Your search keyword '"Sommariva, R."' showing total 108 results

1. Factors Influencing the Formation of Nitrous Acid from Photolysis of Particulate Nitrate

Author

Sommariva, R., primary, Alam, M. S., additional, Crilley, L. R., additional, Rooney, D. J., additional, Bloss, W. J., additional, Fomba, K. W., additional, Andersen, S. T., additional, and Carpenter, L. J., additional

Published

2023

2. HOCl and Cl2 observations in marine air

Author

Lawler, M. J, Sander, R., Carpenter, L. J, Lee, J. D, von Glasow, R., Sommariva, R., and Saltzman, E. S

Subjects

atmospheric chemistry, boundary layer, chlorine, marine atmosphere, methane, numerical model, open ocean, photochemistry, troposphere

Abstract

Cl atoms in the marine atmosphere may significantly impact the lifetimes of methane and other hydrocarbons. However, the existing estimates of Cl atom levels in marine air are based on indirect evidence. Here we present measurements of the Cl precursors HOCl and Cl2 in the marine boundary layer during June of 2009 at the Cape Verde Atmospheric Observatory in the eastern tropical Atlantic. These are the first measurements of tropospheric HOCl. HOCl and Cl2 levels were low in air with open ocean back trajectories, with maximum levels always below 60 and 10 ppt (pmol/mol), respectively. In air with trajectories originating over Europe, HOCl and Cl2 levels were higher, with HOCl maxima exceeding 100 ppt each day and Cl2 reaching up to 35 ppt. The increased Cl cycling associated with long distance pollutant transport over the oceans likely impacts a wide geographic area and represents a mechanism by which human activities have increased the reactivity of the marine atmosphere. Data-constrained model simulations indicate that Cl atoms account for approximately 15 % of methane destruction on days when aged polluted air arrives at the site. A photochemical model does not adequately simulate the observed abundances of HOCl and Cl2, raising the possibility of an unknown HOCl source.

Published

2011

3. AtChem (version 1), an open source box-model for the Master Chemical Mechanism

Author

Sommariva, R, Cox, S, Martin, C, Boronska, K, Young, J, Jimack, PK, Pilling, MJ, Matthaios, VN, Nelson, BS, Newland, MJ, Panagi, M, Bloss, WJ, Monks, PS, and Rickard, AR

Abstract

AtChem is an open-source zero-dimensional box model for atmospheric chemistry. Any general set of chemical reactions can be used with AtChem, but the model was designed specifically for use with the Master Chemical Mechanism (MCM, http://mcm.york.ac.uk/, last access: 16 January 2020). AtChem was initially developed within the EUROCHAMP project as a web application (AtChem-online, https://atchem.leeds.ac.uk/webapp/, last access: 16 January 2020) for modelling environmental chamber experiments; it was recently upgraded and further developed into a stand-alone offline version (AtChem2), which allows the user to run complex and long simulations, such as those needed for modelling of intensive field campaigns, as well as to perform batch model runs for sensitivity studies. AtChem is installed, set up and configured using semi-automated scripts and simple text configuration files, making it easy to use even for inexperienced users. A key feature of AtChem is that it can easily be constrained to observational data which may have different timescales, thus retaining all the information contained in the observations. Implementation of a continuous integration workflow, coupled with a comprehensive suite of tests and version control software, makes the AtChem code base robust, reliable and traceable. The AtChem2 code and documentation are available at https://github.com/AtChem/ (last access: 16 January 2020) under the open-source MIT License.

Published

2020

4. Validity and limitations of simple reaction kinetics to calculate concentrations of organic compounds from ion counts in PTR-MS

Author

Holzinger, R., Acton, W.Joe F., Bloss, J.W., Breitenlechner, M., Crilley, R.L., Dusanter, S., Gonin, M., Gros, V., Keutsch, N.F., Kiendler-Scharr, A., Kramer, J.L., Krechmer, E.J., Languille, B., Locoge, N., Lopez-Hilfiker, F., Materi, D., Moreno, S., Nemitz, E., Quéléver, J.L., Sarda Esteve, R., [Unknown], Sauvage, Schallhart, S., Sommariva, R., Tillmann, R., Wedel, S., Worton, R.D., Xu, K., Zaytsev, A., Holzinger, R., Acton, W.Joe F., Bloss, J.W., Breitenlechner, M., Crilley, R.L., Dusanter, S., Gonin, M., Gros, V., Keutsch, N.F., Kiendler-Scharr, A., Kramer, J.L., Krechmer, E.J., Languille, B., Locoge, N., Lopez-Hilfiker, F., Materi, D., Moreno, S., Nemitz, E., Quéléver, J.L., Sarda Esteve, R., [Unknown], Sauvage, Schallhart, S., Sommariva, R., Tillmann, R., Wedel, S., Worton, R.D., Xu, K., and Zaytsev, A.

Abstract

In September 2017, we conducted a proton-transfer-reaction mass-spectrometry (PTR-MS) intercomparison campaign at the CESAR observatory, a rural site in the central Netherlands near the village of Cabauw. Nine research groups deployed a total of 11 instruments covering a wide range of instrument types and performance. We applied a new calibration method based on fast injection of a gas standard through a sample loop. This approach allows calibrations on timescales of seconds, and within a few minutes an automated sequence can be run allowing one to retrieve diagnostic parameters that indicate the performance status. We developed a method to retrieve the mass-dependent transmission from the fast calibrations, which is an essential characteristic of PTR-MS instruments, limiting the potential to calculate concentrations based on counting statistics and simple reaction kinetics in the reactor/drift tube. Our measurements show that PTR-MS instruments follow the simple reaction kinetics if operated in the standard range for pressures and temperature of the reaction chamber (i.e. 1–4 mbar, 30–120∘, respectively), as well as a reduced field strength E∕N in the range of 100–160 Td. If artefacts can be ruled out, it becomes possible to quantify the signals of uncalibrated organics with accuracies better than ±30 %. The simple reaction kinetics approach produces less accurate results at E∕N levels below 100 Td, because significant fractions of primary ions form water hydronium clusters. Deprotonation through reactive collisions of protonated organics with water molecules needs to be considered when the collision energy is a substantial fraction of the exoergicity of the proton transfer reaction and/or if protonated organics undergo many collisions with water molecules.

Published

2019

5. Nocturnal isoprene oxidation over the Northeast United States in summer and its impact on reactive nitrogen partitioning and secondary organic aerosol

Author

Brown, S. S., Degouw, J. A., Warneke, C., Ryerson, T. B., Dube, W. P., Atlas, E., Weber, R. J., Peltier, R. E., Neuman, J. A., Roberts, J. M., Swanson, A., Flocke, F., Mckeen, S. A., Brioude, J., Sommariva, R., Michael Trainer, Fehsenfeld, F. C., and Ravishankara, A. R.

Subjects

lcsh:Chemistry, lcsh:QD1-999, lcsh:Physics, lcsh:QC1-999

Abstract

Isoprene is the largest single VOC emission to the atmosphere. Although it is primarily oxidized photochemically during daylight hours, late-day emissions that remain in the atmosphere at sunset undergo oxidation by NO3 in regionally polluted areas with large NOx levels. A recent aircraft study examined isoprene and its nocturnal oxidants in a series of night flights across the Northeast US, a region with large emissions of both isoprene and NOx. Substantial amounts of isoprene that were observed after dark were strongly anticorrelated with measured NO3 and were the most important factor determining the lifetime of this radical. The products of photochemical oxidation of isoprene, methyl vinyl ketone and methacrolein, were more uniformly distributed, and served as tracers for the presence of isoprene at sunset, prior to its oxidation by NO3. Comparison of a determination of the mass of isoprene oxidized in darkness by NO3 to a calculation of integrated isoprene emissions showed that large amounts (>20%) of emitted isoprene may undergo nocturnal oxidation in this region. Organic nitrates produced from the NO3+isoprene reaction, though not directly measured, were estimated to account for 2–9% of total reactive nitrogen and 7–31% of other long-lived organic nitrates such as PAN. The mass of isoprene oxidized by NO3 was comparable to and correlated with the organic aerosol loading for flights with relatively low organic aerosol background. The contribution of nocturnal isoprene oxidation to secondary organic aerosol was determined in the range 1–17%, and isoprene SOA mass derived from NO3 was calculated to exceed that due to OH by approximately 50%.

Published

2009

6. Effects of halogens on European air-quality

Author

Sherwen, T., primary, Evans, M. J., additional, Sommariva, R., additional, Hollis, L. D. J., additional, Ball, S. M., additional, Monks, P. S., additional, Reed, C., additional, Carpenter, L. J., additional, Lee, J. D., additional, Forster, G., additional, Bandy, B., additional, Reeves, C. E., additional, and Bloss, W. J., additional

Published

2017

7. Tropospheric ozone and its precursors from the urban to the global scale from air quality to short-lived climate forcer

Author

Monks, P. S., Archibald, A. T., Colette, Augustin, Cooper, O., Coyle, M., Derwent, R., Fowler, D., Granier, Claire, Law, Kathy S., Mills, G. E., Stevenson, D. S., Tarasova, O., Thouret, V., Schneidemesser, E. von, Sommariva, R., Wild, O., Williams, M. L., Department of Chemistry [Leicester], University of Leicester, NCAS-Climate [Cambridge], Department of Chemistry [Cambridge, UK], University of Cambridge [UK] (CAM)-University of Cambridge [UK] (CAM), Institut National de l'Environnement Industriel et des Risques (INERIS), Cooperative Institute for Research in Environmental Sciences (CIRES), University of Colorado [Boulder]-National Oceanic and Atmospheric Administration (NOAA), NERC Centre of Ecology and Hydrology (CEH), Natural Environment Research Council (NERC), Rdscientific [Newbury], NOAA Earth System Research Laboratory (ESRL), National Oceanic and Atmospheric Administration (NOAA), TROPO - LATMOS, Laboratoire Atmosphères, Milieux, Observations Spatiales (LATMOS), Université de Versailles Saint-Quentin-en-Yvelines (UVSQ)-Université Pierre et Marie Curie - Paris 6 (UPMC)-Institut national des sciences de l'Univers (INSU - CNRS)-Centre National de la Recherche Scientifique (CNRS)-Université de Versailles Saint-Quentin-en-Yvelines (UVSQ)-Université Pierre et Marie Curie - Paris 6 (UPMC)-Institut national des sciences de l'Univers (INSU - CNRS)-Centre National de la Recherche Scientifique (CNRS), Centre for Ecology and Hydrology [Bangor] (CEH), School of Geosciences [Edinburgh], University of Edinburgh, World Meteorological Organization (WMO), Laboratoire d'aérologie (LAERO), Université Toulouse III - Paul Sabatier (UT3), Université de Toulouse (UT)-Université de Toulouse (UT)-Observatoire Midi-Pyrénées (OMP), Institut de Recherche pour le Développement (IRD)-Université Toulouse III - Paul Sabatier (UT3), Université de Toulouse (UT)-Université de Toulouse (UT)-Institut national des sciences de l'Univers (INSU - CNRS)-Centre National d'Études Spatiales [Toulouse] (CNES)-Centre National de la Recherche Scientifique (CNRS)-Météo-France -Institut de Recherche pour le Développement (IRD)-Institut national des sciences de l'Univers (INSU - CNRS)-Centre National d'Études Spatiales [Toulouse] (CNES)-Centre National de la Recherche Scientifique (CNRS)-Météo-France -Centre National de la Recherche Scientifique (CNRS), Institute for Advanced Sustainability Studies [Potsdam] (IASS), Lancaster Environment Centre, Lancaster University, MRC-PHE Centre for Environment and Health, King‘s College London, Centre National de la Recherche Scientifique (CNRS)-Observatoire Midi-Pyrénées (OMP), Météo France-Centre National d'Études Spatiales [Toulouse] (CNES)-Université Fédérale Toulouse Midi-Pyrénées-Centre National de la Recherche Scientifique (CNRS)-Institut de Recherche pour le Développement (IRD)-Météo France-Centre National d'Études Spatiales [Toulouse] (CNES)-Université Fédérale Toulouse Midi-Pyrénées-Centre National de la Recherche Scientifique (CNRS)-Institut de Recherche pour le Développement (IRD)-Université Toulouse III - Paul Sabatier (UT3), and Université Fédérale Toulouse Midi-Pyrénées

Subjects

[PHYS.PHYS.PHYS-AO-PH]Physics [physics]/Physics [physics]/Atmospheric and Oceanic Physics [physics.ao-ph], lcsh:Chemistry, lcsh:QD1-999, Science Policy, [SDE]Environmental Sciences, lcsh:Physics, lcsh:QC1-999, Atmospheric Sciences

Abstract

Ozone holds a certain fascination in atmospheric science. It is ubiquitous in the atmosphere, central to tropospheric oxidation chemistry, yet harmful to human and ecosystem health as well as being an important greenhouse gas. It is not emitted into the atmosphere but is a byproduct of the very oxidation chemistry it largely initiates. Much effort is focused on the reduction of surface levels of ozone owing to its health and vegetation impacts, but recent efforts to achieve reductions in exposure at a country scale have proved difficult to achieve owing to increases in background ozone at the zonal hemispheric scale. There is also a growing realisation that the role of ozone as a short-lived climate pollutant could be important in integrated air quality climate change mitigation. This review examines current understanding of the processes regulating tropospheric ozone at global to local scales from both measurements and models. It takes the view that knowledge across the scales is important for dealing with air quality and climate change in a synergistic manner. The review shows that there remain a number of clear challenges for ozone such as explaining surface trends, incorporating new chemical understanding, ozone-climate coupling, and a better assessment of impacts. There is a clear and present need to treat ozone across the range of scales, a transboundary issue, but with an emphasis on the hemispheric scales. New observational opportunities are offered both by satellites and small sensors that bridge the scales.

Published

2015

8. Growth in stratospheric chlorine from short-lived chemicals not controlled by the Montreal Protocol

Author

Hossaini, R., Chipperfield, M. P., Saiz-Lopez, A., Harrison, J. J., von Glasow, R., Sommariva, R., Atlas, E., Navarro, M., Montzka, S. A., Feng, W., Dhomse, S., Harth, C., Mühle, J., Lunder, C., O'Doherty, S., Young, D., Reimann, S., Vollmer, M. K., Krummel, P. B., Bernath, P. F., Hossaini, R., Chipperfield, M. P., Saiz-Lopez, A., Harrison, J. J., von Glasow, R., Sommariva, R., Atlas, E., Navarro, M., Montzka, S. A., Feng, W., Dhomse, S., Harth, C., Mühle, J., Lunder, C., O'Doherty, S., Young, D., Reimann, S., Vollmer, M. K., Krummel, P. B., and Bernath, P. F.

Abstract

We have developed a chemical mechanism describing the tropospheric degradation of chlorine containing very short-lived substances (VSLS). The scheme was included in a global atmospheric model and used to quantify the stratospheric injection of chlorine from anthropogenic VSLS ( inline image) between 2005 and 2013. By constraining the model with surface measurements of chloroform (CHCl3), dichloromethane (CH2Cl2), tetrachloroethene (C2Cl4), trichloroethene (C2HCl3), and 1,2-dichloroethane (CH2ClCH2Cl), we infer a 2013 inline image mixing ratio of 123 parts per trillion (ppt). Stratospheric injection of source gases dominates this supply, accounting for ∼83% of the total. The remainder comes from VSLS-derived organic products, phosgene (COCl2, 7%) and formyl chloride (CHClO, 2%), and also hydrogen chloride (HCl, 8%). Stratospheric inline image increased by ∼52% between 2005 and 2013, with a mean growth rate of 3.7 ppt Cl/yr. This increase is due to recent and ongoing growth in anthropogenic CH2Cl2—the most abundant chlorinated VSLS not controlled by the Montreal Protocol.

Published

2015

9. Tropospheric ozone and its precursors from the urban to the global scale from air quality to short-lived climate forcer

Author

Monks, P.S., Archibald, A.T., Colette, A., Cooper, O., Coyle, M., Derwent, R., Fowler, D., Granier, C., Law, K.S., Mills, G.E., Stevenson, D.S., Tarasova, O., Thouret, V., von Schneidermesser, E., Sommariva, R., Wild, O., Williams, M.L., Monks, P.S., Archibald, A.T., Colette, A., Cooper, O., Coyle, M., Derwent, R., Fowler, D., Granier, C., Law, K.S., Mills, G.E., Stevenson, D.S., Tarasova, O., Thouret, V., von Schneidermesser, E., Sommariva, R., Wild, O., and Williams, M.L.

Abstract

Ozone holds a certain fascination in atmospheric science. It is ubiquitous in the atmosphere, central to tropospheric oxidation chemistry, yet harmful to human and ecosystem health as well as being an important greenhouse gas. It is not emitted into the atmosphere but is a byproduct of the very oxidation chemistry it largely initiates. Much effort is focused on the reduction of surface levels of ozone owing to its health and vegetation impacts, but recent efforts to achieve reductions in exposure at a country scale have proved difficult to achieve owing to increases in background ozone at the zonal hemispheric scale. There is also a growing realisation that the role of ozone as a short-lived climate pollutant could be important in integrated air quality climate change mitigation. This review examines current understanding of the processes regulating tropospheric ozone at global to local scales from both measurements and models. It takes the view that knowledge across the scales is important for dealing with air quality and climate change in a synergistic manner. The review shows that there remain a number of clear challenges for ozone such as explaining surface trends, incorporating new chemical understanding, ozone–climate coupling, and a better assessment of impacts. There is a clear and present need to treat ozone across the range of scales, a transboundary issue, but with an emphasis on the hemispheric scales. New observational opportunities are offered both by satellites and small sensors that bridge the scales.

Published

2015

10. Growth in stratospheric chlorine from short‐lived chemicals not controlled by the Montreal Protocol

Author

Hossaini, R., primary, Chipperfield, M. P., additional, Saiz‐Lopez, A., additional, Harrison, J. J., additional, Glasow, R., additional, Sommariva, R., additional, Atlas, E., additional, Navarro, M., additional, Montzka, S. A., additional, Feng, W., additional, Dhomse, S., additional, Harth, C., additional, Mühle, J., additional, Lunder, C., additional, O'Doherty, S., additional, Young, D., additional, Reimann, S., additional, Vollmer, M. K., additional, Krummel, P. B., additional, and Bernath, P. F., additional

Published

2015

11. Tropospheric ozone and its precursors from the urban to the global scale from air quality to short-lived climate forcer

Author

Monks, P. S., primary, Archibald, A. T., additional, Colette, A., additional, Cooper, O., additional, Coyle, M., additional, Derwent, R., additional, Fowler, D., additional, Granier, C., additional, Law, K. S., additional, Stevenson, D. S., additional, Tarasova, O., additional, Thouret, V., additional, von Schneidemesser, E., additional, Sommariva, R., additional, Wild, O., additional, and Williams, M. L., additional

Published

2014

12. The North Atlantic Marine Boundary Layer Experiment (NAMBLEX). Overview of the campaign held at Mace Head, Ireland, in summer 2002

Author

Heard, D.E., Read, K.A., Methven, J., Al-Haider, S., Bloss, W.J., Johnson, G.P., Pilling, M.J., Seakins, P.W., Smith, S.C., Sommariva, R., Stanton, J.C., Still, T.J., Ingham, T., Brooks, B., Leeuw, G. de, Jackson, A.V., McQuaid, J.B., Morgan, R., Smith, M.H., Carpenter, L.J., Carslaw, N., Hamilton, J., Hopkins, J.R., Lee, J.D., Lewis, A.C., Purvis, R.M., Wevill, D.J., Brough, N., Green, T., Mills, G., Penkett, S.A., Plane, J.M.C., Saiz-Lopez, A., Worten, D., Monks, P.S., Fleming, Z., Rickard, A.R., Alfarra, M.R., Allan, J.D., Bower, K., Coe, H., Cubison, M., Flynn, M., McFiggans, G., Gallagher, M., Norton, E.G., O'Dowd, C.D., Shillito, J., Topping, D., Vaughan, G., Williams, P., Bitter, M., Ball, S.M., Jones, R.L., Povey, I.M., O'Doherty, S., Simmonds, P.G., Allen, A., Kinnersley, R.P., Beddows, D.C.S., Dall'Osto, M., Harrison, R.M., Donovan, R.J., Heal, M.R., Jennings, S.G., Noone, C., and Spain, G.

Subjects

atmospheric chemistry, Mace Head, aerosol, County Galway, Connacht, Western Europe, climatology, boundary layer, Europe, marine ecosystem, atmospheric gas, Eurasia, Atlantic Ocean (North), Atlantic Ocean, Ireland, in situ measurement

Abstract

The North Atlantic Marine Boundary Layer Experiment (NAMBLEX), involving over 50 scientists from 12 institutions, took place at Mace Head, Ireland (53.32° N, 9.90° W), between 23 July and 4 September 2002. A wide range of state-of-the-art instrumentation enabled detailed measurements of the boundary layer structure and atmospheric composition in the gas and aerosol phase to be made, providing one of the most comprehensive in situ studies of the marine boundary layer to date. This overview paper describes the aims of the NAMBLEX project in the context of previous field campaigns in the Marine Boundary Layer (MBL), the overall layout of the site, a summary of the instrumentation deployed, the temporal coverage of the measurement data, and the numerical models used to interpret the field data. Measurements of some trace species were made for the first time during the campaign, which was characterised by predominantly clean air of marine origin, but more polluted air with higher levels of NOx originating from continental regions was also experienced. This paper provides a summary of the meteorological measurements and Planetary Boundary Layer (PBL) structure measurements, presents time series of some of the longer-lived trace species (O3, CO, H2, DMS, CH4, NMHC, NOx, NOy, PAN) and summarises measurements of other species that are described in more detail in other papers within this special issue, namely oxygenated VOCs, HCHO, peroxides, organohalogenated species, a range of shorter lived halogen species (I2, OIO, IO, BrO), NO3 radicals, photolysis frequencies, the free radicals OH, HO2 and (HO2+ΣRO2), as well as a summary of the aerosol measurements. NAMBLEX was supported by measurements made in the vicinity of Mace Head using the NERC Dornier-228 aircraft. Using ECMWF wind-fields, calculations were made of the air-mass trajectories arriving at Mace Head during NAMBLEX, and were analysed together with both meteorological and trace-gas measurements. In this paper a chemical climatology for the duration of the campaign is presented to interpret the distribution of air-mass origins and emission sources, and to provide a convenient framework of air-mass classification that is used by other papers in this issue for the interpretation of observed variability in levels of trace gases and aerosols.

Published

2006

13. The North Atlantic Marine Boundary Layer Experiment (NAMBLEX). Overview of the campaign held at Mace Head, Ireland, in summer 2002

Author

Heard, D. E., Read, K. A., Methven, J., Al-Haider, S., Bloss, W. J., Johnson, G. P., Pilling, M. J., Seakins, P. W., Smith, S. C., Sommariva, R., Stanton, J. C., Still, T. J., Brooks, B., De Leeuw, G., Jackson, A. V., Mcquaid, J. B., Morgan, R., Smith, M. H., Carpenter, L. J., Carslaw, N., Hamilton, J., Hopkins, J. R., Lee, J. D., Lewis, A. C., Purvis, R. M., Wevill, D. J., Brough, N., Green, T., Mills, G., Penkett, S. A., Plane, J. M. C., Saiz-Lopez, A., Worton, D., Monks, P. S., Fleming, Z., Rickard, A. R., Alfarra, M., Allan, J. D., Bower, K., Coe, H., Cubison, M., Flynn, M., Mcfiggans, G., Gallagher, M., Norton, E. G., O'Dowd, C. D., Shillito, J., Topping, D., Vaughan, G., Williams, P., Bitter, M., Ball, S. M., Jones, R. L., Povey, I. M., O'Doherty, S., Simmonds, P. G., Allen, A., Kinnersley, R. P., Beddows, D. C. S., Dall'Osto, M., Harrison, R. M., Donovan, R. J., Heal, M. R., Jennings, S. G., Noone, C., Spain, G., EGU, Publication, School of Chemistry [Leeds], University of Leeds, Department of Meteorology [Reading], University of Reading (UOR), Institute for Climate and Atmospheric Science [Leeds] (ICAS), School of Earth and Environment [Leeds] (SEE), University of Leeds-University of Leeds, The Netherlands Organisation for Applied Scientific Research (TNO), Department of Chemistry [York, UK], University of York [York, UK], Facility for Airborne Atmospheric Measurements ([Cranfield] (FAAM), National Centre for Atmospheric Science [Leeds] (NCAS), Natural Environment Research Council (NERC)-Natural Environment Research Council (NERC), School of Environmental Sciences [Norwich], University of East Anglia [Norwich] (UEA), Department of Chemistry [Leicester], University of Leicester, School of Earth, Atmospheric and Environmental Sciences [Manchester] (SEAES), University of Manchester [Manchester], National University of Ireland [Galway] (NUI Galway), University Chemical Laboratory, School of Chemistry, University of Bristol [Bristol], School of Geography, Earth and Environmental Sciences [Birmingham], University of Birmingham [Birmingham], and University of Edinburgh

Subjects

[SDU.OCEAN]Sciences of the Universe [physics]/Ocean, Atmosphere, 13. Climate action, [SDU.OCEAN] Sciences of the Universe [physics]/Ocean, Atmosphere, 14. Life underwater

Abstract

International audience; The North Atlantic Marine Boundary Layer Experiment (NAMBLEX), involving over 50 scientists from 12 institutions, took place at Mace Head, Ireland (53.32° N, 9.90° W), between 23 July and 4 September 2002. A wide range of state-of-the-art instrumentation enabled detailed measurements of the boundary layer structure and atmospheric composition in the gas and aerosol phase to be made, providing one of the most comprehensive in situ studies of the marine boundary layer to date. This overview paper describes the aims of the NAMBLEX project in the context of previous field campaigns in the Marine Boundary Layer (MBL), the overall layout of the site, a summary of the instrumentation deployed, the temporal coverage of the measurement data, and the numerical models used to interpret the field data. Measurements of some trace species were made for the first time during the campaign, which was characterised by predominantly clean air of marine origin, but more polluted air with higher levels of NOx originating from continental regions was also experienced. This paper provides a summary of the meteorological measurements and Planetary Boundary Layer (PBL) structure measurements, presents time series of some of the longer-lived trace species (O3, CO, H2, DMS, CH4, NMHC, NOx, NOy, PAN) and summarises measurements of other species that are described in more detail in other papers within this special issue, namely oxygenated VOCs, HCHO, peroxides, organo-halogenated species, a range of shorter lived halogen species (I2, OIO, IO, BrO), NO3 radicals, photolysis frequencies, the free radicals OH, HO2 and (HO2+?RO2), as well as a summary of the aerosol measurements. NAMBLEX was supported by measurements made in the vicinity of Mace Head using the NERC Dornier-228 aircraft. Using ECMWF wind-fields, calculations were made of the air-mass trajectories arriving at Mace Head during NAMBLEX, and were analysed together with both meteorological and trace-gas measurements. In this paper a chemical climatology is presented to interpret the distribution of air-mass origins and emission sources, and to provide a convenient framework of air-mass classification that is used by other papers in this issue for the interpretation of observed variability in levels of trace gases and aerosols.

Published

2005

14. OH and HO2 chemistry during NAMBLEX: roles of oxygenates, halogen oxides and heterogeneous uptake

Author

Sommariva, R., Bloss, W. J., Brough, N., Carslaw, N., Flynn, M., Haggerstone, A.-L., Heard, D. E., Hopkins, J. R., Lee, J. D., Lewis, A. C., Mcfiggans, G., Monks, P. S., Penkett, S. A., Pilling, M. J., Plane, J. M. C., Read, K. A., Saiz-Lopez, A., Rickard, A. R., Williams, P. I., EGU, Publication, School of Chemistry, School of Environmental Sciences [Norwich], University of East Anglia [Norwich] (UEA), Environment Department, School of Earth, Atmospheric and Environmental Sciences [Manchester] (SEAES), University of Manchester [Manchester], and Department of Chemistry

Subjects

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

Abstract

International audience; Several zero-dimensional box-models with different levels of chemical complexity, based on the Master Chemical Mechanism (MCM), have been used to study the chemistry of OH and HO2 in a coastal environment in the Northern Hemisphere. The models were constrained to and compared with measurements made during the NAMBLEX campaign (Mace Head, Ireland) in summer 2002. The base models, which were constrained to measured CO, CH4 and NMHCs, were able to reproduce [OH] within 25%, but overestimated [HO2] by about a factor of 2. Agreement was improved when the models were constrained to oxygenated compounds (acetaldehyde, methanol and acetone), highlighting their importance for the radical budget. When the models were constrained to measured halogen monoxides (IO, BrO) and used a more detailed, measurements-based, treatment to describe the heterogeneous uptake, modelled [OH] increased by up to 15% and [HO2] decreased by up to 30%. The actual impact of halogen monoxides on the modelled concentrations of HOx was dependant on the uptake coefficients used for HOI, HOBr and HO2. Better agreement, within the combined uncertainties of the measurements and of the model, was achieved when using high uptake coefficients for HO2 and HOI (?HO2=1, ?HOI=0.6). A rate of production and destruction analysis of the models allowed a detailed study of OH and HO2 chemistry under the conditions encountered during NAMBLEX, showing the importance of oxygenates and of XO (where X=I, Br) as co-reactants for OH and HO2 and of HOX photolysis as a source for OH.

Published

2005

15. OH and HO2 chemistry in clean marine air during SOAPEX-2

Author

Sommariva, R., Haggerstone, A.-L., Carpenter, L. J., Carslaw, N., Creasey, D. J., Heard, D. E., Lee, J. D., Lewis, A. C., Pilling, M. J., Zádor, J., Department of Chemistry, Environment Department, Department of Physical Chemistry, and EGU, Publication

Subjects

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

Abstract

Model-measurement comparisons of HOx in extremely clean air ([NO] The free-radical chemistry was studied using a zero-dimensional box-model based upon the Master Chemical Mechanism (MCM). Two versions of the model were used, with different levels of chemical complexity, to explore the role of hydrocarbons upon free-radical budgets under very clean conditions. The "detailed" model was constrained to measurements of CO, CH4 and 15 NMHCs, while the "simple" model contained only the CO and CH4 oxidation mechanisms, together with inorganic chemistry. The OH and HO2 (HOx) concentrations predicted by the two models agreed to within 5?10%. The model results were compared with the HOx concentrations measured by the FAGE (Fluorescence Assay by Gas Expansion) technique during four days of clean Southern Ocean marine boundary layer (MBL) air. The models overestimated OH concentrations by about 10% on two days and about 20% on the other two days. HO2 concentrations were measured during two of these days and the models overestimated the measured concentrations by about 40%. Better agreement with measured HO2 was observed by using data from several MBL aerosol measurements to estimate the aerosol surface area and by increasing the HO2 uptake coefficient to unity. This reduced the modelled HO2 overestimate by ~40%, with little effect on OH, because of the poor HO2 to OH conversion at the low ambient NOx concentrations. Local sensitivity analysis and Morris One-At-A-Time analysis were performed on the "simple" model, and showed the importance of reliable measurements of j(O1D) and [HCHO] and of the kinetic parameters that determine the efficiency of O(1D) to OH and HCHO to HO2 conversion. A 2? standard deviation of 30?40% for OH and 25?30% for HO2 was estimated for the model calculations using a Monte Carlo technique coupled with Latin Hypercube Sampling (LHS). A rate of production analysis, which demonstrates the relevance of HCHO as a radical source, coupled with the poor performance of the models with respect to the concentrations of formaldehyde and peroxides, suggest that there are significant uncertainties in the chemical mechanism.

Published

2004

16. Iodine monoxide in the Western Pacific marine boundary layer

Author

Großmann, K., Frieß, U., Peters, E., Wittrock, F., Lampel, J., Yilmaz, S., Tschritter, J., Sommariva, R., von Glasow, R., Quack, Birgit, Krüger, Kirstin, Pfeilsticker, K., Platt, U., Großmann, K., Frieß, U., Peters, E., Wittrock, F., Lampel, J., Yilmaz, S., Tschritter, J., Sommariva, R., von Glasow, R., Quack, Birgit, Krüger, Kirstin, Pfeilsticker, K., and Platt, U.

Abstract

A latitudinal cross-section and vertical profiles of iodine monoxide (IO) are reported from the marine boundary layer of the Western Pacific. The measurements were taken using Multi-Axis Differential Optical Absorption Spectroscopy (MAX-DOAS) during the TransBrom cruise of the German research vessel Sonne, which led from Tomakomai, Japan (42° N, 141° E) through the Western Pacific to Townsville, Australia (19° S, 146° E) in October 2009. In the marine boundary layer within the tropics (between 20° N and 5° S), IO mixing ratios ranged between 1 and 2.2 ppt, whereas in the subtropics and at mid-latitudes typical IO mixing ratios were around 1 ppt in the daytime. The profile retrieval reveals that the bulk of the IO was located in the lower part of the marine boundary layer. Photochemical simulations indicate that the organic iodine precursors observed during the cruise (CH3I, CH2I2, CH2ClI, CH2BrI) are not sufficient to explain the measured IO mixing ratios. Reasonable agreement between measured and modelled IO can only be achieved, if an additional sea-air flux of inorganic iodine (e.g. I2) is assumed in the model. Our observations add further evidence to previous studies that reactive iodine is an important oxidant in the marine boundary layer.

Published

2013

17. Jodmonoxid in der marinen Grenzschicht des Westpazifiks

Author

Großmann, K., Frieß, U., Peters, E., Wittrock, F., Lampel, J., Yilmaz, S., Tschritter, J., Sommariva, R., von Glasow, R., Quack, Birgit, Krüger, Kirstin, Pfeilsticker, K., Platt, U., Großmann, K., Frieß, U., Peters, E., Wittrock, F., Lampel, J., Yilmaz, S., Tschritter, J., Sommariva, R., von Glasow, R., Quack, Birgit, Krüger, Kirstin, Pfeilsticker, K., and Platt, U.

Published

2013

18. Iodine monoxide in the Western Pacific marine boundary layer

Author

Großmann, K., primary, Frieß, U., additional, Peters, E., additional, Wittrock, F., additional, Lampel, J., additional, Yilmaz, S., additional, Tschritter, J., additional, Sommariva, R., additional, von Glasow, R., additional, Quack, B., additional, Krüger, K., additional, Pfeilsticker, K., additional, and Platt, U., additional

Published

2013

19. Iodine monoxide in the Western Pacific marine boundary layer

Author

Großmann, K., primary, Frieß, U., additional, Peters, E., additional, Wittrock, F., additional, Lampel, J., additional, Yilmaz, S., additional, Tschritter, J., additional, Sommariva, R., additional, von Glasow, R., additional, Quack, B., additional, Krüger, K., additional, Pfeilsticker, K., additional, and Platt, U., additional

Published

2012

20. Uncertainties in gas-phase atmospheric iodine chemistry

Author

Sommariva, R., primary, Bloss, W.J., additional, and von Glasow, R., additional

Published

2012

21. Emissions and photochemistry of oxygenated VOCs in urban plumes in the Northeastern United States

Author

Sommariva, R., primary, de Gouw, J. A., additional, Trainer, M., additional, Atlas, E., additional, Goldan, P. D., additional, Kuster, W. C., additional, Warneke, C., additional, and Fehsenfeld, F. C., additional

Published

2011

22. Ozone production in remote oceanic and industrial areas derived from ship based measurements of peroxy radicals during TexAQS 2006

Author

Sommariva, R., primary, Brown, S. S., additional, Roberts, J. M., additional, Brookes, D. M., additional, Parker, A. E., additional, Monks, P. S., additional, Bates, T. S., additional, Bon, D., additional, de Gouw, J. A., additional, Frost, G. J., additional, Gilman, J. B., additional, Goldan, P. D., additional, Herndon, S. C., additional, Kuster, W. C., additional, Lerner, B. M., additional, Osthoff, H. D., additional, Tucker, S. C., additional, Warneke, C., additional, Williams, E. J., additional, and Zahniser, M. S., additional

Published

2011

23. HOCl and Cl2 observations in marine air

Author

Lawler, M. J., primary, Sander, R., additional, Carpenter, L. J., additional, Lee, J. D., additional, von Glasow, R., additional, Sommariva, R., additional, and Saltzman, E. S., additional

Published

2011

24. Ozone production in remote oceanic and industrial areas derived from ship based measurements of peroxy radicals during TexAQS 2006

Author

Sommariva, R., primary, Brown, S. S., additional, Roberts, J. M., additional, Brookes, D. M., additional, Parker, A. E., additional, Monks, P. S., additional, Bates, T. S., additional, Bon, D., additional, de Gouw, J. A., additional, Frost, G. J., additional, Gilman, J. B., additional, Goldan, P. D., additional, Herndon, S. C., additional, Kuster, W. C., additional, Lerner, B. M., additional, Osthoff, H. D., additional, Tucker, S. C., additional, Warneke, C., additional, Williams, E. J., additional, and Zahniser, M. S., additional

Published

2010

25. Radicals in the marine boundary layer during NEAQS 2004: a model study of day-time and night-time sources and sinks

Author

Sommariva, R., primary, Osthoff, H. D., additional, Brown, S. S., additional, Bates, T. S., additional, Baynard, T., additional, Coffman, D., additional, de Gouw, J. A., additional, Goldan, P. D., additional, Kuster, W. C., additional, Lerner, B. M., additional, Stark, H., additional, Warneke, C., additional, Williams, E. J., additional, Fehsenfeld, F. C., additional, Ravishankara, A. R., additional, and Trainer, M., additional

Published

2009

26. Nocturnal isoprene oxidation over the Northeast United States in summer and its impact on reactive nitrogen partitioning and secondary organic aerosol

Author

Brown, S. S., primary, deGouw, J. A., additional, Warneke, C., additional, Ryerson, T. B., additional, Dubé, W. P., additional, Atlas, E., additional, Weber, R. J., additional, Peltier, R. E., additional, Neuman, J. A., additional, Roberts, J. M., additional, Swanson, A., additional, Flocke, F., additional, McKeen, S. A., additional, Brioude, J., additional, Sommariva, R., additional, Trainer, M., additional, Fehsenfeld, F. C., additional, and Ravishankara, A. R., additional

Published

2009

27. Radicals in the marine boundary layer during NEAQS 2004: a model study of day-time and night-time sources and sinks

Author

Sommariva, R., primary, Osthoff, H. D., additional, Brown, S. S., additional, Bates, T. S., additional, Baynard, T., additional, Coffman, D., additional, de Gouw, J. A., additional, Goldan, P. D., additional, Kuster, W. C., additional, Lerner, B. M., additional, Stark, H., additional, Warneke, C., additional, Williams, E. J., additional, Fehsenfeld, F. C., additional, Ravishankara, A. R., additional, and Trainer, M., additional

Published

2008

28. Emissions and photochemistry of oxygenated VOCs in urban plumes in the Northeastern United States

Author

Sommariva, R., primary, de Gouw, J. A., additional, Trainer, M., additional, Atlas, E., additional, Goldan, P. D., additional, Kuster, W. C., additional, Warneke, C., additional, and Fehsenfeld, F. C., additional

Published

2008

29. Measurements of PANs during the New England Air Quality Study 2002

Author

Roberts, J. M., primary, Marchewka, M., additional, Bertman, S. B., additional, Sommariva, R., additional, Warneke, C., additional, de Gouw, J., additional, Kuster, W., additional, Goldan, P., additional, Williams, E., additional, Lerner, B. M., additional, Murphy, P., additional, and Fehsenfeld, F. C., additional

Published

2007

30. Night-time radical chemistry during the NAMBLEX campaign

Author

Sommariva, R., primary, Pilling, M. J., additional, Bloss, W. J., additional, Heard, D. E., additional, Lee, J. D., additional, Fleming, Z. L., additional, Monks, P. S., additional, Plane, J. M. C., additional, Saiz-Lopez, A., additional, Ball, S. M., additional, Bitter, M., additional, Jones, R. L., additional, Brough, N., additional, Penkett, S. A., additional, Hopkins, J. R., additional, Lewis, A. C., additional, and Read, K. A., additional

Published

2007

31. Tropospheric ozone and its precursors from the urban to the global scale from air quality to short-lived climate forcer.

Author

Monks, P. S., Archibald, A. T., Colette, A., Cooper, O., Coyle, M., Derwent, R., Fowler, D., Granier, C., Law, K. S., Stevenson, D. S., Tarasova, O., Thouret, V., von Schneidemesser, E., Sommariva, R., Wild, O., and Williams, M. L.

Abstract

Ozone holds a certain fascination in atmospheric science. It is ubiquitous in the atmosphere, central to tropospheric oxidation chemistry, yet harmful to human and ecosystem health as well as being an important greenhouse gas. It is not emitted into the atmosphere but is a by-product of the very oxidation chemistry it largely initiates. Much effort is focussed on the reduction of surface levels of ozone owing to its health impacts but recent efforts to achieve reductions in exposure at a country scale have proved difficult to achieve due to increases in background ozone at the zonal hemispheric scale. There is also a growing realisation that the role of ozone as a short-lived climate pollutant could be important in integrated air quality climate-change mitigation. This review examines current understanding of the processes regulating tropospheric ozone at global to local scales from both measurements and models. It takes the view that knowledge across the scales is important for dealing with air quality and climate change in a synergistic manner. [ABSTRACT FROM AUTHOR]

Published

2014

32. Reactive nitrogen transport and photochemistry in urban plumes over the North Atlantic Ocean

Author

Neuman, J. A., primary, Parrish, D. D., additional, Trainer, M., additional, Ryerson, T. B., additional, Holloway, J. S., additional, Nowak, J. B., additional, Swanson, A., additional, Flocke, F., additional, Roberts, J. M., additional, Brown, S. S., additional, Stark, H., additional, Sommariva, R., additional, Stohl, A., additional, Peltier, R., additional, Weber, R., additional, Wollny, A. G., additional, Sueper, D. T., additional, Hubler, G., additional, and Fehsenfeld, F. C., additional

Published

2006

33. Night-time radical chemistry during the NAMBLEX campaign

Author

Sommariva, R., primary, Pilling, M. J., additional, Bloss, W. J., additional, Heard, D. E., additional, Lee, J. D., additional, Fleming, Z. L., additional, Monks, P. S., additional, Plane, J. M. C., additional, Saiz-Lopez, A., additional, Ball, S. M., additional, Bitter, M., additional, Jones, R. L., additional, Brough, N., additional, Penkett, S. A., additional, Hopkins, J. R., additional, Lewis, A. C., additional, and Read, K. A., additional

Published

2006

34. Ambient formaldehyde measurements made at a remote marine boundary layer site during the NAMBLEX campaign – a comparison of data from chromatographic and modified Hantzsch techniques

Author

Still, T. J., primary, Al-Haider, S., additional, Seakins, P. W., additional, Sommariva, R., additional, Stanton, J. C., additional, Mills, G., additional, and Penkett, S. A., additional

Published

2006

35. The North Atlantic Marine Boundary Layer Experiment(NAMBLEX). Overview of the campaign held at Mace Head, Ireland, in summer 2002

Author

Heard, D. E., primary, Read, K. A., additional, Methven, J., additional, Al-Haider, S., additional, Bloss, W. J., additional, Johnson, G. P., additional, Pilling, M. J., additional, Seakins, P. W., additional, Smith, S. C., additional, Sommariva, R., additional, Stanton, J. C., additional, Still, T. J., additional, Ingham, T., additional, Brooks, B., additional, De Leeuw, G., additional, Jackson, A. V., additional, McQuaid, J. B., additional, Morgan, R., additional, Smith, M. H., additional, Carpenter, L. J., additional, Carslaw, N., additional, Hamilton, J., additional, Hopkins, J. R., additional, Lee, J. D., additional, Lewis, A. C., additional, Purvis, R. M., additional, Wevill, D. J., additional, Brough, N., additional, Green, T., additional, Mills, G., additional, Penkett, S. A., additional, Plane, J. M. C., additional, Saiz-Lopez, A., additional, Worton, D., additional, Monks, P. S., additional, Fleming, Z., additional, Rickard, A. R., additional, Alfarra, M. R., additional, Allan, J. D., additional, Bower, K., additional, Coe, H., additional, Cubison, M., additional, Flynn, M., additional, McFiggans, G., additional, Gallagher, M., additional, Norton, E. G., additional, O'Dowd, C. D., additional, Shillito, J., additional, Topping, D., additional, Vaughan, G., additional, Williams, P., additional, Bitter, M., additional, Ball, S. M., additional, Jones, R. L., additional, Povey, I. M., additional, O'Doherty, S., additional, Simmonds, P. G., additional, Allen, A., additional, Kinnersley, R. P., additional, Beddows, D. C. S., additional, Dall'Osto, M., additional, Harrison, R. M., additional, Donovan, R. J., additional, Heal, M. R., additional, Jennings, S. G., additional, Noone, C., additional, and Spain, G., additional

Published

2006

36. Peroxy radical chemistry and the control of ozone photochemistry at Mace Head, Ireland during the summer of 2002

Author

Fleming, Z. L., primary, Monks, P. S., additional, Rickard, A. R., additional, Heard, D. E., additional, Bloss, W. J., additional, Seakins, P. W., additional, Still, T. J., additional, Sommariva, R., additional, Pilling, M. J., additional, Morgan, R., additional, Green, T. J., additional, Brough, N., additional, Mills, G. P., additional, Penkett, S. A., additional, Lewis, A. C., additional, Lee, J. D., additional, Saiz-Lopez, A., additional, and Plane, J. M. C., additional

Published

2006

37. OH and HO<sub>2</sub> chemistry during NAMBLEX: roles of oxygenates, halogen oxides and heterogeneous uptake

Author

Sommariva, R., primary, Bloss, W. J., additional, Brough, N., additional, Carslaw, N., additional, Flynn, M., additional, Haggerstone, A.-L., additional, Heard, D. E., additional, Hopkins, J. R., additional, Lee, J. D., additional, Lewis, A. C., additional, McFiggans, G., additional, Monks, P. S., additional, Penkett, S. A., additional, Pilling, M. J., additional, Plane, J. M. C., additional, Read, K. A., additional, Saiz-Lopez, A., additional, Rickard, A. R., additional, and Williams, P. I., additional

Published

2006

38. Ambient formaldehyde measurements made at a remote marine boundary layer site during the NAMBLEX campaign – a comparison of data from chromatographic and modified Hantzsch techniques

Author

Still, T. J., primary, Al-Haider, S., additional, Seakins, P. W., additional, Sommariva, R., additional, Stanton, J. C., additional, Mills, G., additional, and Penkett, S. A., additional

Published

2005

39. Peroxy radical chemistry and the control of ozone photochemistry at Mace Head, Ireland during the summer of 2002

Author

Fleming, Z. L., primary, Monks, P. S., additional, Rickard, A. R., additional, Heard, D. E., additional, Bloss, W. J., additional, Seakins, P. W., additional, Still, T. J., additional, Sommariva, R., additional, Pilling, M. J., additional, Morgan, R., additional, Green, T. J., additional, Brough, N., additional, Mills, G. P., additional, Penkett, S. A., additional, Lewis, A. C., additional, Lee, J. D., additional, Saiz-Lopez, A., additional, and Plane, J. M. C., additional

Published

2005

40. The North Atlantic Marine Boundary Layer Experiment (NAMBLEX). Overview of the campaign held at Mace Head, Ireland, in summer 2002

Author

Heard, D. E., primary, Read, K. A., additional, Methven, J., additional, Al-Haider, S., additional, Bloss, W. J., additional, Johnson, G. P., additional, Pilling, M. J., additional, Seakins, P. W., additional, Smith, S. C., additional, Sommariva, R., additional, Stanton, J. C., additional, Still, T. J., additional, Brooks, B., additional, De Leeuw, G., additional, Jackson, A. V., additional, McQuaid, J. B., additional, Morgan, R., additional, Smith, M. H., additional, Carpenter, L. J., additional, Carslaw, N., additional, Hamilton, J., additional, Hopkins, J. R., additional, Lee, J. D., additional, Lewis, A. C., additional, Purvis, R. M., additional, Wevill, D. J., additional, Brough, N., additional, Green, T., additional, Mills, G., additional, Penkett, S. A., additional, Plane, J. M. C., additional, Saiz-Lopez, A., additional, Worton, D., additional, Monks, P. S., additional, Fleming, Z., additional, Rickard, A. R., additional, Alfarra, M., additional, Allan, J. D., additional, Bower, K., additional, Coe, H., additional, Cubison, M., additional, Flynn, M., additional, McFiggans, G., additional, Gallagher, M., additional, Norton, E. G., additional, O’Dowd, C. D., additional, Shillito, J., additional, Topping, D., additional, Vaughan, G., additional, Williams, P., additional, Bitter, M., additional, Ball, S. M., additional, Jones, R. L., additional, Povey, I. M., additional, O’Doherty, S., additional, Simmonds, P. G., additional, Allen, A., additional, Kinnersley, R. P., additional, Beddows, D. C. S., additional, Dall’Osto, M., additional, Harrison, R. M., additional, Donovan, R. J., additional, Heal, M. R., additional, Jennings, S. G., additional, Noone, C., additional, and Spain, G., additional

Published

2005

41. OH and HO2 chemistry during NAMBLEX: roles of oxygenates, halogen oxides and heterogeneous uptake

Author

Sommariva, R., primary, Bloss, W. J., additional, Brough, N., additional, Carslaw, N., additional, Flynn, M., additional, Haggerstone, A.-L., additional, Heard, D. E., additional, Hopkins, J. R., additional, Lee, J. D., additional, Lewis, A. C., additional, McFiggans, G., additional, Monks, P. S., additional, Penkett, S. A., additional, Pilling, M. J., additional, Plane, J. M. C., additional, Read, K. A., additional, Saiz-Lopez, A., additional, Rickard, A. R., additional, and Williams, P. I., additional

Published

2005

42. OH and HO2 chemistry in clean marine air during SOAPEX-2

Author

Sommariva, R., primary, Haggerstone, A.-L., additional, Carpenter, L. J., additional, Carslaw, N., additional, Creasey, D. J., additional, Heard, D. E., additional, Lee, J. D., additional, Lewis, A. C., additional, Pilling, M. J., additional, and Zádor, J., additional

Published

2004

43. Iodine monoxide in the Western Pacific marine boundary layer.

Author

Großmann, K., Frieß, U., Peters, E., Wittrock, F., Lampel, J., Yilmaz, S., Tschritter, J., Sommariva, R., von Glasow, R., Quack, B., Krüger, K., Pfeilsticker, K., and Platt, U.

Abstract

A latitudinal cross-section and vertical profiles of iodine monoxide (IO) are reported from the marine boundary layer of the Western Pacific. The measurements were taken using Multi-Axis Differential Optical Absorption Spectroscopy (MAX-DOAS) during the TransBrom cruise of the German research vessel Sonne, which led from Tomakomai, Japan (42° N, 141° E) through the Western Pacific to Townsville, Australia (19° S, 146 ° E) in October 2009. In the marine boundary layer within the tropics (between 20° N and 5° S), IO mixing ratios ranged between 1 and 2.2 ppt, whereas in the subtropics and at mid-latitudes typical IO mixing ratios were around 1 ppt in the daytime. The profile retrieval reveals that the bulk of the IO was located in the lower part of the marine boundary layer. Photochemical simulations indicate that the organic iodine precursors observed during the cruise (CH3I, CH2I2, CH2ClI, CH2BrI) are not sufficient to explain the measured IO mixing ratios. Reasonable agreement between measured and modelled IO can only be achieved, if an additional sea-air flux of inorganic iodine (e.g. I2) is assumed in the model. Our observations add further evidence to previous studies that reactive iodine is an important oxidant in the marine boundary layer. [ABSTRACT FROM AUTHOR]

Published

2012

44. HOCl and Cl2 observations in marine air.

Author

Lawler, M. J., Sander, R., Carpenter, L. J., Lee, J. D., von Glasow, R., Sommariva, R., and Saltzman, E. S.

Subjects

ATMOSPHERIC methane, ATMOSPHERIC boundary layer, CHLORINE & the environment, ENVIRONMENTAL impact analysis, ATMOSPHERIC models, ATMOSPHERIC chemistry, AIR pollution

Abstract

Cl atoms in the marine atmosphere may significantly impact the lifetimes of methane and other hydrocarbons. However, the existing estimates of Cl atom levels in marine air are based on indirect evidence. Here we present measurements of the Cl precursors HOCl and Cl2 in the marine boundary layer during June of 2009 at the Cape Verde Atmospheric Observatory in the eastern tropical Atlantic. These are the first measurements of tropospheric HOCl. HOCl and Cl2 levels were low in air with open ocean back trajectories, with maximum levels always below 60 and 10 ppt (pmol/mol), respectively. In air with trajectories originating over Europe, HOCl and Cl2 levels were higher, with HOCl maxima exceeding 100 ppt each day and Cl2 reaching up to 35 ppt. The increased Cl cycling associated with long distance pollutant transport over the oceans likely impacts a wide geographic area and represents a mechanism by which human activities have increased the reactivity of the marine atmosphere. Data-constrained model simulations indicate that Cl atoms account for approximately 15% of methane destruction on days when aged polluted air arrives at the site. A photochemical model does not adequately simulate the observed abundances of HOCl and Cl2, raising the possibility of an unknown HOCl source. [ABSTRACT FROM AUTHOR]

Published

2011

45. Emissions and photochemistry of oxygenated VOCs in urban plumes in the Northeastern United States.

Author

Sommariva, R., de Gouw, J. A., Trainer, M., Atlas, E., Goldan, P. D., Kuster, W. C., Warneke, C., and Fehsenfeld, F. C.

Abstract

Photochemical processes inside urban plumes in the Northeast of the United States have been studied using a highly detailed chemical model, based upon the Master Chemical Mechanism (MCM). The model results have been compared to measurements of oxygenated VOCs (acetone, methyl ethyl ketone, acetaldehyde, acetic acid and methanol) obtained during several flights of the NOAA WP-3D aircraft, which sampled plumes from the New York City area during the ICARTT campaign in 2004. The agreement between the model and the measurements was within 40-60% for all species, except acetic acid. The model results have been used to study the formation and photochemical evolution of acetone, methyl ethyl ketone and acetaldehyde. Under the conditions encountered during the ICARTT campaign, acetone is produced from the oxidation of propane (24-28%) and i-propanol (<15%) and from a number of products of i-pentane oxidation. Methyl ethyl ketone (MEK) is mostly produced from the oxidation of n-butane (20-30%) and 3-methylpentane (<40%). Acetaldehyde is formed from several precursors, mostly small alkenes, >C5 alkanes, propanal and MEK. Ethane and ethanol oxidation account, respectively, for 6-23% and 5-25% of acetaldehyde photochemical formation. The results highlight the importance of long-chain alkanes for the photochemical production of ketones and the role of hydroperoxides in sustaining their formation far from the emission sources. [ABSTRACT FROM AUTHOR]

Published

2008

46. The North Atlantic Marine Boundary Layer Experiment (NAMBLEX). Overview of the campaign held at Mace Head, Ireland, in summer 2002.

Author

Heard, D. E., Read, K. A., Methven, J., Al-Haider, S., Bloss, W. J., Johnson, G. P., Pilling, M. J., Seakins, P. W., Smith, S. C., Sommariva, R., Stanton, J. C., Still, T. J., Ingham, T., Brooks, B., De Leeuw, G., Jackson, A. V., McQuaid, J. B., Morgan, R., Smith, M. H., and Carpenter, L. J.

Subjects

AERODYNAMICS, GASES, AIR pollution, PEROXIDES, CLIMATOLOGY, AEROSOLS

Abstract

The North Atlantic Marine Boundary Layer Experiment (NAMBLEX), involving over 50 scientists from 12 institutions, took place at Mace Head, Ireland (53.32° N, 9.90° W), between 23 July and 4 September 2002. A wide range of state-of-the-art instrumentation enabled detailed measurements of the boundary layer structure and atmospheric composition in the gas and aerosol phase to be made, providing one of the most comprehensive in situ studies of the marine boundary layer to date. This overview paper describes the aims of the NAMBLEX project in the context of previous field campaigns in the Marine Boundary Layer (MBL), the overall layout of the site, a summary of the instrumentation deployed, the temporal coverage of the measurement data, and the numerical models used to interpret the field data. Measurements of some trace species were made for the first time during the campaign, which was characterised by predominantly clean air of marine origin, but more polluted air with higher levels of NOx originating from continental regions was also experienced. This paper provides a summary of the meteorological measurements and Planetary Boundary Layer (PBL) structure measurements, presents time series of some of the longer-lived trace species (O3, CO, H2, DMS, CH4, NMHC, NOx, NOy, PAN) and summarises measurements of other species that are described in more detail in other papers within this special issue, namely oxygenated VOCs, HCHO, peroxides, organohalogenated species, a range of shorter lived halogen species (I2, OIO, IO, BrO), NO3 radicals, photolysis frequencies, the free radicals OH, HO2 and (HO2+ΣRO2), as well as a summary of the aerosol measurements. NAMBLEX was supported by measurements made in the vicinity of Mace Head using the NERC Dornier-228 aircraft. Using ECMWF windfields, calculations were made of the air-mass trajectories arriving at Mace Head during NAMBLEX, and were analysed together with both meteorological and trace-gas measurements. In this paper a chemical climatology for the duration of the campaign is presented to interpret the distribution of air-mass origins and emission sources, and to provide a convenient framework of air-mass classification that is used by other papers in this issue for the interpretation of observed variability in levels of trace gases and aerosols. [ABSTRACT FROM AUTHOR]

Published

2006

47. OH and HO2 chemistry during NAMBLEX: roles of oxygenates, halogen oxides and heterogeneous uptake.

Author

Sommariva, R., Bloss, W. J., Brough, N., Carslaw, N., Flynn, M., Haggerstone, A. -L., Heard, D. E., Hopkins, J. R., Lee, J. D., Lewis, A. C., McFiggans, G., Monks, P. S., Penkett, S. A., Pilling, M. J., Plane, J. M. C., Read, K. A., Saiz-Lopez, A., Rickard, A. R., and Williams, P. I.

Subjects

CARBON monoxide, ACETALDEHYDE, MATHEMATICAL models, OXYGEN, OXYGENASES

Abstract

Several zero-dimensional box-models with different levels of chemical complexity, based on the Master Chemical Mechanism (MCM), have been used to study the chemistry of OH and HO2 in a coastal environment in the Northern Hemisphere. The models were constrained to and compared with measurements made during the NAMBLEX campaign (Mace Head, Ireland) in summer 2002. The base models, which were constrained to measured CO, CH4 and NMHCs, were able to reproduce [OH] within 25%, but overestimated [HO2] by about a factor of 2. Agreement was improved when the models were constrained to oxygenated compounds (acetaldehyde, methanol and acetone), highlighting their importance for the radical budget. When the models were constrained to measured halogen monoxides (IO, BrO) and used a more detailed, measurements-based, treatment to describe the heterogeneous uptake, modelled [OH] increased by up to 15% and [HO2] decreased by up to 30%. The actual impact of halogen monoxides on the modelled concentrations of HOx was dependant on the uptake coefficients used for HOI, HOBr and HO2. Better agreement, within the combined uncertainties of the measurements and of the model, was achieved when using high uptake coefficients for HO2 and HOI (γHO2=1, γHOI=0.6). A rate of production and destruction analysis of the models allowed a detailed study of OH and HO2 chemistry under the conditions encountered during NAMBLEX, showing the importance of oxygenates and of XO (where X=I, Br) as coreactants for OH and HO2 and of HOX photolysis as a source for OH. [ABSTRACT FROM AUTHOR]

Published

2006

48. Ambient formaldehyde measurements made at a remote marine boundary layer site during the NAMBLEX campaign -- a comparison of data from chromatographic and modified Hantzsch techniques.

Author

Still, T. J., Al-Haider, S., Seakins, P. W., Sommariva, R., Stanton, J. C., Mills, G., and Penkett, S. A.

Abstract

Ambient formaldehyde concentrations are reported from the North Atlantic Marine Boundary Layer Experiment (NAMBLEX) campaign at Mace Head on the west coast of Ireland during August 2002. The results from two techniques, using direct determination via gas chromatography and the Hantzsch technique, show similar trends but a significant off set in concentrations. For westerly air flows characteristic of the marine boundary layer, formaldehyde concentrations from the gas chromatographic and Hantzsch technique ranged from 0.78-1.15 ppb and 0.13-0.43 ppb, respectively. Possible reasons for the discrepancy have been investigated and are discussed, however, no satisfactory explanation has yet been found. In a subsequent intercomparison the two techniques were in good agreement. The observed concentrations have been compared with previous formaldehyde measurements in the North Atlantic marine boundary layer and with other measurements from the NAMBLEX campaign. The measurements from the Hantzsch technique and the GC results lie at the lower and upper ends respectively of previous measurements. In contrast to some previous measurements, both techniques show distinct diurnal profiles with day maxima and with an amplitude of approximately 0.15 ppb. Strong correlations were observed with ethanal concentrations measured during NAMBLEX and the ratio of ethanal to formaldehyde determined by the gas chromatographic technique is in good agreement with previous measurements. Some simple box modelling has been undertaken to investigate possible sources of formaldehyde. Such models are not able to predict absolute formaldehyde concentrations as they do not include transport processes, but the results show that oxygenated VOCs such as ethanal and methanol are very significant sources of formaldehyde in the air masses reaching Mace Head. [ABSTRACT FROM AUTHOR]

Published

2005

49. Peroxy radical chemistry and the control of ozone photochemistry at Mace Head, Ireland during the summer of 2002.

Author

Fleming, Z. L., Monks, P. S., Rickard, A. R., Heard, D. E., Bloss, W. J., Seakins, P. W., Still, T. J., Sommariva, R., Pilling, M. J., Morgan, R., Green, T. J., Brough, N., Mills, G. P., Penkett, S. A., Lewis, A. C., Lee, J. D., Saiz-Lopez, A., and Plane, J. M. C.

Abstract

Peroxy radical (HO2+ΣRO2) measurements, using the PEroxy Radical Chemical Amplification (PERCA) technique at the North Atlantic Marine Boundary Layer EXperiment (NAMBLEX) at Mace Head in summer 2002, are presented and put into the context of marine, boundary-layer chemistry. A suite of other chemical parameters (NO, NO2, NO3, CO, CH4, O3, VOCs, peroxides), photolysis frequencies and meteorological measurements, are used to present a detailed analysis of the role of peroxy radicals in tropospheric oxidation cycles and ozone formation. Under the range of conditions encountered the peroxy radical daily maxima varied from 10 to 40 pptv. The diurnal cycles showed an asymmetric shape typically shifted to the afternoon. Using a box model based on the master chemical mechanism the average model measurement agreement was 2.5 across the campaign. The addition of halogen oxides to the model increases the level of model/measurement agreement, apparently by respeciation of HOx. A good correlation exists between j(HCHO).[HCHO] and the peroxy radicals indicative of the importance of HCHO in the remote atmosphere as a HOx source, particularly in the afternoon. The peroxy radicals showed a strong dependence on [NOx] with a break point at 0.1 ppbv, where the radicals increased concomitantly with the reactive VOC loading, this is a lower value than seen at representative urban campaigns. The HO2/(HO2+ΣRO2) ratios are dependent on [NOx] ranging between 0.2 and 0.6, with the ratio increasing linearly with NOx. Significant night-time levels of peroxy radicals were measured up to 25 pptv. The contribution of ozone-alkenes and NO3-alkene chemistry to night-time peroxy radical production was shown to be on average 59 and 41%. The campaign mean net ozone production rate was 0.11±0.3 ppbv h-1. The ozone production rate was strongly dependent on [NO] having linear sensitivity (dln(P(O3))/dln(NO)=1.0). The results imply that the N(O3) (the in-situ net photochemical rate of ozone production/destruction) will be strongly sensitive in the marine boundary layer to small changes in [NO] which has ramifications for changing NOx loadings in the European continental boundary layer. [ABSTRACT FROM AUTHOR]

Published

2005

50. OH and HO2 chemistry during NAMBLEX: roles of oxygenates, halogen oxides and heterogeneous uptake.

Author

Sommariva, R., Bloss, W. J., Brough, N., Carslaw, N., Flynn, M., Haggerstone, A.-L., Heard, D. E., Hopkins, J. R., Lee, J. D., Lewis, A. C., McFiggans, G., Monks, P. S., Penkett, S. A., Pilling, M. J., Plane, J. M. C., Read, K. A., Saiz-Lopez, A., Rickard, A. R., and Williams, P. I.

Abstract

Several zero-dimensional box-models with different levels of chemical complexity, based on the Master Chemical Mechanism (MCM), have been used to study the chemistry of OH and HO2 in a coastal environment in the Northern Hemisphere. The models were constrained to and compared with measurements made during the NAMBLEX campaign (Mace Head, Ireland) in summer 2002. The base models, which were constrained to measured CO, CH4 and NMHCs, were able to reproduce [OH] within 25%, but overestimated [HO2] by about a factor of 2. Agreement was improved when the models were constrained to oxygenated compounds (acetaldehyde, methanol and acetone), highlighting their importance for the radical budget. When the models were constrained to measured halogen monoxides (IO, BrO) and used a more detailed, measurements-based, treatment to describe the heterogeneous uptake, modelled [OH] increased by up to 15% and [HO2] decreased by up to 30%. The actual impact of halogen monoxides on the modelled concentrations of HOx was dependant on the uptake coefficients used for HOI, HOBr and HO2. The best agreement with the measurements was achieved by constraining the model to measured IO and setting γHO2 = 1 and γHOI = 0.6. A rate of production and destruction analysis of the models allowed a detailed study of OH and HO2 chemistry under the conditions encountered during NAMBLEX, showing the importance of oxygenates and of XO (where X=I, Br) as co-reactants for OH and HO2 and of HOX photolysis as a source for OH. [ABSTRACT FROM AUTHOR]

Published

2005