Edward V. Browell, Martin G. Schultz, Donald R. Blake, Yuhang Wang, Richard E. Shetter, John D. Bradshaw, and Brian G. Heikes

Subjects

Pollution, Atmospheric Science, Ozone, media_common.quotation_subject, Soil Science, Aquatic Science, Oceanography, Atmospheric sciences, Troposphere, chemistry.chemical_compound, Altitude, Geochemistry and Petrology, Earth and Planetary Sciences (miscellaneous), Nitrogen dioxide, Tropospheric ozone, NOx, Earth-Surface Processes, Water Science and Technology, media_common, Ecology, Paleontology, Forestry, Ozone depletion, Geophysics, chemistry, Space and Planetary Science, Climatology, Environmental science

Abstract

The budgets of ozone and nitrogen oxides (NOx = NO + NO2) ill the tropical South Pacific troposphere are analyzed by photochemical point modeling of aircraft observations at 0-12 km altitude from the Pacific Exploratory Mission-Tropics A campaign flown in September- October 1996. The model reproduces the observed NO2/NO concentration ratio to within 30% and has similar success in simulating observed concentrations of peroxides (H202, CH3OOH), lending confidence in its use to investigate ozone chemistry. It is found that chemical production of ozone balances only half of chemical loss in the tropospheric column over the tropical South Pacific. The net loss is 1.8 x 1011 molecules cm -2 S '1. The missing source of ozone is matched by west- erly transport of continental pollution into the region. Independent analysis of the regional ozone budget with a global three-dimensional model corroborates the results from the point model and reveals the importance of biomass burning emissions in South America and Africa for the ozone budget over the tropical South Pacific. In this model, biomass burning increases average ozone concentrations by 7-8 ppbv throughout the troposphere. The NOx responsible for ozone produc- tion within the South Pacific troposphere below 4 km can be largely explained by decomposition of peroxyacetylnitrate (PAN) transported into the region with biomass burning pollution at higher altitudes.

Published

1999

16. Aerosol chemical composition and distribution during the Pacific Exploratory Mission (PEM) Tropics

Author

Robert W. Talbot, Eric Scheuer, Gerald L. Gregory, Nicola J. Blake, Donald R. Blake, Donald C. Thornton, Jack E. Dibb, and G. W. Sachse

Subjects

Atmospheric Science, Ecology, Intertropical Convergence Zone, Paleontology, Soil Science, Tropics, Forestry, Aquatic Science, Oceanography, Aerosol, Troposphere, Geophysics, Altitude, Space and Planetary Science, Geochemistry and Petrology, Climatology, Earth and Planetary Sciences (miscellaneous), Mixing ratio, Environmental science, Precipitation, Scavenging, Earth-Surface Processes, Water Science and Technology

Abstract

Distributions of aerosol-associated soluble ions over much of the South Pacific were determined by sampling from the NASA DC-8 as part of the Pacific Exploratory Mission (PEM) Tropics campaign. The mixing ratios of all ionic species were surprisingly low throughout the free troposphere (2–12 km), despite the pervasive influence from biomass burning plumes advecting over the South Pacific from the west during PEM-Tropics. At the same time, the specific activity of 7Be frequently exceeded 1000 fCi m−3 through much of the depth of the troposphere. These distributions indicate that the plumes must have been efficiently scavenged by precipitation (removing the soluble ions), but that the scavenging must have occurred far upwind of the DC-8 sampling regions (otherwise 7Be activities would also have been low). This inference is supported by large enhancements of HNO3 and carboxylic acids in many of the plumes, as these soluble acidic gases would also be readily scavenged in any precipitation events. Decreasing mixing ratios of NH4+ with altitude in all South Pacific regions sampled provide support for recent suggestions that oceanic emissions of NH3 constitute a significant source far from continents. Our sampling below 2 km reaffirms the latitudinal pattern in the methylsulfonate/non-sea-salt sulfate (MSA/nss SO4=) molar ratio established through surface-based and shipboard sampling, with values increasing from

Published

1999

17. Influence of biomass combustion emissions on the distribution of acidic trace gases over the southern Pacific basin during austral springtime

Author

G. W. Sachse, Robert W. Talbot, Eric Scheuer, Nicola J. Blake, Donald R. Blake, Hanwant B. Singh, Scott T. Sandholm, Jack E. Dibb, Gerald L. Gregory, and John D. Bradshaw

Subjects

Atmospheric Science, Ecology, Paleontology, Soil Science, Forestry, Aquatic Science, Oceanography, Combustion, Trace gas, Troposphere, Geophysics, Altitude, Space and Planetary Science, Geochemistry and Petrology, Biomass combustion, Atmospheric chemistry, Earth and Planetary Sciences (miscellaneous), Mixing ratio, Environmental science, NOx, Earth-Surface Processes, Water Science and Technology

Abstract

This paper describes the large-scale distributions of HNO3, HCOOH, and CH3COOH over the central and South Pacific basins during the Pacific Exploratory Mission-Tropics (PEM-Tropics) in austral springtime. Because of the remoteness of this region from continental areas, low part per trillion by volume (pptv) mixing ratios of acidic gases were anticipated to be pervasive over the South Pacific basin. However, at altitudes of 2–12 km over the South Pacific, air parcels were encountered frequently with significantly enhanced mixing ratios (up to 1200 pptv) of acidic gases. Most of these air parcels were centered in the 3–7 km altitude range and occurred within the 15°−65°S latitudinal band. The acidic gases exhibited an overall general correlation with CH3Cl, PAN, and O3, suggestive of photochemical and biomass burning sources. There was no correlation or trend of acidic gases with common industrial tracer compounds (e.g., C2Cl4 or CH3CCl3). The combustion emissions sampled over the South Pacific basin were relatively aged exhibiting C2H2/CO ratios in the range of 0.2–2.2 pptv/ppbv. The relationships between acidic gases and this ratio were similar to what was observed in aged air parcels (i.e., >3–5 days since they were over a continental area) over the western North Pacific during the Pacific Exploratory Mission-West Phases A and B (PEM-West A and B). In the South Pacific marine boundary layer a median C2H2/CO ratio of 0.6 suggested that this region was generally not influenced by direct inputs of biomass combustion emissions. Here we observed the lowest mixing ratios of acidic gases, with median values of 14 pptv for HNO3, 19 pptv for HCOOH, and 18 pptv for CH3COOH. These values were coincident with low mixing ratios of NOx(

Published

1999

18. Photochemical production and loss rates of ozone at Sable Island, Nova Scotia during the North Atlantic Regional Experiment (NARE) 1993 summer intensive

Author

L. Feng, George M. Albercook, John S. Holloway, Tao Wang, Donald R. Blake, G. Forbes, Katharine A. Duderstadt, Sanford Sillman, Mary Anne Carroll, Nicola J. Blake, Fred C. Fehsenfeld, and David D. Parrish

Subjects

Nova scotia, Atmospheric Science, Ozone, Marine boundary layer, Ecology, Planetary boundary layer, Cloud cover, Solar intensity, Paleontology, Soil Science, Forestry, Photochemical ozone, Aquatic Science, Oceanography, Photochemistry, Troposphere, chemistry.chemical_compound, Geophysics, chemistry, Space and Planetary Science, Geochemistry and Petrology, Climatology, Earth and Planetary Sciences (miscellaneous), Earth-Surface Processes, Water Science and Technology

Abstract

Three weeks of summertime surface-based chemical and meteorological observations at Sable Island, Nova Scotia during the North Atlantic Regional Experiment (NARE) 1993 summer intensive are used to study instantaneous photochemical production and loss rates of ozone by means of a numerical photochemical model. Results are most sensitive to the averaging scheme of data used to constrain the model and the ambient variability of the measurements. Model simulations driven by a time series of 5 min averaged data, most representative of the chemistry at the site, yield an average net photochemical ozone production of 3.6 ppbv/d. Estimates of net ozone production designed to filter out local sources, by using 1000–1400 LT median values of observations to drive the model and by excluding short-lived hydrocarbons, give values ranging from 1 to 4 ppbv/d. These positive values of net ozone production within the marine boundary layer over Sable Island demonstrate the impact of polluted continental plumes on the background photochemistry of the region during the intensive. The dominant ambient variables controlling photochemical production and loss rates of ozone at the site during the measurement campaign appear to be levels of nitrogen oxides, ozone, nonmethane hydrocarbons, and solar intensity determined by cloud cover. The model partitioning of nitrogen oxides agrees for the most part with measurements, lending credence to calculated photochemical production and loss rates of ozone as well as inferred levels of peroxy radicals not measured at the site. Discrepancies, however, often occur during episodes of intermittent cloud cover, fog, and rain, suggesting the influence of cloud processes on air masses reaching the site.

Published

1998

19. Spatial and temporal variability of nonmethane hydrocarbon mixing ratios and their relation to photochemical lifetime

Author

William C. Kuster, David D. Parrish, Paul D. Goldan, Bertram T. Jobson, H. Niki, Donald R. Blake, Nicola J. Blake, and Fred C. Fehsenfeld

Subjects

Nova scotia, Atmospheric Science, Soil Science, Aquatic Science, Oceanography, Atmospheric sciences, Standard deviation, chemistry.chemical_compound, Geochemistry and Petrology, Earth and Planetary Sciences (miscellaneous), Mixing ratio, Benzene, Mixing (physics), Earth-Surface Processes, Water Science and Technology, chemistry.chemical_classification, Ecology, Paleontology, Forestry, Geophysics, Hydrocarbon, chemistry, Space and Planetary Science, Environmental science, Spatial variability, Physical geography

Abstract

The relationship between temporal and spatial variability of C2-C8 nonmethane hydrocarbon mixing ratios and their HO lifetimes (τ) is presented for samples collected during the 1993 North Atlantic Regional Experiment (NARE) and from other urban and remote sites. The C2-C4 alkanes, acetylene and benzene typically define a trend of the form slnx = Aτ−b where slnx is the standard deviation of the ln of the mixing ratio. The relationship extended over a wider range of hydrocarbons in winter. The exponent b ranged in value from 0.28±0.023 for winter urban data where C2-C8 hydrocarbons defined a strongly correlated trend, to 0.56±0.15 for C2-C4 hydrocarbons at a coastal site in Nova Scotia during NARE. The trends are significantly different from that given by the Junge relationship [Junge, 1974]. Data from the Azores do not display such a trend and were likely influenced by local emissions. Variance trends are a useful analytical tool for examining the validity of hydrocarbon measurements.

Published

1998

20. Large-scale distributions of tropospheric nitric, formic, and acetic acids over the western Pacific basin during wintertime

Author

Jack E. Dibb, Gerald L. Gregory, Nicola J. Blake, J. D. Bradshaw, J. E. Collins, S Smyth, Barry Lefer, Scott T. Sandholm, Robert W. Talbot, Eric Scheuer, Donald R. Blake, and G. W. Sachse

Subjects

Atmospheric Science, Ecology, Northern Hemisphere, Paleontology, Soil Science, Forestry, Aquatic Science, Oceanography, Troposphere, Geophysics, Altitude, Volume (thermodynamics), Space and Planetary Science, Geochemistry and Petrology, Climatology, Middle latitudes, Earth and Planetary Sciences (miscellaneous), Mixing ratio, Environmental science, Scavenging, Stratosphere, Earth-Surface Processes, Water Science and Technology

Abstract

We report here measurements of the acidic gases nitric (HNO3), formic (HCOOH), and acetic (CH3COOH) over the western Pacific basin during the February-March 1994 Pacific Exploratory Mission-West (PEM-West B). These data were obtained aboard the NASA DC-8 research aircraft as it flew missions in the altitude range of 0.3 - 12.5 km over equatorial regions near Guam and then further westward encompassing the entire Pacific Rim arc. Aged marine air over the equatorial Pacific generally exhibited mixing ratios of acidic gases less than 100 parts per trillion by volume (pptv). Near the Asian continent, discrete plumes encountered below 6 km altitude contained up to 8 parts per billion by volume (ppbv) HNO3 and 10 ppbv HCOOH and CH3COOH. Overall there was a general correlation between mixing ratios of acidic gases with those of CO, C2H2, and C2Cl4, indicative of emissions from combustion and industrial sources. The latitudinal distributions of HNO3 and CO showed that the largest mixing ratios were centered around 15 deg N, while HCOOH, CH3COOH, and C2Cl4 peaked at 25 deg N. The mixing ratios of HCOOH and CH3COOH were highly correlated (r(sup 2) = 0.87) below 6 km altitude, with a slope (0.89) characteristic of the nongrowing season at midlatitudes in the northern hemisphere. Above 6 km altitude, HCOOH and CH3COOH were marginally correlated (r(sup 2) = 0.50), and plumes well defined by CO, C2H2, and C2Cl4 were depleted in acidic gases, most likely due to scavenging during vertical transport of air masses through convective cloud systems over the Asian continent. In stratospheric air masses, HNO, mixing ratios were several parts per billion by volume (ppbv), yielding relationships with 03 and N2O consistent with those previously reported for NO(y).

Published

1997

21. Distribution and seasonality of selected hydrocarbons and halocarbons over the western Pacific basin during PEM-West A and PEM-West B

Author

Glen W. Sachse, F. Sherwood Rowland, Nicola J. Blake, J. E. Collins, Bruce E. Anderson, Tai-Yih Chen, and Donald R. Blake

Subjects

Atmospheric Science, Ecology, Paleontology, Soil Science, Forestry, Subtropics, Aquatic Science, Seasonality, Oceanography, medicine.disease, Latitude, Trace gas, Troposphere, Geophysics, Space and Planetary Science, Geochemistry and Petrology, Earth and Planetary Sciences (miscellaneous), Temperate climate, medicine, Mixing ratio, Environmental science, Outflow, Earth-Surface Processes, Water Science and Technology

Abstract

Nonmethane hydrocarbons (NMHCs) and halocarbons were measured in the troposphere over the northwestern Pacific as part of the airborne component of NASA's Pacific Exploratory Mission-West Phase B (PEM-West B). This study took place in late winter of 1994, a period characterized by maximum outflow from the Asian continent. The results are compared to those from Pacific Exploratory Mission-West Phase A (PEM-West A), which was flown in the same region during late summer of 1991, when flow from the subtropical western Pacific dominated the lower troposphere. Mixing ratios of NMHCs, tetrachloroethene (C2Cl4), and methyl bromide (CH3Br) were significantly higher during PEM-West B than during PEM-West A, particularly at latitudes north of 25 deg N and altitudes lower than 6 km. The primary reasons for these higher ambient concentrations were the seasonal increase in the atmospheric lifetimes of trace gases controlled by HO radical reactions, and the more frequent input of continental air masses. During PEM-West B, air masses of continental origin observed north of 25 deg N latitude were augmented with urban signature gases such as C2Cl4. By contrast, more southerly continental outflow had characteristics associated with combustion sources such as biomass burning, including wood fuel burning. During the summer PEM-West A period, the spatial distribution of methyl iodide (CH3I) was consistent with effective oceanic sources at all latitudes, being especially strong in tropical and subtropical regions. At low latitudes, PEM-West B CH3I mixing ratios in the lower troposphere were similar to PEM-West A, but at latitudes greater than about 25 deg N PEM-West B concentrations were significantly reduced. Equatorial regions exhibited enhanced CH3I mixing ratios extending into the upper tropical troposphere, consistent with fast vertical transport of air from the tropical marine boundary layer.

Published

1997

22. Chemical characteristics of continental outflow from Asia to the troposphere over the western Pacific Ocean during February-March 1994: Results from PEM-West B

Author

Nicola J. Blake, John Merrill, G. W. Sachse, Robert W. Talbot, Alan R. Bandy, Donald R. Blake, Rudolf F. Pueschel, J. D. Bradshaw, Scott T. Sandholm, Barry Lefer, J. E. Collins Jr., Gerald L. Gregory, Brian G. Heikes, Bruce E. Anderson, Donald C. Thornton, Hanwant B. Singh, and Jack E. Dibb

Subjects

Atmospheric Science, Ecology, Paleontology, Soil Science, Forestry, Aquatic Science, Particulates, Oceanography, Aerosol, Latitude, Trace gas, Troposphere, Atmosphere, Geophysics, Altitude, Space and Planetary Science, Geochemistry and Petrology, Climatology, Earth and Planetary Sciences (miscellaneous), Outflow, Earth-Surface Processes, Water Science and Technology

Abstract

We present here the chemical composition of outflow from the Asian continent to the atmosphere over the western Pacific basin during the Pacific Exploratory Mission-West (PEM-West B) in February-March 1994. Comprehensive measurements of important tropospheric trace gases and aerosol particulate matter were performed from the NASA DC-8 airborne laboratory. Backward 5 day isentropic trajectories were used to partition the outflow from two major source regions- continental north (greater than 20 deg N) and continental south (less than 20 deg N). Air parcels that had not passed over continental areas for the previous 5 days were classified as originating from an aged marine source. The trajectories and the chemistry together indicated that there was extensive rapid outflow of air parcels at altitudes below 5 km, while aged marine air was rarely encountered and only at less than 20 deg N latitude. The outflow at low altitudes had enhancements in common industrial solvent vapors such as C2Cl4, CH3CCl3, and C6H6, intermixed with the combustion emission products C2H2, C2H6, CO, and NO. The mixing ratios of all species were up to tenfold greater in outflow from the continental north compared to the continental south source region, with Pb-210 concentrations reaching 38 fCi (10(exp -15) curies) per standard cubic meter. In the upper troposphere we again observed significant enhancements in combustion-derived species in the 8-10 km altitude range, but water-soluble trace gases and aerosol species were depleted. These observations suggest that ground level emissions were lofted to the upper troposphere by wet convective systems which stripped water-soluble components from these air parcels. There were good correlations between C2H2 and CO and C2H6 (r(sup 2) = 0.70 - 0.97) in these air parcels and much weaker ones between C2H2 and H2O2 or CH3OOH (r(sup 2) = 0.50). These correlations were the strongest in the continental north outflow where combustion inputs appeared to be recent (1 - 2 days old). Ozone and PAN showed general correlation in these same air parcels but not with the combustion products. It thus appears that several source inputs were intermixed in these upper tropospheric air masses, with possible contributions from European or Middle Eastern source regions. In aged marine air mixing ratios of 03 (approximately equals 20 parts per billion by volume) and PAN (less than or equal to 10 parts per trillion by volume) were nearly identical at less than 2 km and 10 - 12 km altitudes due to extensive convective uplifting of marine boundary layer air over the equatorial Pacific even in wintertime. Comparison of the Pacific Exploratory Mission-West A and PEM-West B data sets shows significantly larger mixing ratios of SO2 and H2O2 during PEM-West A. Emissions from eruption of Mount Pinatubo are a likely cause for the former, while suppressed photochemical activity in winter was probably responsible for the latter. This comparison also highlighted the twofold enhancement in C2H2, C2H6, and C3H8 in the continental north outflow during /PEM-West B. Although this could be due to reduced OH oxidation rates of these species in wintertime, we argue that increased source emissions are primarily responsible.

Published

1997

23. Biomass burning emissions and vertical distribution of atmospheric methyl halides and other reduced carbon gases in the South Atlantic region

Author

J. E. Collins, F. Sherwood Rowland, Bruce E. Anderson, Nicola J. Blake, Tai-Yih Chen, Barkley C. Sive, Glen W. Sachse, and Donald R. Blake

Subjects

Atmospheric Science, Soil Science, Biomass, chemistry.chemical_element, Aquatic Science, Oceanography, Atmospheric sciences, Combustion, Methane, Troposphere, chemistry.chemical_compound, Geochemistry and Petrology, Dry season, Earth and Planetary Sciences (miscellaneous), Earth-Surface Processes, Water Science and Technology, Hydrology, Ecology, Paleontology, Forestry, Trace gas, Geophysics, chemistry, Space and Planetary Science, Carbon dioxide, Environmental science, Carbon

Abstract

The NASA TRACE A experiment (September – October 1992) investigated effects of dry season biomass burning emissions from both South America and southern Africa on the tropical South Atlantic troposphere. Whole air canister samples were collected aboard the NASA DC-8 aircraft and analyzed for a wide range of nonmethane hydrocarbons (NMHCs) and halocarbons. Fast response in situ quantification of CH4, CO, and CO2 were also performed on the DC-8. Sampling took place over Brazilian agricultural areas and southern African savanna where there was active biomass burning. The vertical distribution of the measured gases revealed that the concentrations of most hydrocarbons, methyl halides, CH4, CO, and CO2, were enhanced in the boundary layer of these regions principally as a result of biomass fires. Brazilian and African biomass burning emission ratios were calculated for CH3Br, CH3Cl, CH3I, and NMHCs relative to CO and CO2. Although both fire regions were dominated by efficient (flaming) combustion (CO/CO2 ratios

Published

1996

24. Factors influencing the upper free tropospheric distribution of reactive nitrogen over the South Atlantic during the TRACE A experiment

Author

G. W. Sachse, Gerald L. Gregory, Donald R. Blake, J. E. Collins, Robert W. Talbot, Nicola J. Blake, John D. Bradshaw, Bruce E. Anderson, Scott T. Sandholm, F. S. Rowland, S. Smyth, A. S. Bachmeier, and Hanwant B. Singh

Subjects

Atmospheric Science, Ecology, Reactive nitrogen, Equator, Paleontology, Soil Science, Forestry, Aquatic Science, Oceanography, Atmospheric sciences, Trace gas, Troposphere, Geophysics, Space and Planetary Science, Geochemistry and Petrology, TRACER, Climatology, Atmospheric chemistry, Earth and Planetary Sciences (miscellaneous), Mixing ratio, Environmental science, NOx, Earth-Surface Processes, Water Science and Technology

Abstract

This paper evaluates the potential sources of the enhanced levels of NO that were observed throughout the upper troposphere over the equatorial and tropical South Atlantic. During September/October 1992 NOx (NO + NO2) mixing ratios in the 8- to 13-km region averaged 150 parts per trillion by volume (pptv) and were greatly affected by what appeared as spatially large “plumes” (100 to 1000 km) with NO enhancements of over 800 parts per trillion by volume. Other trace gases were also enhanced within these plumes (e.g., CO, CO2, CH4, CH3Cl, C2H2, C2H6, C3H8, and PAN). However, for these tracers of surface emissions, inconsistent patterns of enhancement were found with respect to one another and to NO. We analyzed these plumes for indications of coherent relationships between the enhanced levels of NO and the enhanced levels of biogenic and combustion-related tracers. This analysis indicated that the tracer relationships were primarily produced by their common injection via deep convection into the upper troposphere. A corollary analysis using a combustion tracer reference frame in combination with meteorological analysis indicates a longer than expected lifetime of NOx in the upper troposphere. This analysis also suggests that an efficient mechanism may exist in the upper troposphere for recycling HNO3 back into NOx with a rate comparable to that predicted for the HNO3 formation. During the Transport and Atmospheric Chemistry Near the Equator Atlantic study period this in-situ formation of NOx is estimated to provide the equivalent of approximately 0.7 TgN/yr of NOx within the South Atlantic basin's upper troposphere. This magnitude of local in situ source is estimated to be comparable to the combined inputs from lightning and biomass burning, which are both injected via deep convection. Our analysis also suggests that lightning can contribute as much as half of the external input of NOx into this region of the upper troposphere with biomass burning possibly representing the remainder.

Published

1996

25. Aerosols from biomass burning over the tropical South Atlantic region: Distributions and impacts

Author

Donald R. Bagwell, Donald R. Blake, Nicola J. Blake, Charles H. Hudgins, Bruce E. Anderson, Gerald L. Gregory, Glen W. Sachse, William B. Grant, Edward V. Browell, and J. E. Collins

Subjects

Atmospheric Science, Haze, Ecology, Northern Hemisphere, Paleontology, Soil Science, Forestry, Aquatic Science, Oceanography, Marine stratocumulus, Aerosol, Troposphere, chemistry.chemical_compound, Geophysics, chemistry, Space and Planetary Science, Geochemistry and Petrology, Anticyclone, Climatology, Cloud albedo, Earth and Planetary Sciences (miscellaneous), Environmental science, Tropospheric ozone, Earth-Surface Processes, Water Science and Technology

Abstract

The NASA Global Tropospheric Experiment (GTE) Transport and Atmospheric Chemistry Near the Equator-Atlantic (TRACE A) expedition was conducted September 21 through October 26, 1992, to investigate factors responsible for creating the seasonal South Atlantic tropospheric ozone maximum. During these flights, fine aerosol (0.1–3.0 μm) number densities were observed to be enhanced roughly tenfold over remote regions of the tropical South Atlantic and greater over adjacent continental areas, relative to northern hemisphere observations and to measurements recorded in the same area during the wet season. Chemical and meteorological analyses as well as visual observations indicate that the primary source of these enhancements was biomass burning occurring within grassland regions of north central Brazil and southeastern Africa. These fires exhibited fine aerosol (N) emission ratios relative to CO (dN/dCO) of 22.5 ± 9.7 and 23.6 ± 15.1 cm−3 parts per billion by volume (ppbv)−1 over Brazil and Africa, respectively. Convection coupled with counterclockwise flow around the South Atlantic subtropical anticyclone subsequently distributed these aerosols throughout the remote South Atlantic troposphere. We calculate that dilute smoke from biomass burning produced an average tenfold enhancement in optical depth over the continental regions as well as a 50% increase in this parameter over the middle South Atlantic Ocean; these changes correspond to an estimated net cooling of up to 25 W m−2 and 2.4 W m−2 during clear-sky conditions over savannas and ocean respectively. Over the ocean our analyses suggest that modification of CCN concentrations within the persistent eastern Atlantic marine stratocumulus clouds by entrainment of subsiding haze layers could significantly increase cloud albedo resulting in an additional surface radiative cooling potentially greater in magnitude than that caused by direct extinction of solar radiation by the aerosol particles themselves.

Published

1996

26. Hydrocarbon and halocarbon measurements as photochemical and dynamical indicators of atmospheric hydroxyl, atomic chlorine, and vertical mixing obtained during Lagrangian flights

Author

Oliver W. Wingenter, Nicola J. Blake, Donald R. Blake, Tyrrel W. Smith, Michael K. Kubo, and F. Sherwood Rowland

Subjects

Atmospheric Science, Ecology, Planetary boundary layer, Mixed layer, Paleontology, Soil Science, Forestry, Aquatic Science, Oceanography, Atmospheric sciences, Trace gas, Aerosol, Troposphere, Geophysics, Space and Planetary Science, Geochemistry and Petrology, Earth and Planetary Sciences (miscellaneous), Environmental science, Surface layer, Stratosphere, Air mass, Earth-Surface Processes, Water Science and Technology

Abstract

Nonmethane hydrocarbons and halocarbons were measured during two Lagrangian experiments conducted in the lower troposphere of the North Atlantic as part of the June 1992, Atlantic Stratosphere Transition Experiment/Marine Aerosol and Gas Exchange (ASTEX/MAGE) expedition. The first experiment was performed in very clean marine air. Meteorological observations indicate that the height of the marine boundary layer rose rapidly, entraining free tropospheric air. However, the free tropospheric and marine boundary layer halocarbon concentrations were too similar to allow this entrainment to be quantified by these measurements. The second Lagrangian experiment took place along the concentration gradient of an aged continental air mass advecting from Europe. The trace gas measurements confirm that the National Center for Atmospheric Research (NCAR) Electra aircraft successfully intercepted the same air mass on consecutive days. Two layers, a surface layer and a mixed layer with chemically distinct compositions, were present within the marine boundary layer. The composition of the free troposphere was very different from that of the mixed layer, making entrainment from the free troposphere evident. Concentrations of the nonmethane hydrocarbons in the Lagrangian surface layer were observed to become depleted relative to the longer-lived tetrachloroethene. A best fit to the observations was calculated using various combinations of the three parameters, loss by reaction with hydroxyl, loss by reaction with chlorine, and/or dilution from the mixed layer. These calculations provided estimated average concentrations in the surface layer for a 5-hour period from dawn to 11 UT of 0.3 ± 0.5 × 106 molecules cm−3 for HO, and 3.3 ± 1.1 × 104 molecules cm−3 for Cl. Noontime concentration estimates were 2.6 ± 0.7 × 106 molecules cm−3 for HO and 6.5 ± 1.4 × 104 molecules cm−3 for Cl.

Published

1996

27. Nonmethane hydrocarbon and halocarbon distributions during Atlantic Stratocumulus Transition Experiment/Marine Aerosol and Gas Exchange, June 1992

Author

Donald R. Blake, F. Sherwood Rowland, Tyrrel W. Smith, Nicola J. Blake, and Oliver W. Wingenter

Subjects

Atmospheric Science, Ozone, Planetary boundary layer, Soil Science, Aquatic Science, Oceanography, Atmospheric sciences, Troposphere, chemistry.chemical_compound, Geochemistry and Petrology, Earth and Planetary Sciences (miscellaneous), Tropospheric ozone, Air mass, Earth-Surface Processes, Water Science and Technology, Ecology, Paleontology, Forestry, Trace gas, Aerosol, Geophysics, chemistry, Space and Planetary Science, Environmental science, Outflow

Abstract

Aircraft measurements of selected nonmethane hydrocarbon and halocarbon species were made in the lower troposphere of the NE Atlantic near the Azores, Portugal, during June 1992 as part of the Atlantic Stratocumulus Transition Experiment/Marine Aerosol and Gas Exchange. In this paper, the impact of continental outflow from both Europe and North America on the study region were assessed. Four main air mass types were characterized from trajectories and trace gas concentrations: clean marine from the Atlantic, and continental air from the Iberian Peninsula, the British Isles and Northern Europe, and North America. Each classification exhibited trace gas concentrations that had been modified en route by photochemical processes and mixing. Comparison with the clean marine boundary layer (MBL) shows that the boundary layer of the predominantly continental air masses were enhanced in hydrocarbons and halocarbons by factors of approximately 2 for ethane, 5 for propane, 2–6 for ethyne and benzene, and 2–3 for C2Cl4. The same air masses also exhibited large ozone enhancements, with 2 to 3 times higher mixing ratios in the continental boundary layer air compared to the clean MBL. This indicates a primarily anthropogenic photochemical source for a significant fraction of the lower tropospheric ozone in this region. Methyl bromide exhibited on average 10–20% higher concentrations in the boundary layer affected by continental outflow than in the clean MBL, and was seen to be enhanced in individual plumes of air of continental origin. This is consistent with significant anthropogenic sources for methyl bromide. In addition, median MBL concentrations of ethene and methyl iodide showed enhancements of approximately a factor of 2 above free tropospheric values, suggesting primarily coastal/oceanic sources for these species.

Published

1996

28. Three-dimensional distribution of nonmenthane hydrocarbons and halocarbons over the northwestern Pacific during the 1991 Pacific Exploratory Mission (PEM-West A)

Author

Oliver W. Wingenter, Tai-Yih Chen, Donald R. Blake, Tyrrel W. Smith, Edward W. Mayer, F. S. Rowland, Nicola J. Blake, and Charles J.-L. Wang

Subjects

Pollution, Atmospheric Science, media_common.quotation_subject, Air pollution, Soil Science, Aquatic Science, Oceanography, medicine.disease_cause, Troposphere, Deep convection, Altitude, Geochemistry and Petrology, Natural gas, Atmospheric convection, Earth and Planetary Sciences (miscellaneous), medicine, Earth-Surface Processes, Water Science and Technology, media_common, Ecology, business.industry, Paleontology, Forestry, Trace gas, Geophysics, Space and Planetary Science, Environmental science, business

Abstract

A total of 1667 whole air samples were collected onboard the NASA DC-8 aircraft during the 6-week Pacific Exploratory Mission over the western Pacific (PEM-West A) in September and October 1991. The samples were assayed for 15 C2-C7 hydrocarbons and six halocarbons. Latitudinal (0.5°S to 59.5°N) and longitudinal (114°E to 122°W) profiles were obtained from samples collected between ground level and 12.7 km. Thirteen of the 18 missions exhibited at least one vertical profile where the hydrocarbon mixing ratios increased with altitude. Longitude-latitude color patch plots at three altitude levels and three-dimensional color latitude-altitude and longitude-altitude contour plots exhibit a significant number of middle-upper tropospheric pollution events. These and several lower tropospheric pollution plumes were characterized by comparison with urban data from Tokyo and Hong Kong, as well as with natural gas and the products from incomplete combustion. Elevated levels of nonmethane hydrocarbons (NMHC) and other trace gases in the upper-middle free troposphere were attributed to deep convection over the Asian continent and to typhoon-driven convection near the western Pacific coast of Asia. In addition, NMHCs and CH3CCl3 were found to be useful tracers with which to distinguish hydrocarbon and halocarbon augmented plumes emitted from coastal Asian cities into the northwestern Pacific.

Published

1996

29. The seasonal variation of nonmethane hydrocarbons in the free troposphere over the North Atlantic Ocean: Possible evidence for extensive reaction of hydrocarbons with the nitrate radical

Author

Nicola J. Blake, G. Butcher, P. Lightman, Stuart A. Penkett, P. Anwyl, and A. R. W. Marsh

Subjects

Atmospheric Science, Ozone, Radical, Soil Science, Aquatic Science, Oceanography, Reaction rate, Troposphere, chemistry.chemical_compound, Geochemistry and Petrology, Earth and Planetary Sciences (miscellaneous), Air mass, Earth-Surface Processes, Water Science and Technology, chemistry.chemical_classification, Ecology, Paleontology, Forestry, Geophysics, Hydrocarbon, chemistry, Space and Planetary Science, Atmospheric chemistry, Environmental chemistry, Hydroxyl radical

Abstract

Detailed observations have been made of the seasonal variation in concentration of a wide range of nonmethane hydrocarbons over the North Atlantic Ocean in air with a predominantly polar maritime origin. The results bear out many of the findings of our previous studies [Lightman et al., 1990] with the observation of a concentration maximum in the winter and a minimum in the summer. The more recent results indicate that the amplitude of the seasonal cycle is remarkably constant. Also the total concentration of reactive carbon in the various forms of nonmethane hydrocarbons probably exceeds 20 ppbC. This constitutes a substantial reservoir of material which could take part in ozone production in the relatively remote troposphere, if sufficient nitrogen oxides are copresent. The hydrocarbon composition of air in winter is strongly dependent on its origin, with tropical air having a composition similar to polar air in the spring months. The relative magnitude of the seasonal cycles for some hydrocarbons is proportional to their rates of reaction with hydroxyl radicals. This is true for straight chain paraffins up to C5, acetylene and benzene, and it suggests that the removal of these molecules from the atmosphere occurs predominantly by reaction with hydroxyl radicals. For other molecules, particularly branched chain paraffins and substituted aromatic molecules, there is evidence that other removal processes are operating in competition with the hydroxyl radical, especially in winter. Arguments are advanced that in the case of the branched chain paraffins this may be caused by reaction with nitrate radicals.

Published

1993

30. Estimates of atmospheric hydroxyl radical concentrations from the observed decay of many reactive hydrocarbons in well-defined urban plumes

Author

A. R. W. Marsh, Stuart A. Penkett, Nicola J. Blake, P. Anwyl, P. Lightman, Kevin C. Clemitshaw, and G. Butcher

Subjects

Pollution, Atmospheric Science, Ozone, Meteorology, media_common.quotation_subject, Radical, Soil Science, Aquatic Science, Oceanography, Photochemistry, chemistry.chemical_compound, Geochemistry and Petrology, Earth and Planetary Sciences (miscellaneous), Earth-Surface Processes, Water Science and Technology, media_common, chemistry.chemical_classification, Ecology, Paleontology, Forestry, Plume, Geophysics, Hydrocarbon, Atmosphere of Earth, chemistry, Space and Planetary Science, Atmospheric chemistry, Hydroxyl radical

Abstract

An analytical system has been developed which allows the confident identification and measurement of 35 hydrocarbons of different reactivities in air samples collected in many locations. This paper describes the application of the technique to follow the differential decay of hydrocarbons in urban plumes spreading from London during the summer. The data have been used to determine atmospheric hydroxyl radical concentrations, averaged over several hours, on the assumption that the decay of the hydrocarbons is entirely due to reaction with these radicals. Hydroxyl radical concentrations were derived from the measured decay of several alkenes which agreed with theoretical estimates. There are strong indications, however, that substituted aromatic molecules decay much faster than could be accounted for solely by reaction with hydroxyl radicals; this may indicate the presence of a further chemical removal mechanism. 18 refs., 9 figs., 5 tabs.

Published

1993

31. Role of convection in redistributing formaldehyde to the upper troposphere over North America and the North Atlantic during the summer 2004 INTEX campaign

Author

Xinrong Ren, Gao Chen, Michael Porter, R. Shetter, Antony D. Clarke, Cameron S. McNaughton, J. Snow, James H. Crawford, Stephanie A. Vay, Kenneth E. Pickering, Ronald C. Cohen, Petter Weibring, Glen W. Sachse, Timothy H. Bertram, S. Kim, Dylan B. Millet, Hanwant B. Singh, Donald R. Blake, Nicola J. Blake, Alan Fried, Jennifer R. Olson, Brian G. Heikes, Lee Thornhill, James Walega, William H. Brune, Frank K. Tittel, Haiwei Shen, Glenn S. Diskin, G. Huey, Chad Roller, Jeremy Halland, Dirk Richter, Daniel O'Sullivan, Samuel R. Hall, Melody A. Avery, Bruce E. Anderson, Henry E. Fuelberg, and James R. Podolske

Subjects

Convection, Atmospheric Science, Ecology, Atmospheric circulation, Paleontology, Soil Science, Forestry, Aquatic Science, Oceanography, Troposphere, Boundary layer, Geophysics, Space and Planetary Science, Geochemistry and Petrology, Climatology, Atmospheric chemistry, Trend surface analysis, Earth and Planetary Sciences (miscellaneous), Stratosphere, Air mass, Earth-Surface Processes, Water Science and Technology

Abstract

Measurements of CH2O from a tunable diode laser absorption spectrometer (TDLAS) were acquired onboard the NASA DC-8 during the summer 2004 INTEX-NA (Intercontinental Chemical Transport Experiment - North America) campaign to test our understanding of convection and production mechanisms in the upper troposphere (UT, 6-12-km) over continental North America and the North Atlantic Ocean. Point-by-point comparisons with box model calculations, when MHP (CH3OOH) measurements were available for model constraint, resulted in a median CH2O measurement/model ratio of 0.91 in the UT. Multiple tracers were used to arrive at a set of UT CH2O background and perturbed air mass periods, and 46% of the TDLAS measurements fell within the latter category. At least 66% to 73% of these elevated UT observations were caused by enhanced production from CH2O precursors rather than direct transport of CH2O from the boundary layer. This distinction is important, since the effects from the former can last for over a week or more compared to one day or less in the case of convective transport of CH2O itself. In general, production of CH2O from CH4 was found to be the dominant source term, even in perturbed air masses. This was followed by production from MHP, methanol, PAN type compounds, and ketones, in descending order of their contribution. In the presence of elevated NO from lightning and potentially from the stratosphere, there was a definite trend in the CH2O discrepancy, which for the highest NO mixing ratios produced a median CH2O measurement/model ratio of 3.9 in the 10-12-km range. Discrepancies in CH2O and HO2 in the UT with NO were highly correlated and this provided further information as to the possible mechanism(s) responsible. These discrepancies with NO are consistent with additional production sources of both gases involving CH3O2 + NO reactions, most likely caused by unmeasured hydrocarbons.

Published

2008

32. Carbonyl sulfide (OCS): Large-scale distributions over North America during INTEX-NA and relationship to CO2

Author

Michael A. Kamboures, B. J. Novak, J. Elliott Campbell, L. Gregory Huey, Donald R. Blake, Stephanie A. Vay, Jason Midyett, F. Sherwood Rowland, Henry E. Fuelberg, Lambert A. Doezema, Andreas J. Beyersdorf, Simone Meinardi, Nicola J. Blake, Jennifer McAdams, Barbara Barletta, A. Baker, and Glen W. Sachse

Subjects

Atmospheric Science, Soil Science, Aquatic Science, Oceanography, Atmospheric sciences, Sink (geography), chemistry.chemical_compound, Geochemistry and Petrology, Earth and Planetary Sciences (miscellaneous), Panache, Mixing ratio, Earth-Surface Processes, Water Science and Technology, Carbonyl sulfide, Low altitude, geography, geography.geographical_feature_category, Ecology, Paleontology, Forestry, Chemical evolution, Geophysics, chemistry, Space and Planetary Science, Atmospheric chemistry, Environmental science, Outflow, Physical geography

Abstract

[1] An extensive set of carbonyl sulfide (OCS) observations were made as part of the NASA Intercontinental Chemical Transport Experiment–North America (INTEX-NA) study, flown from 1 July to 14 August 2004 mostly over the eastern United States and Canada. These data show that summertime OCS mixing ratios at low altitude were dominated by surface drawdown and were highly correlated with CO2. Although local plumes were observed on some low-altitude flight legs, anthropogenic OCS sources were small compared to this sink. These INTEX-NA observations were in marked contrast to the early springtime 2001 Transport and Chemical Evolution over the Pacific experiment, which sampled Asian outflow dominated by anthropogenic OCS emissions. To test the gridded OCS fluxes used in past models, the INTEX-NA observations were combined with the sulfur transport Eulerian model (STEM) regional atmospheric chemistry model for a top-down assessment of bottom-up OCS surface fluxes for North America. Initial STEM results suggest that the modeled fluxes underestimate the OCS plant sink by more than 200%.

Published

2008

33. Characteristics of the atmospheric CO2signal as observed over the conterminous United States during INTEX-NA

Author

Jung-Hun Woo, Amber J. Soja, Leonhard Pfister, Stephanie A. Vay, Alan Fried, Yonghoon Choi, Henry E. Fuelberg, Nicola J. Blake, S. R. Nolf, Glenn S. Diskin, Hanwant B. Singh, Donald R. Blake, Melody A. Avery, Krishna Prasad Vadrevu, and Glen W. Sachse

Subjects

Convection, Atmospheric Science, geography, geography.geographical_feature_category, Ecology, Paleontology, Soil Science, Sampling (statistics), Forestry, Aquatic Science, Oceanography, Geophysics, Altitude, Boreal, Space and Planetary Science, Geochemistry and Petrology, Climatology, Earth and Planetary Sciences (miscellaneous), Mixing ratio, Environmental science, Outflow, Oceanic basin, Air mass, Earth-Surface Processes, Water Science and Technology

Abstract

[1] High resolution in situ measurements of atmospheric CO2 were made from the NASA DC-8 aircraft during the Intercontinental Chemical Transport Experiment–North America (INTEX-NA) campaign, part of the wider International Consortium for Atmospheric Research on Transport and Transformation (ICARTT). During the summer of 2004, eighteen flights comprising 160 h of measurements were conducted within a region bounded by 27 to 53°N and 36 to 139°W over an altitude range of 0.15 to 12 km. These large-scale surveys provided the opportunity to examine the characteristics of the atmospheric CO2 signal over sparsely sampled areas of North America and adjacent ocean basins. The observations showed a high degree of variability (≤18%) due to the myriad source and sink processes influencing the air masses intercepted over the INTEX-NA sampling domain. Surface fluxes had strong effects on continental scale concentration gradients. Clear signatures of CO2 uptake were seen east of the Mississippi River, notably a persistent CO2 deficit in the lowest 2–3 km. When combining the airborne CO2 measurements with LANDSAT and MODIS data products, the lowest CO2 mixing ratios observed during the campaign (337 ppm) were tied to mid-continental agricultural fields planted in corn and soybeans. We used simultaneous measurements of CO, O3, C2Cl4, C2H6, C2H2 and other unique chemical tracers to differentiate air mass types. Coupling these distinct air mass chemical signatures with transport history permitted identification of convection, stratosphere-troposphere exchange, long-range transport from Eastern Asia, boreal wildfires, and continental outflow as competing processes at multiple scales influencing the observed concentrations. Our results suggest these are important factors contributing to the large-scale distribution in CO2 mixing ratios thus these observations offer new constraints in the computation of the North American carbon budget.

Published

2008

34. Halogen-driven low-altitude O3and hydrocarbon losses in spring at northern high latitudes

Author

Tao Zeng, Yuhang Wang, Brian A. Ridley, Nicola J. Blake, Kelly Chance, and Donald R. Blake

Subjects

Atmospheric Science, Ozone, Chemical transport model, Meteorology, Soil Science, Aquatic Science, Oceanography, Atmospheric sciences, Latitude, Troposphere, chemistry.chemical_compound, Altitude, Geochemistry and Petrology, Earth and Planetary Sciences (miscellaneous), Tropospheric ozone, Earth-Surface Processes, Water Science and Technology, chemistry.chemical_classification, Ecology, Paleontology, Forestry, Ozone depletion, Geophysics, Hydrocarbon, chemistry, Space and Planetary Science, Environmental science

Abstract

[1] Halogen-driven ozone and hydrocarbon losses in springtime Arctic boundary layer are investigated using a regional chemical transport model. Surface observations of ozone at Alert and Barrow and aircraft observations of ozone and hydrocarbons during the Tropospheric Ozone Production about the Spring Equinox (TOPSE) experiment from February to May in 2000 are analyzed. We prescribe halogen radical distributions on the basis of GOME BrO observations. Tropospheric GOME BrO column shows an apparent anticorrelation with surface temperature over high-BrO regions. The enhancements of tropospheric BrO columns coincide with movements of cold polar air masses. While GOME BrO measurements reach the maximum in March, simulated near-surface ozone loss peaks in April because of the increasing daylight hours and hence the time for chemical processing. At its peak, the area of simulated near-surface ozone depletions (O3 50% of the northern high latitudes. Analysis of surface measurements at Alert and Barrow points to the importance of long-range transport of ozone-poor air from high-BrO regions. We find that specifying a BrO layer thickness of 300 m results in the best overall agreement between observed and simulated ozone. The apparent halogen-driven ozone loss up to 1 km was reproduced in the model because of vertical transport of ozone-poor air from low altitudes. When the empirical Cl/Br ratios derived from previous observations are used, the model can reproduce the observed halogen loss of light alkanes and acetylene. The Cl/Br ratios from a recent box model study using an accepted chemical mechanism are, however, much higher than the empirical results. We show that the hydrocarbon loss is not as sensitive to the prescribed thickness of the halogen layer as the ozone loss, therefore representing a more robust measure for evaluating satellite BrO column measurements.

Published

2006

35. Atomic chlorine concentrations derived from ethane and hydroxyl measurements over the equatorial Pacific Ocean: Implication for dimethyl sulfide and bromine monoxide

Author

Barkley C. Sive, F. Sherwood Rowland, Nicola J. Blake, Oliver W. Wingenter, and Donald R. Blake

Subjects

Atmospheric Science, Analytical chemistry, Soil Science, chemistry.chemical_element, Mineralogy, Flux, Aquatic Science, Oceanography, chemistry.chemical_compound, Geochemistry and Petrology, Earth and Planetary Sciences (miscellaneous), Chlorine, Mixing ratio, Sunrise, Surface layer, Earth-Surface Processes, Water Science and Technology, Ecology, Mass balance, Paleontology, Forestry, Geophysics, chemistry, Space and Planetary Science, Dimethyl sulfide, Tampon

Abstract

10 4 Cl cm � 3 , decreasing to 5.7 (±2.0) � 10 4 Cl cm � 3 at midday, is included, the observed and estimated C2H6 values are in excellent agreement. Using our [Cl], we estimate a DMS flux a factor of 2 higher than when HO is the only oxidant considered. This flux estimate, when compared to that derived by Lenschow et al. (1999), suggests that if the differences are real, we may be missing a loss term. Best agreement occurs when an average BrO mixing ratio of 1.3 (±1.3) pptv is included in our mass balance equation.

Published

2005

36. Carbonyl sulfide and carbon disulfide: Large-scale distributions over the western Pacific and emissions from Asia during TRACE-P

Author

Robert W. Talbot, Kazuyuki Kita, Alan R. Bandy, Donald R. Blake, Nicola J. Blake, Glen W. Sachse, Elliot Atlas, Stephanie A. Vay, F. Sherwood Rowland, Isobel J. Simpson, Jack E. Dibb, Henry E. Fuelberg, Simone Meinardi, Jung Hun Woo, Jonathan Green, Melody A. Avery, Donald C. Thornton, and David G. Streets

Subjects

Atmospheric Science, Soil Science, Aquatic Science, Oceanography, Atmospheric sciences, Latitude, chemistry.chemical_compound, Altitude, Geochemistry and Petrology, Earth and Planetary Sciences (miscellaneous), Mixing ratio, Coal, Earth-Surface Processes, Water Science and Technology, Carbonyl sulfide, Ecology, business.industry, Paleontology, Forestry, Geophysics, chemistry, Space and Planetary Science, Period (geology), business, Longitude, Far East, Geology

Abstract

[1] An extensive set of carbonyl sulfide (OCS) and carbon disulfide (CS2) observations were made as part of the NASA Transport and Chemical Evolution over the Pacific (TRACE-P) project, which took place in the early spring 2001. TRACE-P sampling focused on the western Pacific region but in total included the geographic region 110°E to 290°E longitude, 5°N to 50°N latitude, and 0–12 km altitude. Substantial OCS and CS2 enhancements were observed for a great many air masses of Chinese and Japanese origin during TRACE-P. Over the western Pacific, mean mixing ratios of long-lived OCS and shorter-lived CS2 showed a gradual decrease by about 10% and a factor of 5–10, respectively, from the surface to 8–10 km altitude, presumably because land-based sources dominated their distribution during February through April 2001. The highest mean OCS and CS2 levels (580 and 20 pptv, respectively, based on 2.5° × 2.5° latitude bins) were observed below 2 km near the coast of Asia, at latitudes between 25°N and 35°N, where urban Asian outflow was strongest. Ratios of OCS versus CO for continental SE Asia were much lower compared to Chinese and Japanese signatures and were strongly associated with biomass burning/biofuel emissions. We present a new inventory of anthropogenic Asian emissions (including biomass burning) for OCS and CS2 and compare it to emission estimates based on regional relationships of OCS and CS2 to CO and CO2. The OCS and CS2 results for the two methods compare well for continental SE Asia and Japan plus Korea and also for Chinese CS2 emissions. However, it appears that the inventory underestimates Chinese emissions of OCS by about 30–100%. This difference may be related to the fact that we did not include natural sources such as wetland emissions in our inventory, although the contributions from such sources are believed to be at a seasonal low during the study period. Uncertainties in OCS emissions from Chinese coal burning, which are poorly characterized, likely contribute to the discrepancy.

Published

2004

37. An assessment of western North Pacific ozone photochemistry based on springtime observations from NASA's PEM-West B (1994) and TRACE-P (2001) field studies

Author

Brian G. Heikes, Derek M. Cunnold, James H. Crawford, G. Chen, S. J. Oltmans, Nicola J. Blake, Ping Jing, Barry Lefer, Shaw Chen Liu, Yoshiko Kondo, William B. Grant, Edward V. Browell, Scott T. Sandholm, Douglas D. Davis, Marta A. Fenn, Stephanie A. Vay, C. H. Hudgins, John D. W. Barrick, Melody A. Avery, Bruce E. Anderson, Richard E. Shetter, David Tan, B. DiNunno, Donald R. Blake, and G. W. Sachse

Subjects

Atmospheric Science, Ozone, Ecology, Range (biology), Ozone photochemistry, Spring season, Paleontology, Soil Science, Forestry, Photochemical ozone, Aquatic Science, Oceanography, Latitude, chemistry.chemical_compound, Geophysics, chemistry, Space and Planetary Science, Geochemistry and Petrology, Climatology, Earth and Planetary Sciences (miscellaneous), Environmental science, Emission inventory, Earth-Surface Processes, Water Science and Technology, Calendar time

Abstract

[1] The current study provides a comparison of the photochemical environments for two NASA field studies focused on the western North Pacific (PEM-West-B (PWB) and TRACE-P (TP)). These two studies were separated in calendar time by approximately 7 years. Both studies were carried out under springtime conditions, with PWB being launched in 1994 and TP being deployed in 2001 (i.e., 23 February–15 March 1994 and 10 March–15 April 2001, respectively). Because of the 7-year time separation, these two studies presented a unique scientific opportunity to assess whether evidence could be found to support the Department of Energy's projections in 1997 that increases in anthropogenic emissions from East Asia could reach 5%/yr. Such projections would lead one to the conclusion that a significant shift in the atmospheric photochemical properties of the western North Pacific would occur. To the contrary, the findings from this study support the most recent emission inventory data [Streets et al., 2003] in that they show no significant systematic trend involving increases in any O3 precursor species and no evidence for a significant shift in the level of photochemical activity over the western North Pacific. This conclusion was reached in spite of there being real differences in the concentration levels of some species as well as differences in photochemical activity between PWB and TP. However, nearly all of these differences were shown to be a result of a near 3-week shift in TP's sampling window relative to PWB, thus placing it later in the spring season. The photochemical enhancements seen during TP were most noticeable for latitudes in the range of 25–45°N. Most important among these were increases in J(O1D), OH, and HO2 and values for photochemical ozone formation and destruction, all of which were typically two times larger than those calculated for PWB. A comparison of these airborne results with ozonesonde data from four Japanese stations provided further evidence showing that the 3-week shift in the respective sampling windows of PWB and TP was a likely cause for the differences seen in O3 levels and in photochemical activity between the two airborne studies.

Published

2003

38. Intercontinental transport of pollution manifested in the variability and seasonal trend of springtime O3at northern middle and high latitudes

Author

Robert W. Talbot, Nicola J. Blake, Frank Flocke, Changsub Shim, Jack E. Dibb, Brian A. Ridley, Andrew J. Weinheimer, Elliot Atlas, Donald R. Blake, Anthony J. Wimmers, Yunsoo Choi, Jennie L. Moody, and Yuhang Wang

Subjects

Atmospheric Science, Ozone, Ecology, Reactive nitrogen, Paleontology, Soil Science, Forestry, Aquatic Science, Oceanography, Latitude, Troposphere, chemistry.chemical_compound, Geophysics, chemistry, Space and Planetary Science, Geochemistry and Petrology, Climatology, Middle latitudes, Earth and Planetary Sciences (miscellaneous), Potential temperature, Environmental science, Tropospheric ozone, Stratosphere, Earth-Surface Processes, Water Science and Technology

Abstract

[1] Observations (0–8 km) from the Tropospheric Ozone Production about the Spring Equinox (TOPSE) experiment are analyzed to examine air masses contributing to the observed variability of springtime O3 and its seasonal increase at 40°–85°N over North America. Factor analysis using the positive matrix factorization and principal component analysis methods is applied to the data set with 14 chemical tracers (O3, NOy, PAN, CO, CH4, C2H2, C3H8, CH3Cl, CH3Br, C2Cl4, CFC-11, HCFC-141B, Halon-1211, and 7Be) and one dynamic tracer (potential temperature). Our analysis results are biased by the measurements at 5–8 km (70% of the data) due to the availability of 7Be measurements. The identified tracer characteristics for seven factors are generally consistent with the geographical origins derived from their 10 day back trajectories. Stratospherically influenced air accounts for 14 ppbv (35–40%) of the observed O3 variability for data with O3 concentrations

Published

2003

39. BIBLE A whole-air sampling as a window on Asian biogeochemistry

Author

Barkley C. Sive, Scott Elliott, Donald R. Blake, Felisa A. Smith, F. Sherwood Rowland, Manvendra K. Dubey, and Nicola J. Blake

Subjects

Atmospheric Science, Earth science, Soil Science, Aquatic Science, Oceanography, Combustion, Atmosphere, Geochemistry and Petrology, Earth and Planetary Sciences (miscellaneous), Marine ecosystem, Earth-Surface Processes, Water Science and Technology, geography, geography.geographical_feature_category, Ecology, business.industry, Fossil fuel, Paleontology, Biogeochemistry, Forestry, Trace gas, Geophysics, Space and Planetary Science, Atmospheric chemistry, Archipelago, business, Geology

Abstract

[1] Asian trace gas and aerosol emissions into carbon, nitrogen, and other elemental cycles will figure prominently in near term Earth system evolution. Atmospheric hydrocarbon measurements resolve numerous chemical species and can be used to investigate sourcing for key geocarriers. A recent aircraft study of biomass burning and lightning (BIBLE A) explored the East Asian atmosphere and was unique in centering on the Indonesian archipelago. Samples of volatile organics taken over/between the islands of Japan, Saipan, Java, and Borneo are here examined as a guide to whole-air-based studies of future Asian biogeochemistry. The midlatitude onshore/offshore pulse and tropical convection strongly influence concentration distributions. As species of increasing molecular weight are considered, rural, combustion, and industrial source regimes emerge. Methane-rich inputs such as waste treatment and rice cultivation are evidenced in the geostrophic outflow. The Indonesian atmosphere is rich in biomass burning markers and also those of vehicular activity. Complexity of air chemistry in the archipelago is a direct reflection of diverse topography, land use, and local economies in a rapidly developing nation. Conspicuous in its absence is the fingerprint for liquefied petroleum gas leakage, but it can be expected to appear as demand for clean fossil fuels rises along with per capita incomes. Combustion tracers indicate high nitrogen mobilization rates, linking regional terrestrial geocycles with open marine ecosystems. Sea to air fluxes are superimposed on continental and marine backgrounds for the methyl halides. However, ocean hot spots are not coordinated and suggest an intricate subsurface kinetics. Levels of long-lived anthropogenic halocarbons attest to the success of international environmental treaties while reactive chlorine containing species track industrial air masses. The dozens of hydrocarbons resolvable by gas chromatographic methods will enable monitoring of upcoming Asian modernization. Crucial uncertainties are underscored. Signatures for Asian combustion processes and megacities have been obtained only indirectly or at a distance. Detailed fingerprinting must be combined with regular aircraft and ground station measurements to maximize utility of the database.

Published

2003

40. Steady state free radical budgets and ozone photochemistry during TOPSE

Author

Richard E. Shetter, Lee Mauldin, Donald R. Blake, B J Heikes, E. Kosciuch, Eric Scheuer, Christopher A. Cantrell, Robert W. Talbot, James W. Hannigan, Teresa Campos, Nicola J. Blake, J. Snow, S. Stephens, Jack E. Dibb, Brian A. Ridley, Edward V. Browell, Samuel R. Hall, Jimena P. Lopez, B. Wert, Fred L. Eisele, M. T. Coffey, Alan Fried, Barry Lefer, James Walega, Aaron S. Katzenstein, Frank Flocke, Andrew J. Weinheimer, Elliot Atlas, Mark A. Zondlo, and Garry Seid

Subjects

Atmospheric Science, Ozone, Ozone photochemistry, Formaldehyde, Soil Science, Steady State theory, Aquatic Science, Oceanography, Atmospheric sciences, Latitude, chemistry.chemical_compound, Geochemistry and Petrology, Photostationary state, Earth and Planetary Sciences (miscellaneous), Tropospheric ozone, Earth-Surface Processes, Water Science and Technology, Ecology, Paleontology, Forestry, Geophysics, chemistry, Space and Planetary Science, Climatology, Middle latitudes, Environmental science

Abstract

[1] A steady state model, constrained by a number of measured quantities, was used to derive peroxy radical levels for the conditions of the Tropospheric Ozone Production about the Spring Equinox (TOPSE) campaign. The analysis is made using data collected aboard the NCAR/NSF C-130 aircraft from February through May 2000 at latitudes from 40° to 85°N, and at altitudes from the surface to 7.6 km. HO2 + RO2 radical concentrations were measured during the experiment, which are compared with model results over the domain of the study showing good agreement on the average. Average measurement/model ratios are 1.04 (σ = 0.73) and 0.96 (σ = 0.52) for the MLB and HLB, respectively. Budgets of total peroxy radical levels as well as of individual free radical members were constructed, which reveal interesting differences compared to studies at lower latitudes. The midlatitude part of the study region is a significant net source of ozone, while the high latitudes constitute a small net sink leading to the hypothesis that transport from the middle latitudes can explain the observed increase in ozone in the high latitudes. Radical reservoir species concentrations are modeled and compared with the observations. For most conditions, the model does a good job of reproducing the formaldehyde observations, but the peroxide observations are significantly less than steady state for this study. Photostationary state (PSS) derived total peroxy radical levels and NO/NO2 ratios are compared with the measurements and the model; PSS-derived results are higher than observations or the steady state model at low NO concentrations.

Published

2003

41. The seasonal evolution of NMHCs and light alkyl nitrates at middle to high northern latitudes during TOPSE

Author

Aaron S. Katzenstein, Donald R. Blake, Nicola J. Blake, Oliver W. Wingenter, Barkley C. Sive, Simone Meinardi, Frank Flocke, Brian A. Ridley, Elliot Atlas, and F. Sherwood Rowland

Subjects

Atmospheric Science, Ecology, Northern Hemisphere, Paleontology, Soil Science, Forestry, Aquatic Science, Oceanography, Atmospheric sciences, Trace gas, Troposphere, chemistry.chemical_compound, Geophysics, Altitude, chemistry, Arctic, Space and Planetary Science, Geochemistry and Petrology, Climatology, Earth and Planetary Sciences (miscellaneous), Mixing ratio, Tropospheric ozone, Air mass, Earth-Surface Processes, Water Science and Technology

Abstract

[1] The Tropospheric Ozone Production about the Spring Equinox (TOPSE) experiment was designed to follow the role of photochemistry in the evolution of the springtime maximum of tropospheric ozone (O3) in the Northern Hemisphere (NH) at high latitudes. Determination of the composition and seasonal evolution of volatile organic carbon (VOC) species, which take part in and are good indicators for photochemical processes in the troposphere, was an important part of this study. We report measurements of a large number of C2–C10 nonmethane hydrocarbons (NMHCs), selected C1–C2 halocarbons, and C1–C4 alkyl nitrates. These gases were quantified in whole air samples collected aboard the National Center for Atmospheric Research (NCAR) C-130 aircraft at altitudes between 30 m and 8 km. Seven TOPSE sampling trips were flown between early February and mid-May 2000 covering the region from Colorado (40°N) to Churchill (in Manitoba, Canada), Thule (in northern Greenland), and as far north as 85°N. These measurements represent the most comprehensive spatial characterization of the North American Arctic to date and revealed strong latitudinal, vertical, and temporal NMHC gradients. In the midtroposphere north of Churchill (58°N), ΣNMHCs decreased by ∼6.2 ppbC between February and May (1.6 ppbC month−1) and the magnitude of this change diminished with altitude. Over the same period, midtropospheric O3 levels increased by ∼16 ppbv (4.2 ppbv month−1). Free tropospheric NMHC decreases were consistent with removal by hydroxyl (OH) radicals at an average mixing ratio for mid-March to mid-May of 4.1 × 105 mol cm−3. The alkyl nitrates, which are a reservoir species for tropospheric reactive odd nitrogen (NOY), revealed similar latitudinal, vertical, and temporal gradients to their parent NMHCs. Their total decreased by ∼4 pptv month−1, representing 10% or less of NOY. In conjunction with meteorological trajectory analysis, different trace gas signatures provided significant clues to the origins of individual polluted air masses. Several of these air masses were rapidly advected over the Pole from source regions in northeastern and western Europe as well as an air mass that originated over the southwestern United States/Baja California that contained unusually high levels of alkanes. In addition, episodes of low boundary layer (BL) O3 associated with low NMHC mixing ratios and trajectories from over the Arctic Ocean were frequently sampled toward the latter part of the experiment. The TOPSE data described here provide a unique picture of NH trace gas evolution from winter to summer that will be invaluable to models investigating the role that anthropogenic emissions play in high latitude O3 chemistry.

Published

2003

42. Ozone depletion events observed in the high latitude surface layer during the TOPSE aircraft program

Author

Anthony J. Wimmers, William B. Grant, Edward V. Browell, J. W. Hair, Robert W. Talbot, Richard E. Shetter, Ronald C. Cohen, James Walega, James W. Hannigan, M. T. Coffey, B. Wert, Andrew J. Weinheimer, Frank Flocke, Roy L. Mauldin, Joel A. Thornton, L. Cinquini, Christopher A. Cantrell, B J Heikes, Elliot Atlas, Jennie L. Moody, Alan Fried, Barry Lefer, Jack E. Dibb, Brian A. Ridley, F. E. Grahek, J. Snow, Denise D. Montzka, Louisa K. Emmons, Nicola J. Blake, Donald R. Blake, Russell J. DeYoung, and Fred Eisele

Subjects

Atmospheric Science, Soil Science, Aquatic Science, Oceanography, Atmospheric sciences, Latitude, chemistry.chemical_compound, Altitude, Geochemistry and Petrology, Ozone layer, Earth and Planetary Sciences (miscellaneous), Tropospheric ozone, Surface layer, Earth-Surface Processes, Water Science and Technology, Ecology, Paleontology, Forestry, Snow, Ozone depletion, Geophysics, Arctic, chemistry, Space and Planetary Science, Climatology, Environmental science

Abstract

[1] During the Tropospheric Ozone Production about the Spring Equinox (TOPSE) aircraft program, ozone depletion events (ODEs) in the high latitude surface layer were investigated using lidar and in situ instruments. Flight legs of 100 km or longer distance were flown 32 times at 30 m altitude over a variety of regions north of 58° between early February and late May 2000. ODEs were found on each flight over the Arctic Ocean but their occurrence was rare at more southern latitudes. However, large area events with depletion to over 2 km altitude in one case were found as far south as Baffin Bay and Hudson Bay and as late as 22 May. There is good evidence that these more southern events did not form in situ but were the result of export of ozone-depleted air from the surface layer of the Arctic Ocean. Surprisingly, relatively intact transport of ODEs occurred over distances of 900–2000 km and in some cases over rough terrain. Accumulation of constituents in the frozen surface over the dark winter period cannot be a strong prerequisite of ozone depletion since latitudes south of the Arctic Ocean would also experience a long dark period. Some process unique to the Arctic Ocean surface or its coastal regions remains unidentified for the release of ozone-depleting halogens. There was no correspondence between coarse surface features such as solid ice/snow, open leads, or polynyas with the occurrence of or intensity of ozone depletion over the Arctic or subarctic regions. Depletion events also occurred in the absence of long-range transport of relatively fresh “pollution” within the high latitude surface layer, at least in spring 2000. Direct measurements of halogen radicals were not made. However, the flights do provide detailed information on the vertical structure of the surface layer and, during the constant 30 m altitude legs, measurements of a variety of constituents including hydroxyl and peroxy radicals. A summary of the behavior of these constituents is made. The measurements were consistent with a source of formaldehyde from the snow/ice surface. Median NOx in the surface layer was 15 pptv or less, suggesting that surface emissions were substantially converted to reservoir constituents by 30 m altitude and that ozone production rates were small (0.15–1.5 ppbv/d) at this altitude. Peroxyacetylnitrate (PAN) was by far the major constituent of NOy in the surface layer independent of the ozone mixing ratio.

Published

2003

43. Airborne tunable diode laser measurements of formaldehyde during TRACE-P: Distributions and box model comparisons

Author

Nicola J. Blake, Henry E. Fuelberg, Richard E. Shetter, J. Snow, David Tan, Alan Fried, Barry Lefer, Simone Meinardi, Ian Faloona, James Walega, Daniel O'Sullivan, Bryan P. Wert, Gregory R. Carmichael, Donald R. Blake, Bruce E. Anderson, Brian G. Heikes, Hanwant B. Singh, Carolyn E. Jordan, Glen W. Sachse, William T. Potter, Christopher M. Kiley, Scott T. Sandholm, Charles Harward, Jennifer R. Olson, and James H. Crawford

Subjects

Pollution, Atmospheric Science, Tunable diode laser absorption spectroscopy, Steady state, Ecology, Meteorology, media_common.quotation_subject, Paleontology, Soil Science, Steady State theory, Forestry, Aquatic Science, Oceanography, Aerosol, Troposphere, Geophysics, Altitude, Space and Planetary Science, Geochemistry and Petrology, Earth and Planetary Sciences (miscellaneous), Environmental science, Longitude, Earth-Surface Processes, Water Science and Technology, media_common

Abstract

[1] Airborne measurements of CH2O were acquired employing tunable diode laser absorption spectroscopy during the 2001 Transport and Chemical Evolution Over the Pacific (TRACE-P) study onboard NASA's DC-8 aircraft. Above ∼2.5 km, away from the most extreme pollution influences and heavy aerosol loadings, comprehensive comparisons with a steady state box model revealed agreement to within ±37 pptv in the measurement and model medians binned according to altitude and longitude. Likewise, a near unity slope (0.98 ± 0.03) was obtained from a bivariate fit of the measurements, averaged into 25 pptv model bins, versus the modeled concentrations for values up to ∼450 pptv. Both observations suggest that there are no systematic biases on average between CH2O measurements and box model results out to model values ∼450 pptv. However, the model results progressively underpredict the observations at higher concentrations, possibly due to transport effects unaccounted for in the steady state model approach. The assumption of steady state also appears to contribute to the scatter observed in the point-by-point comparisons. The measurement-model variance was further studied employing horizontal flight legs. For background legs screened using a variety of nonmethane hydrocarbon (NMHC) tracers, measurement and model variance agreed to within 15%. By contrast, measurement variance was ∼60% to 80% higher than the model variance, even with small to modest elevations in the NMHC tracers. Measurement-model comparisons of CH2O in clouds and in the lower marine troposphere in the presence of marine aerosols suggest rather significant CH2O uptake by as much as 85% in one extreme case compared to expectations based on modeled gas phase processes.

Published

2003

44. Chemical composition of Asian continental outflow over the western Pacific: Results from Transport and Chemical Evolution over the Pacific (TRACE-P)

Author

Henry E. Fuelberg, Nicola J. Blake, Scott T. Sandholm, Hanwant B. Singh, Rachel S. Russo, Eric Scheuer, Carolyn E. Jordan, Donald R. Blake, Melody A. Avery, Stephanie A. Vay, Jack E. Dibb, David Tan, Garry Seid, Alan Fried, Elliot Atlas, G. W. Sachse, B J Heikes, J. Snow, and Robert W. Talbot

Subjects

Atmospheric Science, Biomass (ecology), Ecology, Paleontology, Soil Science, Forestry, Aquatic Science, Effects of high altitude on humans, Oceanography, Atmospheric sciences, Troposphere, Geophysics, Space and Planetary Science, Geochemistry and Petrology, Earth and Planetary Sciences (miscellaneous), Environmental science, East Asia, Outflow, Far East, Longitude, Chemical composition, Earth-Surface Processes, Water Science and Technology

Abstract

We characterize the chemical composition of Asian continental outflow observed during the NASA Transport and Chemical Evolution over the Pacific (TRACE-P) mission during February-April 2001 in the western Pacific using data collected on the NASA DC-8 aircraft. A significant anthropogenic impact was present in the free troposphere and as far east as 150degE longitude reflecting rapid uplift and transport of continental emissions. Five-day backward trajectories were utilized to identify five principal Asian source regions of outflow: central, coastal, north-northwest(NNW), southeast (SE), and west-southwest (WSW). The maximum mixing ratios for several species, such as CO, C2Cl4, CH3Cl, and hydrocarbons, were more than a factor of 2 larger in the boundary layer of the central and coastal regions due to industrial activity in East Asia. CO was well correlated with C2H2, C2H6, C2Cl4, and CH3Cl at low altitudes in these two regions (r(sup 2) approx. 0.77-0.97). The NNW, WSW, and SE regions were impacted by anthropogenic sources above the boundary layer presumably due to the longer transport distances of air masses to the western Pacific. Frontal and convective lifting of continental emissions was most likely responsible for the high altitude outflow in these three regions. Photochemical processing was influential in each source region resulting in enhanced mixing ratios of O3, PAN, HNO3, H2O2, and CH3OOH. The air masses encountered in all five regions were composed of a complex mixture of photcrchemically aged air with more recent emissions mixed into the outflow as indicated by enhanced hydrocarbon ratios (C2H2/CO greater than or equal to 3 and C3H8/C2H6 greater than or equal to 0.2). Combustion, industrial activities, and the burning of biofuels and biomass all contributed to the chemical composition of air masses from each source region as demonstrated by the H6, SO2, and C2Cl4 were compared for the TRACE-P and PEM-West B missions. In the more northern regions, O3, CO, and SO2 were higher at low altitudes during TRACE-P. In general, mixing ratios were fairly similar between the two missions in the southern regions. A comparison between CO/CO2, CO/CH4, C2H6/C3H8, NO(x)/SO2, and NO(y)/(SO2 + nss-SO4) ratios for the five source regions and for the 2000 Asian emissions summary showed vay close agreement indicating that Asian emissions were well represented by the TRACE-P data and tbe emissions inventory.

Published

2003

45. Latitudinal, vertical, and seasonal variations of C1-C4alkyl nitrates in the troposphere over the Pacific Ocean during PEM-Tropics A and B: Oceanic and continental sources

Author

Nicola J. Blake, Frank Flocke, Elliot Atlas, Aaron L. Swanson, F. Sherwood Rowland, and Donald R. Blake

Subjects

Atmospheric Science, Ecology, Butyl nitrate, Paleontology, Soil Science, Forestry, Aquatic Science, Oceanography, Ethyl nitrate, Latitude, Troposphere, chemistry.chemical_compound, Geophysics, Altitude, chemistry, Space and Planetary Science, Geochemistry and Petrology, Earth and Planetary Sciences (miscellaneous), Mixing ratio, Environmental science, Longitude, Air mass, Earth-Surface Processes, Water Science and Technology

Abstract

[1] We present concentration distributions of C1-C4 alkyl nitrates observed during the NASA airborne campaigns Pacific Exploratory Mission (PEM) -Tropics A (September–October 1996) and PEM-Tropics B (March–April 1999). The total geographic range for PEM-Tropics A was 45°N–72°S latitude and 153°E–75°W longitude, and for PEM-Tropics B was 40°N–36°S latitude and 149°E–75°W longitude. The maximum altitude for these missions was 12 km. These experiments provide the most extensive set of tropospheric measurements collected to date over the tropical Pacific Ocean. We observed high methyl nitrate (MeONO2, CH3ONO2) mixing ratios (approximately 50 pptv) at low altitudes in a latitude band between 8°N to 13°S stretching across the equatorial Pacific, illustrating the oceanic source of MeONO2. This source may be associated with the high-nutrient, low-chlorophyll character of equatorial Pacific waters. We discuss MeONO2 and ethyl nitrate (EtONO2, C2H5ONO2), whose abundance is dominated by equatorial oceanic sources, 2-Propyl nitrate (2-PrONO2, 2-C3H7ONO2), which has significant oceanic and northern hemispheric (NH) sources associated with urban/industrial hydrocarbon emissions, and 2-butyl nitrate (2-BuONO2 2-C4H8ONO2), which has mostly NH sources. PEM-Tropics A and B resulted in remarkably similar equatorial mixing ratios. The excellent correlations between MeONO2 and the other alkyl nitrates in this region produced comparable correlation slopes between the two expeditions. By contrast, NH air masses influenced by urban/industrial emissions typically exhibited much lower MeONO2:EtONO2, MeONO2:2-PrONO2, and MeONO2:2-BuONO2 ratios. These relationships can be useful as a diagnostic of air mass origin. North of 10°N, the springtime PEM-Tropics B mixing ratios of C2-C4 alkyl nitrates were many-fold higher at low-mid altitudes than for late summer PEM-Tropics A, consistent with strong continental outflow of NMHC precursors during spring.

Published

2003

46. Seasonal variations of C2–C4nonmethane hydrocarbons and C1–C4alkyl nitrates at the Summit research station in Greenland

Author

Frank Flocke, Nicola J. Blake, Donald R. Blake, Aaron L. Swanson, F. Sherwood Rowland, and Elliot Atlas

Subjects

Atmospheric Science, Soil Science, Aquatic Science, Oceanography, Atmospheric sciences, chemistry.chemical_compound, Nitrate, Geochemistry and Petrology, Propane, Earth and Planetary Sciences (miscellaneous), medicine, Earth-Surface Processes, Water Science and Technology, chemistry.chemical_classification, Ecology, biology, Northern Hemisphere, Paleontology, Forestry, Seasonality, medicine.disease, biology.organism_classification, Annual cycle, Trace gas, Geophysics, Hydrocarbon, chemistry, Space and Planetary Science, Climatology, Environmental science, Groenlandia

Abstract

[1] We report measurements of light (C2–C4) nonmethane hydrocarbons (NMHCs) and C1–C4 alkyl nitrates made at Summit, Greenland, over a full annual cycle (June 1997–1998). The remoteness of the Summit camp from industrial source regions resulted in trends of these trace gases that showed a clear seasonal variation with low variability. Variability (calculated as the percentage 1-sigma deviation of a running 10-point mean) averaged 7–9% for ethane over the entire study. The shorter-lived species (ethyne, propane, and the butanes) exhibited variability from 12–20% in winter to 20–100% in summer. The best fit curve to the annual cycle of ethane is a sinusoidal oscillation, but each of the shorter-lived NMHCs exhibited flat periods of low concentrations during the summer months. The C2–C4 NMHCs peaked between 8 and 24 February, with the longer-lived NMHCs maximizing latest. These data were broadly consistent with literature values, confirming that high-latitude Northern Hemisphere (NH) emissions are similar year to year. Employing their linear fall accumulation rates, we calculated average NMHC ratios versus ethane of 0.59(±0.10):0.33(±0.05):0.26(±0.08):0.14(±0.04) for propane, ethyne, n-butane, and i-butane, respectively. We suggest that these ratios represent useful quantities with which to compare averaged mid- and high-latitude NH emission ratios. We also report the first year-round observations of the seasonal cycle of light C1–C4 alkyl nitrates. Similar to the NMHCs, the seasonal trend of these gases shows primary dependence on transport to Summit during winter, and photochemical removal during summer. Unlike their parent NMHCs, alkyl nitrate concentrations did not asymptote to low levels during summer and they exhibited winter maxima later with decreasing photochemical lifetime.

Published

2003

47. Photochemical production and evolution of selected C2–C5alkyl nitrates in tropospheric air influenced by Asian outflow

Author

F. Sherwood Rowland, Simone Meinardi, Elliot Atlas, Henry E. Fuelberg, Christopher M. Kiley, James H. Crawford, Donald R. Blake, Nicola J. Blake, Frank Flocke, and Isobel J. Simpson

Subjects

chemistry.chemical_classification, Atmospheric Science, Ecology, Paleontology, Soil Science, Forestry, Aquatic Science, Oceanography, Photochemistry, Ethyl nitrate, Dilution, Troposphere, chemistry.chemical_compound, Geophysics, chemistry, Nitrate, Space and Planetary Science, Geochemistry and Petrology, Propane, Earth and Planetary Sciences (miscellaneous), Hydroxyl radical, Alkyl, Air mass, Earth-Surface Processes, Water Science and Technology

Abstract

Author(s): Simpson, IJ; Blake, NJ; Blake, DR; Atlas, E; Flocke, F; Crawford, JH; Fuelberg, HE; Kiley, CM; Meinardi, S; Rowland, FS | Abstract: The photochemical production and evolution of six C2-C5 alkyl nitrates (ethyl-, 1-propyl-, 2-propyl-, 2-butyl-, 2-pentyl-, and 3-pentyl nitrate) was investigated using selected data from 5500 whole air samples collected downwind of Asia during the airborne Transport and Chemical Evolution over the Pacific (TRACE-P) field campaign (February-April 2001). Air mass age was important for selecting appropriate field data to compare with laboratory predictions of C5 alkyl nitrate production rates. In young, highly polluted air masses, the ratio between the production rates of 3-pentyl nitrate and 2-pentyl nitrate from n-pentane was 0.60-0.65. These measured ratios show excellent agreement with results from a field study in Germany (0.63 ± 0.06), and they agree better with predicted ratios from older laboratory kinetic studies (0.63-0.66) than with newer laboratory results (0.73 ± 0.08). TRACE-P samples that did not show influence from marine alkyl nitrate sources were used to investigate photochemical alkyl nitrate evolution. Relative to 2-butyl nitrate/n-butane, the measured ratios of ethyl nitrate/ethane and 2-propyl nitrate/propane showed notable deviations from modeled values based on laboratory kinetic data, suggesting additional Asian sources of their alkyl peroxy radical precursors. By contrast, the measured ratios of 1-propyl-, 2-pentyl-, and 3-pentyl nitrate to their respective parent hydrocarbons were fairly close to modeled values. The 1-propyl nitrate findings contrast with field studies in North America, and suggest that air downwind of Asia was not significantly impacted by additional 1-propyl nitrate precursors. The sensitivity of modeled photochemical processing times to hydroxyl radical concentration, altitude, city ventilation times, and dilution is discussed.

Published

2003

48. NMHCs and halocarbons in Asian continental outflow during the Transport and Chemical Evolution over the Pacific (TRACE-P) Field Campaign: Comparison With PEM-West B

Author

Donald R. Blake, Jimena P. Lopez, Barbara Barletta, Melody A. Avery, Kazuyuki Kita, Nicola J. Blake, Christopher M. Kiley, Elliot Atlas, Glen W. Sachse, Stephanie A. Vay, F. Sherwood Rowland, Aaron L. Swanson, Henry E. Fuelberg, Tomoko Shirai, Isobel J. Simpson, Simone Meinardi, and Aaron S. Katzenstein

Subjects

Atmospheric Science, Ecology, Pacific Rim, Paleontology, Soil Science, Forestry, Aquatic Science, Oceanography, Chemical evolution, Geophysics, Southern china, Space and Planetary Science, Geochemistry and Petrology, Climatology, Earth and Planetary Sciences (miscellaneous), Mixing ratio, Environmental science, Outflow, East Asia, Emission inventory, Field campaign, Earth-Surface Processes, Water Science and Technology

Abstract

[1] We present an overview of the spatial distributions of nonmethane hydrocarbons (NMHCs) and halocarbons observed over the western north Pacific as part of the NASA GTE Transport and Chemical Evolution over the Pacific (TRACE-P) airborne field campaign (February–April 2001). The TRACE-P data are compared with earlier measurements from the Pacific Rim during the Pacific Exploratory Mission-West B (PEM-West B), which took place in February–March 1994, and with emission inventory data for 2000. Despite the limited spatial and temporal data coverage inherent to airborne sampling, mean levels of the longer-lived NMHCs (including ethane, ethyne, and benzene) were remarkably similar to our results during the PEM-West B campaign. By comparison, mixing ratios of the fire extinguisher Halon-1211 (CF2ClBr) increased by about 50% in the period between 1994 and 2001. Southern China (south of 35°N), and particularly the Shanghai region, appears to have been a substantial source of Halon-1211 during TRACE-P. Our previous analysis of the PEM-West B data employed methyl chloroform (CH3CCl3) as a useful industrial tracer. However, regulations have reduced its emissions to the extent that its mixing ratio during TRACE-P was only one-third of that measured in 1994. Methyl chloroform mixing ratio “hot spots,” indicating regions downwind of continuing emissions, included outflow from the vicinity of Shanghai, China, but particularly high emission ratios relative to CO were observed close to Japan and Korea. Tetrachloroethene (C2Cl4) levels have also decreased significantly, especially north of 25°N, but this gas still remains a useful indicator of northern industrial emissions. Methyl bromide (CH3Br) levels were systematically 1–2 pptv lower from 1994 to 2001, in accord with recent reports. However, air masses that had been advected over Japan and/or South Korean port cities typically exhibited elevated levels of CH3Br. As a consequence, emissions of CH3Br from Japan and Korea calculated employing CH3Br/CO ratios and scaled to CO emission inventory estimates, were almost as large as for all of south China (south of 35°N). Total east Asian emissions of CH3Br and CH3Cl were estimated to be roughly 4.7 Gg/yr and 167 Gg/yr, respectively, in 2001.

Published

2003

49. Tunable diode laser measurements of formaldehyde during the TOPSE 2000 study: Distributions, trends, and model comparisons

Author

Richard E. Shetter, J. Snow, M. T. Coffey, Donald R. Blake, Nicola J. Blake, Bob Talbot, Brian G. Heikes, Dieter H. Ehhalt, Yuhang Wang, Christopher A. Cantrell, Alan Fried, Barry Lefer, James W. Hannigan, Elliot Atlas, Jack E. Dibb, Brian A. Ridley, Oliver W. Wingenter, Eric Scheuer, Bryan P. Wert, Simone Meinardi, and James Walega

Subjects

Atmospheric Science, Meteorology, Formaldehyde, Soil Science, Equinox, Aquatic Science, Oceanography, Atmospheric sciences, Latitude, Troposphere, chemistry.chemical_compound, Altitude, Geochemistry and Petrology, ddc:550, tunable diode laser measurements, formaldehyde during TOPSE, Earth and Planetary Sciences (miscellaneous), Tropospheric ozone, Earth-Surface Processes, Water Science and Technology, formaldehyde measurements at high latitudes, Tunable diode laser absorption spectroscopy, Ecology, Paleontology, airborne formaldehyde measurements, Forestry, Geophysics, chemistry, Volume (thermodynamics), Space and Planetary Science, Environmental science

Abstract

[1] Airborne measurements of formaldehyde (CH2O) were acquired employing tunable diode laser absorption spectroscopy (TDLAS) during the 2000 Tropospheric Ozone Production About the Spring Equinox (TOPSE) study. This study consisted of seven deployments spanning the time period from 4 February to 23 May 2000 and covered a wide latitudinal band from 40degreesN to 85degreesN. The median measured CH2O concentrations, with a few exceptions, did not show any clear temporal trends from February to May in each of five altitude and three latitude bins examined. Detailed measurement-model comparisons were carried out using a variety of approaches employing two different steady state models. Because recent emissions of CH2O and/or its precursors often result in model underpredictions, background conditions were identified using a number of chemical tracers. For background conditions at temperatures warmer than -45degreesC, the measurement-model agreement on average ranged between -13% and +5% (measurement-model/measurement), which corresponded to mean and median (measurement-model) differences of 3 +/- 69 and -6 parts per trillion by volume (pptv), respectively. At very low temperatures starting at around -45degreesC, significant and persistent (measurement-model) differences were observed from February to early April from southern Canada to the Arctic Ocean in the 6-8 km altitude range. In such cases, measured CH2O was as much as 392 pptv higher than modeled, and the median difference was 132 pptv (83%). Low light conditions as well as cold temperatures may be important in this effect. A number of possible mechanisms involving the reaction of CH3O2 with HO2 to produce CH2O directly were investigated, but in each case the discrepancy was only minimally reduced. Other possibilities were also considered but in each case there was no compelling evidence to support any of the hypotheses. Whatever the cause, the elevated CH2O concentrations significantly impact upper tropospheric HOx levels at high latitudes (>57degreesN) in the February-April time frame.

Published

2003

50. Peroxy radical behavior during the Transport and Chemical Evolution over the Pacific (TRACE-P) campaign as measured aboard the NASA P-3B aircraft

Author

Donald R. Blake, Mark A. Zondlo, Christopher A. Cantrell, John D. W. Barrick, Andrew J. Weinheimer, Isobel J. Simpson, Yoshiko Kondo, Monica Martinez, Nicola J. Blake, Hartwig Harder, Melody A. Avery, Eric C. Apel, Jennifer R. Olson, Alan Fried, Barry Lefer, Brian G. Heikes, Fred L. Eisele, Samuel R. Hall, Roy L. Mauldin, G. W. Sachse, William H. Brune, Alan R. Bandy, Antony D. Clarke, Frank Flocke, Daniel J. Jacob, James H. Crawford, S. Stephens, E. Kosciuch, Richard E. Shetter, Donald C. Thornton, G. D. Edwards, and Hanwant B. Singh

Subjects

Quenching, Atmospheric Science, Ozone, Ecology, Reactive nitrogen, Radical, Photodissociation, Paleontology, Soil Science, Forestry, Aquatic Science, Oceanography, Kinetic energy, Trace gas, chemistry.chemical_compound, Geophysics, chemistry, Space and Planetary Science, Geochemistry and Petrology, Environmental chemistry, Earth and Planetary Sciences (miscellaneous), NOx, Earth-Surface Processes, Water Science and Technology

Abstract

[1] Peroxy radical concentrations were measured aboard the NASA P-3B aircraft during the Transport and Chemical Evolution over the Pacific (TRACE-P) campaign in the spring of 2001 and varied in ways that depended on radical production rates and reactive nitrogen concentrations. Measurements of HO2 ,H O2 +R O2, and OH during this study allowed calculation of radical ratios, examination of functional relationships of these ratios on controlling variables, and comparison with numerical model estimations. Radical production terms show changes in relative contributions at low, middle, and high total production rates that are understandable in terms of systematic variations in the controlling components (trace gas concentrations and photolysis rate coefficients). Ozone tendency calculations indicate net ozone production in the western Pacific basin because the concentrations of critical precursor trace gases (e.g., NOx, hydrocarbons) are highest there. The dependence of ozone tendency follows the concentration of NO systematically. Peroxy radical levels on the two aircraft (HO2 +R O2 on the P-3B and HO2 on the DC-8) during two relatively short prescribed intercomparison periods were in good agreement in one instance and poorer in another given reasonable assumptions about the apportioning of radicals between HO2 and RO2. Recommended changes to CH2O photolysis quantum yields, HO2 self reaction, and O( 1 D) quenching kinetics lead to small changes (

Published

2003