Your search keyword '"Christina Williamson"' showing total 22 results

1. Widespread biomass burning smoke throughout the remote troposphere

Author

P. R. Colarco, Alan J. Hills, Christina Williamson, Karl D. Froyd, Rebecca S. Hornbrook, Gregory P. Schill, Eric A. Ray, Charles A. Brock, A. Kupc, Mian Chin, Huisheng Bian, Eric C. Apel, and Daniel M. Murphy

Subjects

Smoke, geography, geography.geographical_feature_category, 010504 meteorology & atmospheric sciences, 010502 geochemistry & geophysics, Atmospheric sciences, complex mixtures, 01 natural sciences, Latitude, Aerosol, Atmosphere, Troposphere, General Earth and Planetary Sciences, Environmental science, Precipitation, Oceanic basin, Absorption (electromagnetic radiation), 0105 earth and related environmental sciences

Abstract

Biomass burning emits ~34–41 Tg yr−1 of smoke aerosol to the atmosphere. Biomass burning aerosol directly influences the Earth’s climate by attenuation of solar and terrestrial radiation; however, its abundance and distribution on a global scale are poorly constrained, particularly after plumes dilute into the background remote troposphere and are subject to removal by clouds and precipitation. Here we report global-scale, airborne measurements of biomass burning aerosol in the remote troposphere. Measurements were taken during four series of seasonal flights over the Pacific and Atlantic Ocean basins, each with near pole-to-pole latitude coverage. We find that biomass burning particles in the remote troposphere are dilute but ubiquitous, accounting for one-quarter of the accumulation-mode aerosol number and one-fifth of the aerosol mass. Comparing our observations with a high-resolution global aerosol model, we find that the model overestimates biomass burning aerosol mass in the remote troposphere with a mean bias of >400%, largely due to insufficient wet removal by in-cloud precipitation. After updating the model’s aerosol removal scheme we find that, on a global scale, dilute smoke contributes as much as denser plumes to biomass burning’s scattering and absorption effects on the Earth’s radiation field. Aerosol particles produced by biomass burning are ubiquitous in the remote troposphere, according to global airborne measurements over remote ocean regions.

Published

2020

2. Aerosol size distributions during the Atmospheric Tomography Mission (ATom): methods, uncertainties, and data products

Author

Christina Williamson, Maximilian Dollner, Agnieszka Kupc, Nicholas L. Wagner, Joshua P. Schwarz, Karl D. Froyd, Frank Erdesz, Thaopaul V. Bui, Bernadett Weinzierl, M. Richardson, Ru-Shan Gao, Jose L. Jimenez, Pedro Campuzano-Jost, Charles A. Brock, Daniel M. Murphy, Benjamin A. Nault, Joseph M. Katich, and Jason C. Schroder

Subjects

Atmospheric Science, 010504 meteorology & atmospheric sciences, Spectrometer, lcsh:TA715-787, lcsh:Earthwork. Foundations, Photometer, 010502 geochemistry & geophysics, Atmospheric sciences, medicine.disease_cause, 01 natural sciences, Light scattering, Soot, lcsh:Environmental engineering, law.invention, Aerosol, Troposphere, Wavelength, 13. Climate action, law, medicine, Environmental science, lcsh:TA170-171, Particle density, 0105 earth and related environmental sciences

Abstract

From 2016 to 2018 a DC-8 aircraft operated by the US National Aeronautics and Space Administration (NASA) made four series of flights, profiling the atmosphere from 180 m to ∼12 km above sea level (km a.s.l.) from the Arctic to the Antarctic over both the Pacific and Atlantic oceans. This program, the Atmospheric Tomography Mission (ATom), sought to sample the troposphere in a representative manner, making measurements of atmospheric composition in each season. This paper describes the aerosol microphysical measurements and derived quantities obtained during this mission. Dry size distributions from 2.7 nm to 4.8 µm in diameter were measured in situ at 1 Hz using a battery of instruments: 10 condensation particle counters with different nucleation diameters, two ultra-high-sensitivity aerosol size spectrometers (UHSASs), one of which measured particles surviving heating to 300 ∘C, and a laser aerosol spectrometer (LAS). The dry aerosol measurements were complemented by size distribution measurements from 0.5 to 930 µm diameter at near-ambient conditions using a cloud, aerosol, and precipitation spectrometer (CAPS) mounted under the wing of the DC-8. Dry aerosol number, surface area, and volume, and optical scattering and asymmetry parameters at several wavelengths from the near-UV to the near-IR ranges were calculated from the measured dry size distributions (2.7 nm to 4.8 µm). Dry aerosol mass was estimated by combining the size distribution data with particle density estimated from independent measurements of aerosol composition with a high-resolution aerosol mass spectrometer and a single-particle soot photometer. We describe the instrumentation and fully document the aircraft inlet and flow distribution system, the derivation of uncertainties, and the calculation of data products from combined size distributions. Comparisons between the instruments and direct measurements of some aerosol properties confirm that in-flight performance was consistent with calibrations and within stated uncertainties for the two deployments analyzed. The unique ATom dataset contains accurate, precise, high-resolution in situ measurements of dry aerosol size distributions, and integral parameters, and estimates and measurements of optical properties, for particles µm in diameter that can be used to evaluate aerosol abundance and processes in global models.

Published

2019

3. Chemical transport models often underestimate inorganic aerosol acidity in remote regions of the atmosphere

Author

Paul O. Wennberg, Huisheng Bian, Donald R. Blake, Glenn S. Diskin, Douglas A. Day, Duseong S. Jo, Jeffrey R. Pierce, Roya Bahreini, Joseph M. Katich, John D. Crounse, Jason C. Schroder, Hannah M. Allen, Joel A. Thornton, Alma Hodzic, Pedro Campuzano-Jost, Jose L. Jimenez, A. Kupc, John B. Nowak, Mian Chin, Felipe D. Lopez-Hilfiker, Kostas Tsigaridis, Michael J. Cubison, John K. Kodros, Simon L. Clegg, Weiwei Hu, Michelle J. Kim, Benjamin A. Nault, Christina Williamson, Peter F. DeCarlo, Gregory P. Schill, Peter R. Colarco, Eric Scheuer, Brett B. Palm, Eloise A. Marais, J. Andrew Neuman, Ann M. Middlebrook, Fabien Paulot, and Jack E. Dibb

Subjects

Physicochemical Processes, Atmospheric chemistry, 010504 meteorology & atmospheric sciences, Radiative cooling, Lead (sea ice), 010501 environmental sciences, Atmospheric sciences, 01 natural sciences, Aerosol, Atmosphere, chemistry.chemical_compound, Nitrate, chemistry, Environmental chemistry, General Earth and Planetary Sciences, Environmental science, Ammonium, Sulfate, Climate and Earth system modelling, 0105 earth and related environmental sciences, General Environmental Science

Abstract

The inorganic fraction of fine particles affects numerous physicochemical processes in the atmosphere. However, there is large uncertainty in its burden and composition due to limited global measurements. Here, we present observations from eleven different aircraft campaigns from around the globe and investigate how aerosol pH and ammonium balance change from polluted to remote regions, such as over the oceans. Both parameters show increasing acidity with remoteness, at all altitudes, with pH decreasing from about 3 to about −1 and ammonium balance decreasing from almost 1 to nearly 0. We compare these observations against nine widely used chemical transport models and find that the simulations show more scatter (generally R2

Published

2021

4. Large hemispheric difference in ultrafine aerosol concentrations in the lowermost stratosphere

Author

Donald R. Blake, Karl D. Froyd, Chelsea R. Thompson, Charles A. Brock, Gregory P. Schill, Jan Kazil, Eric A. Ray, Joshua P. DiGangi, Jeff Peischl, Agnieszka Kupc, Bernadett Weinzierl, Christina Williamson, Glenn S. Diskin, ThaoPau V Bui, Daniel M. Murphy, Ilann Bourgeois, Thomas B. Ryerson, Andrew W. Rollins, and Maximilian Dollner

Subjects

Environmental science, Atmospheric sciences, Stratosphere, Aerosol

Abstract

On the NASA Atmospheric Tomography Mission (ATom), we observed a sharp hemispheric contrast in the concentration of ultrafine aerosols (3-12 nm diameter) in the lowermost stratosphere that persisted through all four seasons. Exploring possible causes, we show that this is likely caused by aircraft, which emit both ultrafine aerosol and precursor gases for new particle formation (NPF) in quantities that agree well with our observations. While aircraft may emit a range of NPF precursors, we focus here on sulphur dioxide (a major source of atmospheric sulphuric acid), of which we have observations from the same mission. We observe the same hemispheric contrast in sulphur dioxide as ultrafine aerosol, and find that the observed concentrations are in alignment with inventoried aircraft emissions. We present box modeling and thermodynamic calculations that support the plausibility of NPF under the conditions and sulphur dioxide concentrations observed on ATom.While the direct climate impact of ultrafine aerosol in the lowermost stratosphere (LMS) may currently be small, our observations show a definitive size distribution shift of the background aerosol distribution in the northern hemisphere. This is important for assessing aviation impacts, and the expected impacts of increased air-traffic. Furthermore, climate intervention via injection of sulphate or aerosols into the stratosphere is a current subject of research. Our study shows that NPF is possible and likely already happening in the LMS, which must be accounted for in models for stratospheric modification, and points out that we must consider that any intentional stratospheric modification will be applied to two very different hemispheres: a largely pristine southern hemisphere; and an already anthropogenically modified northern hemisphere.

Published

2021

5. Distinct particle modes in the lower stratosphere constrain secondary aerosol chemistry and gas-phase concentrations

Author

Christina Williamson, Karl D. Froyd, Greg Schill, Charles A. Brock, Agnieszka Kupc, and Daniel M. Murphy

Subjects

Chemical physics, Particle, Stratosphere, Aerosol, Gas phase

Abstract

There are distinct types of aerosol particles in the lower stratosphere. Stratospheric sulfuric acid particles with and without meteoric metals coexist with mixed organic-sulfate particles that originated in the troposphere. That these particles remain distinct has important implications for aerosol chemistry and the concentrations of several gas-phase species. Neither semi-volatile organics nor ammonia can be in equilibrium with the gas phase. The gas-phase concentrations of semi-volatile organics and ammonia must be very low, or else the sulfuric acid particles would not stay so pure. The upper concentration limits are around a pptv. Yet the sulfuric acid particles in the Northern Hemisphere show a very small but measurable uptake of organics and ammonia, indicating non-zero gas-phase concentrations of those species. Finally, the organic-sulfate particles must be resistant to photochemical loss, or else they would no longer retain their organic content.

Published

2021

6. Radiative and chemical implications of the size and composition of aerosol particles in the existing or modified global stratosphere

Author

Christina Williamson, Karl D. Froyd, Charles A. Brock, Gregory P. Schill, Chelsea R. Thompson, Daniel M. Murphy, Jeff Peischl, Pengfei Yu, Ilann Bourgeois, and A. Kupc

Subjects

Range (particle radiation), geography, Atmospheric Science, geography.geographical_feature_category, 010504 meteorology & atmospheric sciences, Physics, QC1-999, Northern Hemisphere, 010502 geochemistry & geophysics, Atmospheric sciences, 01 natural sciences, Light scattering, Aerosol, Troposphere, Chemistry, Volcano, Radiative transfer, QD1-999, Stratosphere, 0105 earth and related environmental sciences

Abstract

The size of aerosol particles has fundamental effects on their chemistry and radiative effects. We explore those effects using aerosol size and composition data in the lowermost stratosphere along with calculations of light scattering. In the size range between about 0.1 and 1.0 µm diameter (accumulation mode), there are at least two modes of particles in the lowermost stratosphere. The larger mode consists mostly of particles produced in the stratosphere, and the smaller mode consists mostly of particles transported from the troposphere. The stratospheric mode is similar in the Northern and Southern Hemisphere, whereas the tropospheric mode is much more abundant in the Northern Hemisphere. The purity of sulfuric acid particles in the stratospheric mode shows that there is limited production of secondary organic aerosol in the stratosphere, especially in the Southern Hemisphere. Out of eight sets of flights sampling the lowermost stratosphere (four seasons and two hemispheres) there were three with large injections of specific materials: volcanic, biomass burning, or dust. The stratospheric and tropospheric modes have very different roles for radiative effects on climate and for heterogeneous chemistry. Because the larger particles are more efficient at scattering light, most of the radiative effect in the lowermost stratosphere is due to stratospheric particles. In contrast, the tropospheric particles can have more surface area, at least in the Northern Hemisphere. The surface area of tropospheric particles could have significant implications for heterogeneous chemistry because these particles, which are partially neutralized and contain organics, do not correspond to the substances used for laboratory studies of stratospheric heterogeneous chemistry. We then extend the analysis of size-dependent properties to particles injected into the stratosphere, either intentionally or from volcanoes. There is no single size that will simultaneously maximize the climate impact relative to the injected mass, infrared heating, potential for heterogeneous chemistry, and undesired changes in direct sunlight. In addition, light absorption in the far ultraviolet is identified as an issue requiring more study for both the existing and potentially modified stratosphere.

Published

2021

7. Global Measurements of Brown Carbon and Estimated Direct Radiative Effects

Author

Jack E. Dibb, Gregory P. Schill, Rodney J. Weber, Joshua P. Schwarz, Eric Scheuer, A. Kupc, Daniel M. Murphy, Aoxing Zhang, Yuhang Wang, Linghan Zeng, Charles A. Brock, Christina Williamson, Nicholas L. Wagner, Karl D. Froyd, and Joseph M. Katich

Subjects

Earth's energy budget, biomass burning, Atmospheric Science, 010504 meteorology & atmospheric sciences, aerosol, chemistry.chemical_element, Forcing (mathematics), Atmospheric Composition and Structure, 010502 geochemistry & geophysics, Atmospheric sciences, black carbon, 01 natural sciences, Radiation: Transmission and Scattering, Atmosphere, Oceanography: Biological and Chemical, Paleoceanography, Constituent Sources and Sinks, Radiative transfer, Research Letter, radiation forcing, Instruments and Techniques, Absorption (electromagnetic radiation), 0105 earth and related environmental sciences, Aerosols, Aerosols and Particles, Research Letters, Aerosol, Wavelength, Geophysics, Pollution: Urban and Regional, chemistry, light absorption, brown carbon, General Earth and Planetary Sciences, Environmental science, Troposphere: Constituent Transport and Chemistry, Carbon

Abstract

Brown carbon (BrC) is an organic aerosol material that preferentially absorbs light of shorter wavelengths. Global‐scale radiative impacts of BrC have been difficult to assess due to the lack of BrC observational data. To address this, aerosol filters were continuously collected with near pole‐to‐pole latitudinal coverage over the Pacific and Atlantic basins in three seasons as part of the Atmospheric Tomography Mission. BrC chromophores in filter extracts were measured. We find that globally, BrC was highly spatially heterogeneous, mostly detected in air masses that had been transported from regions of extensive biomass burning. We calculate the average direct radiative effect due to BrC absorption accounted for approximately 7% to 48% of the top of the atmosphere clear‐sky instantaneous forcing by all absorbing carbonaceous aerosols in the remote atmosphere, indicating that BrC from biomass burning is an important component of the global radiative balance., Key Points Globally, biomass burning is a large source of light‐absorbing carbonaceous aerosol that directly affect the planetary radiation balanceTransported over long distances, brown carbon is a significant component of these aerosols, but its contribution was highly variableBrown carbon contributed up to 48% of average clear‐sky instantaneous forcing by light absorption by carbonaceous aerosols

Published

2020

8. Global airborne sampling reveals a previously unobserved dimethyl sulfide oxidation mechanism in the marine atmosphere

Author

Simone Tilmes, A. B. Thames, Jean-Francois Lamarque, Chelsea R. Thompson, William H. Brune, Benjamin A. Nault, Rebecca S. Hornbrook, Glenn M. Wolfe, Christina Williamson, Carlos A. Cuevas, Jose L. Jimenez, Steven S. Brown, Ilann Bourgeois, Thomas B. Ryerson, Douglas E. Kinnison, A. Kupc, Jason C. Schroder, Alfonso Saiz-Lopez, Andrew W. Rollins, Eric C. Apel, T. Paul Bui, Kristian H. Møller, S. Meinardi, Henrik G. Kjaergaard, Alan J. Hills, Charles A. Brock, Derek J. Price, Maximilian Dollner, James B. Burkholder, Patrick R. Veres, Emmanuel Assaf, Jeff Peischl, Pedro Campuzano-Jost, Christopher M. Jernigan, Douglas A. Day, Timothy H. Bertram, D. O. Miller, J. Andrew Neuman, James M. Roberts, Bernadett Weinzierl, Qinyi Li, Donald R. Blake, National Oceanic and Atmospheric Administration (US), National Aeronautics and Space Administration (US), Independent Research Fund Denmark, University of Copenhagen, Ministry of Higher Education and Science (Denmark), Austrian Science Fund, European Commission, National Center for Atmospheric Research (US), National Science Foundation (US), University of Vienna, Veres, P. R. [0000-0001-7539-353X], Wolfe, G.M. [0000-0001-6586-4043], Saiz-Lopez, A. [0000-0002-0060-1581], Peischl, Jeff [0000-0002-9320-7101], Moller, Kristian H. [0000-0001-8070-8516], Li, Qinyi [0000-0002-5146-5831], Kjaergaard, Henrik G. [0000-0002-7275-8297], Kinnison, Douglas [0000-0002-3418-0834], Cuevas, Carlos A. [0000-0002-9251-5460], Campuzano-Jost, Pedro [0000-0003-3930-010X], Brown, Steven S. [0000-0001-7477-9078], Veres, P. R., Wolfe, G.M., Saiz-Lopez, A., Peischl, Jeff, Moller, Kristian H., Li, Qinyi, Kjaergaard, Henrik G., Kinnison, Douglas, Cuevas, Carlos A., Campuzano-Jost, Pedro, and Brown, Steven S.

Subjects

Earth's energy budget, 010504 meteorology & atmospheric sciences, chemistry.chemical_element, 010501 environmental sciences, Atmospheric sciences, 01 natural sciences, Atmosphere, marine aerosols, chemistry.chemical_compound, Cloud condensation nuclei, 14. Life underwater, marine sulfur, dimethyl sulfide, 0105 earth and related environmental sciences, Multidisciplinary, Atmospheric models, fungi, Biogeochemistry, Correction, Sulfur, Aerosol, Climate Action, autoxidation, chemistry, 13. Climate action, Physical Sciences, Environmental science, Dimethyl sulfide, aerosol sulfate

Abstract

6 pags., 5 figs., Dimethyl sulfide (DMS), emitted from the oceans, is the most abundant biological source of sulfur to the marine atmosphere. Atmospheric DMS is oxidized to condensable products that form secondary aerosols that affect Earth’s radiative balance by scattering solar radiation and serving as cloud condensation nuclei. We report the atmospheric discovery of a previously unquantified DMS oxidation product, hydroperoxymethyl thioformate (HPMTF, HOOCH2SCHO), identified through global-scale airborne observations that demonstrate it to be a major reservoir of marine sulfur. Observationally constrained model results show that more than 30% of oceanic DMS emitted to the atmosphere forms HPMTF. Coincident particle measurements suggest a strong link between HPMTF concentration and new particle formation and growth. Analyses of these observations show that HPMTF chemistry must be included in atmospheric models to improve representation of key linkages between the biogeochemistry of the ocean, marine aerosol formation and growth, and their combined effects on climate., Additional National Oceanic and Atmospheric Administration (NOAA) support for ATom was provided by NASA funding via Inter-Agency Transfer NNH15AB12l and by funding from the NOAA Climate Program Office and the NOAA Atmospheric Chemistry, Carbon Cycle, and Climate program. K.H.M. and H.G.K. acknowledge the financial support of the Independent Research Fund Denmark, the University of Copenhagen, and the Danish Ministry for Higher Education and Science’s Elite Research travel grant. J.L.J.’s group acknowledges NASA grants NHX15AH33A and 80NSSC19K0124. A.K. was supported by the Austrian Science Fund’s Erwin Schrodinger Fellowship. A.S.-L., Q.L., and C.A.C. are supported by the European Research Council (ERC) Executive Agency under the European Union’s Horizon 2020 Research and Innovation programme (Project ERC-2016-COG 726349 CLIMAHAL). The National Center for Atmospheric Research is sponsored by the National Science Foundation. E.A. and J.B. were funded in part by NASA Atmospheric Composition Program. T.H.B. and C.M.J. acknowledge support from the National Science Foundation Center for Aerosol Impacts on Chemistry of the Environment under grant CHE 1801971. B.W. and M.D. have received funding from the ERC under the European Union’s Horizon 2020 research and innovation framework program under grant 640458 (A-LIFE) and from the University of Vienna.

Published

2020

9. Fast time response measurements of particle size distributions in the 3–60 nm size range with the nucleation mode aerosol size spectrometer

Author

Christina Williamson, David W. Gesler, Frank Erdesz, Charles A. Brock, J. Michael Reeves, Agnieszka Kupc, Richard J. McLaughlin, and James C. Wilson

Subjects

Atmospheric Science, Materials science, 010504 meteorology & atmospheric sciences, Particle number, Spectrometer, lcsh:TA715-787, lcsh:Earthwork. Foundations, Nucleation, 010501 environmental sciences, 01 natural sciences, Aerosol, Computational physics, lcsh:Environmental engineering, Troposphere, Cloud condensation nuclei, Particle size, lcsh:TA170-171, Particle counter, 0105 earth and related environmental sciences

Abstract

Earth's radiation budget is affected by new particle formation (NPF) and the growth of these nanometre-scale particles to larger sizes where they can directly scatter light or act as cloud condensation nuclei (CCN). Large uncertainties remain in the magnitude and spatiotemporal distribution of nucleation (less than 10 nm diameter) and Aitken (10–60 nm diameter) mode particles. Acquiring size-distribution measurements of these particles over large regions of the free troposphere is most easily accomplished with research aircraft. We report on the design and performance of an airborne instrument, the nucleation mode aerosol size spectrometer (NMASS), which provides size-selected aerosol concentration measurements that can be differenced to identify aerosol properties and processes or inverted to obtain a full size distribution between 3 and 60 nm. By maintaining constant downstream pressure the instrument operates reliably over a large range of ambient pressures and during rapid changes in altitude, making it ideal for aircraft measurements from the boundary layer to the stratosphere. We describe the modifications, operating principles, extensive calibrations, and laboratory and in-flight performance of two NMASS instruments operated in parallel as a 10-channel battery of condensation particle counters (CPCs) in the NASA Atmospheric Tomography Mission (ATom) to investigate NPF and growth to cloud-active sizes in the remote free troposphere. An inversion technique to obtain size distributions from the discrete concentrations of each NMASS channel is described and evaluated. Concentrations measured by the two NMASS instruments flying in parallel are self-consistent and also consistent with measurements made with an optical particle counter. Extensive laboratory calibrations with a range of particle sizes and compositions show repeatability of the response function of the instrument to within 5–8 % and no sensitivity in sizing performance to particle composition. Particle number, surface area, and volume concentrations from the data inversion are determined to better than 20 % for typical particle size distributions. The excellent performance of the NMASS systems provides a strong analytical foundation to explore NPF around the globe in the ATom dataset.

Published

2018

10. Modification, calibration, and performance of the Ultra-High Sensitivity Aerosol Spectrometer for particle size distribution and volatility measurements during the Atmospheric Tomography Mission (ATom) airborne campaign

Author

Charles A. Brock, Christina Williamson, Agnieszka Kupc, Nicholas L. Wagner, and Mathews S. Richardson

Subjects

Standard conditions for temperature and pressure, Atmospheric Science, 010504 meteorology & atmospheric sciences, Particle number, Spectrometer, lcsh:TA715-787, Chemistry, lcsh:Earthwork. Foundations, Counting efficiency, Analytical chemistry, 010501 environmental sciences, 01 natural sciences, lcsh:Environmental engineering, Aerosol, Troposphere, Particle-size distribution, lcsh:TA170-171, Volatility (chemistry), 0105 earth and related environmental sciences

Abstract

Atmospheric aerosol is a key component of the chemistry and climate of the Earth's atmosphere. Accurate measurement of the concentration of atmospheric particles as a function of their size is fundamental to investigations of particle microphysics, optical characteristics, and chemical processes. We describe the modification, calibration, and performance of two commercially available, Ultra-High Sensitivity Aerosol Spectrometers (UHSASs) as used on the NASA DC-8 aircraft during the Atmospheric Tomography Mission (ATom). To avoid sample flow issues related to pressure variations during aircraft altitude changes, we installed a laminar flow meter on each instrument to measure sample flow directly at the inlet as well as flow controllers to maintain constant volumetric sheath flows. In addition, we added a compact thermodenuder operating at 300 °C to the inlet line of one of the instruments. With these modifications, the instruments are capable of making accurate (ranging from 7 % for Dp Dp > 0.13 µm), precise ( 1000 to 225 hPa, while simultaneously providing information on particle volatility.We assessed the effect of uncertainty in the refractive index (n) of ambient particles that are sized by the UHSAS assuming the refractive index of ammonium sulfate (n = 1.52). For calibration particles with n between 1.44 and 1.58, the UHSAS diameter varies by +4/−10 % relative to ammonium sulfate. This diameter uncertainty associated with the range of refractive indices (i.e., particle composition) translates to aerosol surface area and volume uncertainties of +8.4/−17.8 and +12.4/−27.5 %, respectively. In addition to sizing uncertainty, low counting statistics can lead to uncertainties of 1000 cm−3.Examples of thermodenuded and non-thermodenuded aerosol number and volume size distributions as well as propagated uncertainties are shown for several cases encountered during the ATom project. Uncertainties in particle number concentration were limited by counting statistics, especially in the tropical upper troposphere where accumulation-mode concentrations were sometimes −3 (counting rates ∼ 5 Hz) at standard temperature and pressure.

Published

2018

11. Temperature uniformity in the CERN CLOUD chamber

Author

Sebastian Ehrhart, Jasper Kirkby, Antonio Dias, Samuel Mumford, Christina Williamson, Serge Mathot, Antti Onnela, Joao Almeida, and Alexander L. Vogel

Subjects

Atmospheric Science, 010504 meteorology & atmospheric sciences, Nucleation, 010402 general chemistry, Atmospheric sciences, 01 natural sciences, law.invention, law, Physics in General, Vertical direction, ddc:550, lcsh:TA170-171, 0105 earth and related environmental sciences, Temperature control, Chemistry, lcsh:TA715-787, lcsh:Earthwork. Foundations, Mechanics, 0104 chemical sciences, Volumetric flow rate, Trace gas, Aerosol, lcsh:Environmental engineering, 13. Climate action, Total air temperature, Cloud chamber

Abstract

The CLOUD (Cosmics Leaving OUtdoor Droplets) experiment at CERN (European Council for Nuclear Research) investigates the nucleation and growth of aerosol particles under atmospheric conditions and their activation into cloud droplets. A key feature of the CLOUD experiment is precise control of the experimental parameters. Temperature uniformity and stability in the chamber are important since many of the processes under study are sensitive to temperature and also to contaminants that can be released from the stainless steel walls by upward temperature fluctuations. The air enclosed within the 26 m3 CLOUD chamber is equipped with several arrays (strings) of high precision, fast-response thermometers to measure its temperature. Here we present a study of the air temperature uniformity inside the CLOUD chamber under various experimental conditions. Measurements were performed under calibration conditions and run conditions, which are distinguished by the flow rate of fresh air and trace gases entering the chamber at 20 and up to 210 L min−1, respectively. During steady-state calibration runs between −70 and +20 °C, the air temperature uniformity is better than ±0.06 °C in the radial direction and ±0.1 °C in the vertical direction. Larger non-uniformities are present during experimental runs, depending on the temperature control of the make-up air and trace gases (since some trace gases require elevated temperatures until injection into the chamber). The temperature stability is ±0.04 °C over periods of several hours during either calibration or steady-state run conditions. During rapid adiabatic expansions to activate cloud droplets and ice particles, the chamber walls are up to 10 °C warmer than the enclosed air. This results in temperature differences of ±1.5 °C in the vertical direction and ±1 °C in the horizontal direction, while the air returns to its equilibrium temperature with a time constant of about 200 s.

Published

2017

12. A new method to quantify mineral dust and other aerosol species from aircraft platforms using single-particle mass spectrometry

Author

Charles A. Brock, Karl D. Froyd, Ann M. Middlebrook, Agnieszka Kupc, Jose-Luis Jimenez, Jack E. Dibb, Daniel M. Murphy, Christina Williamson, Pedro Campuzano-Jost, Kenneth L. Thornhill, James C. Wilson, Gregory P. Schill, and Luke D. Ziemba

Subjects

Atmospheric Science, education.field_of_study, food.ingredient, 010504 meteorology & atmospheric sciences, Resolution (mass spectrometry), lcsh:TA715-787, Sea salt, Population, lcsh:Earthwork. Foundations, Mineralogy, 010501 environmental sciences, Mineral dust, Mass spectrometry, Combustion, 01 natural sciences, Aerosol, lcsh:Environmental engineering, food, Environmental science, Particle, lcsh:TA170-171, education, 0105 earth and related environmental sciences

Abstract

Single-particle mass spectrometry (SPMS) instruments characterize the composition of individual aerosol particles in real time. Their fundamental ability to differentiate the externally mixed particle types that constitute the atmospheric aerosol population enables a unique perspective into sources and transformation. However, quantitative measurements by SPMS systems are inherently problematic. We introduce a new technique that combines collocated measurements of aerosol composition by SPMS and size-resolved absolute particle concentrations on aircraft platforms. Quantitative number, surface area, volume, and mass concentrations are derived for climate-relevant particle types such as mineral dust, sea salt, and biomass burning smoke. Additionally, relative ion signals are calibrated to derive mass concentrations of internally mixed sulfate and organic material that are distributed across multiple particle types. The NOAA Particle Analysis by Laser Mass Spectrometry (PALMS) instrument measures size-resolved aerosol chemical composition from aircraft. We describe the identification and quantification of nine major atmospheric particle classes, including sulfate–organic–nitrate mixtures, biomass burning, elemental carbon, sea salt, mineral dust, meteoric material, alkali salts, heavy fuel oil combustion, and a remainder class. Classes can be sub-divided as necessary based on chemical heterogeneity, accumulated secondary material during aging, or other atmospheric processing. Concentrations are derived for sizes that encompass the accumulation and coarse size modes. A statistical error analysis indicates that particle class concentrations can be determined within a few minutes for abundances above ∼10 ng m−3. Rare particle types require longer sampling times. We explore the instrumentation requirements and the limitations of the method for airborne measurements. Reducing the size resolution of the particle data increases time resolution with only a modest increase in uncertainty. The principal limiting factor to fast time response concentration measurements is statistically relevant sampling across the size range of interest, in particular, sizes D µm for accumulation-mode studies and D > 2 µm for coarse-mode analysis. Performance is compared to other airborne and ground-based composition measurements, and examples of atmospheric mineral dust concentrations are given. The wealth of information afforded by composition-resolved size distributions for all major aerosol types represents a new and powerful tool to characterize atmospheric aerosol properties in a quantitative fashion.

Published

2019

13. A large source of cloud condensation nuclei from new particle formation in the tropics

Author

Maximilian Dollner, Pedro Campuzano-Jost, Jeffrey R. Pierce, Charles A. Brock, Karl D. Froyd, Jose L. Jimenez, A. Kupc, Anna L. Hodshire, Bernadett Weinzierl, Pengfei Yu, Thaopaul V. Bui, Fangqun Yu, Gan Luo, Eric A. Ray, Christina Williamson, John K. Kodros, Kelsey R. Bilsback, Daniel M. Murphy, James C. Wilson, Duncan Axisa, and Benjamin A. Nault

Subjects

Convection, Aerosols, Tropical Climate, Multidisciplinary, Pacific Ocean, 010504 meteorology & atmospheric sciences, Atmosphere, Tropics, Particle (ecology), 010501 environmental sciences, Atmospheric sciences, 01 natural sciences, Aerosol, Troposphere, Models, Chemical, 13. Climate action, Atmospheric chemistry, Radiative transfer, Environmental science, Cloud condensation nuclei, Particulate Matter, Atlantic Ocean, 0105 earth and related environmental sciences

Abstract

Cloud condensation nuclei (CCN) can affect cloud properties and therefore Earth’s radiative balance1–3. New particle formation (NPF) from condensable vapours in the free troposphere has been suggested to contribute to CCN, especially in remote, pristine atmospheric regions4, but direct evidence is sparse, and the magnitude of this contribution is uncertain5–7. Here we use in situ aircraft measurements of vertical profiles of aerosol size distributions to present a global-scale survey of NPF occurrence. We observe intense NPF at high altitudes in tropical convective regions over both Pacific and Atlantic oceans. Together with the results of chemical-transport models, our findings indicate that NPF persists at all longitudes as a global-scale band in the tropical upper troposphere, covering about 40 per cent of Earth’s surface. Furthermore, we find that this NPF in the tropical upper troposphere is a globally important source of CCN in the lower troposphere, where CCN can affect cloud properties. Our findings suggest that the production of CCN as new particles descend towards the surface is not adequately captured in global models, which tend to underestimate both the magnitude of tropical upper tropospheric NPF and the subsequent growth of new particles to CCN sizes. Widespread formation of new particles from condensable vapours observed in the tropical upper troposphere is an important source of cloud condensation nuclei in the lower troposphere, affecting cloud properties.

Published

2019

14. The distribution of sea-salt aerosol in the global troposphere

Author

Eric Scheuer, Maximillian Dollner, Charles A. Brock, Pengfei Yu, Glenn S. Diskin, Daniel M. Murphy, Gregory P. Schill, Joshua P. DiGangi, Agnieszka Kupc, Bernadett Weinzierl, Huisheng Bian, Christina Williamson, Karl D. Froyd, and Jack E. Dibb

Subjects

geography, Atmospheric Science, geography.geographical_feature_category, 010504 meteorology & atmospheric sciences, respiratory system, 010502 geochemistry & geophysics, Atmospheric sciences, 01 natural sciences, Arctic ice pack, complex mixtures, lcsh:QC1-999, Latitude, Aerosol, Troposphere, Atmosphere, lcsh:Chemistry, lcsh:QD1-999, 13. Climate action, Sea salt aerosol, Scavenging, Water vapor, lcsh:Physics, 0105 earth and related environmental sciences

Abstract

We present the first data on the concentration of sea-salt aerosol throughout most of the depth of the troposphere and over a wide range of latitudes, which were obtained during the Atmospheric Tomography (ATom) mission. Sea-salt concentrations in the upper troposphere are very small, usually less than 10 ng per standard m3 (about 10 parts per trillion by mass) and often less than 1 ng m−3. This puts stringent limits on the contribution of sea-salt aerosol to halogen and nitric acid chemistry in the upper troposphere. Within broad regions the concentration of sea-salt aerosol is roughly proportional to water vapor, supporting a dominant role for wet scavenging in removing sea-salt aerosol from the atmosphere. Concentrations of sea-salt aerosol in the winter upper troposphere are not as low as in the summer and the tropics. This is mostly a consequence of less wet scavenging in the drier, colder winter atmosphere. There is also a source of sea-salt aerosol over pack ice that is distinct from that over open water. With a well-studied and widely distributed source, sea-salt aerosol provides an excellent test of wet scavenging and vertical transport of aerosols in chemical transport models.

Published

2019

15. Efficient In-Cloud Removal of Aerosols by Deep Convection

Author

A. Kupc, Owen B. Toon, Joseph M. Katich, Charles A. Brock, Pengfei Yu, Karen H. Rosenlof, Robert W. Portmann, Christopher Maloney, Daniel M. Murphy, Tianyi Fan, Christina Williamson, Karl D. Froyd, Charles G. Bardeen, Saulo R. Freitas, Shang Liu, Gregory P. Schill, Joshua P. Schwarz, and Ru-Shan Gao

Subjects

Convection, Atmospheric Science, food.ingredient, aerosol, Atmospheric Composition and Structure, Atmospheric sciences, complex mixtures, Convective Processes, Troposphere, Oceanography: Biological and Chemical, food, Paleoceanography, Research Letter, secondary activation, Aerosols, Drop (liquid), Sea salt, Carbon black, Radiative forcing, respiratory system, Aerosols and Particles, deep convection, Research Letters, Aerosol, Trace gas, Geophysics, Pollution: Urban and Regional, Atmospheric Processes, convective transport, General Earth and Planetary Sciences, Environmental science, Clouds and Aerosols

Abstract

Convective systems dominate the vertical transport of aerosols and trace gases. The most recent in situ aerosol measurements presented here show that the concentrations of primary aerosols including sea salt and black carbon drop by factors of 10 to 10,000 from the surface to the upper troposphere. In this study we show that the default convective transport scheme in the National Science Foundation/Department of Energy Community Earth System Model results in a high bias of 10–1,000 times the measured aerosol mass for black carbon and sea salt in the middle and upper troposphere. A modified transport scheme, which considers aerosol activation from entrained air above the cloud base and aerosol‐cloud interaction associated with convection, dramatically improves model agreement with in situ measurements suggesting that deep convection can efficiently remove primary aerosols. We suggest that models that fail to consider secondary activation may overestimate black carbon's radiative forcing by a factor of 2., Key Points Deep convection efficiently removes particles at and above the cloud baseThe default convective scheme in climate model overestimates middle and upper tropospheric aerosol (sea salt and black carbon) by a factor of 10–1,000The default convective transport scheme overestimates black carbon's radiative forcing by a factor of 2

Published

2018

16. Reduced anthropogenic aerosol radiative forcing caused by biogenic new particle formation

Author

Ari Laaksonen, Ugo Molteni, Serge Mathot, Matti P. Rissanen, Jaeseok Kim, Richard C. Flagan, Hamish Gordon, Manuel Krapf, Felix Piel, Roberto Guida, Yuri Stozhkov, Armin Hansel, S. A. Monks, Sangeeta Sharma, Josef Dommen, Antonio Dias, Neil M. Donahue, Jasper Kirkby, Sophia Brilke, Frank Stratmann, Lukas Fischer, Jonathan Duplissy, Gerhard Steiner, Martin Breitenlechner, Urs Baltensperger, Penglin Ye, Alexandru Rap, Joachim Curtius, Juha Kangasluoma, António Tomé, Douglas R. Worsnop, Tuukka Petäjä, Eimear M. Dunne, Carla Frege, Jasmin Tröstl, Paul M. Winkler, Kenneth S. Carslaw, Chao Yan, Nina Sarnela, Joao Almeida, Xuan Zhang, Linda Rondo, Kamalika Sengupta, Otso Peräkylä, J. S. Craven, Jani Hakala, Antti Onnela, Markku Kulmala, Mario Simon, F. Bianchi, Heikki Junninen, Paul E. Wagner, Andreas Kürten, Sebastian Ehrhart, Martin Heinritzi, Kirsty J. Pringle, John H. Seinfeld, Ismael K. Ortega, Claudia Fuchs, Mikko Sipilä, Alessandro Franchin, Tuija Jokinen, Tuomo Nieminen, Daniela Wimmer, Xuemeng Chen, Anne-Kathrin Bernhammer, António Amorim, Ernest Weingartner, Andrea Christine Wagner, Annele Virtanen, Vladimir Makhmutov, Katrianne Lehtipalo, Alexey Adamov, N. A. D. Richards, Arnaud P. Praplan, Catherine E. Scott, Christopher R. Hoyle, Siegfried Schobesberger, Christina Williamson, Alexander L. Vogel, Robert Wagner, CERN [Genève], University of Leeds, Helsinki Institute of Physics (HIP), University of Helsinki, Paul Scherrer Institute (PSI), Institute for Atmospheric and Environmental Sciences [Frankfurt/Main] (IAU), Goethe-University Frankfurt am Main, Cooperative Institute for Research in Environmental Sciences (CIRES), University of Colorado [Boulder]-National Oceanic and Atmospheric Administration (NOAA), National Oceanic and Atmospheric Administration (NOAA), University of Eastern Finland, ONERA - The French Aerospace Lab [Palaiseau], ONERA-Université Paris Saclay (COmUE), Laboratoire de Physique des Lasers, Atomes et Molécules - UMR 8523 (PhLAM), Université de Lille-Centre National de la Recherche Scientifique (CNRS), Finnish Meteorological Institute (FMI), Laboratory for Systems, Instrumentation and Modeling in Science and Technology for Space and the Environment (University of Lisbon and University of Beira Interior), Institut für Ionenphysik und Angewandte Physik - Institute for Ion Physics and Applied Physics [Innsbruck], Leopold Franzens Universität Innsbruck - University of Innsbruck, Ionicon Analytik GmbH, California Institute of Technology (CALTECH), Institute for Snow and Avalanche Research SLF, WSL, Korea Polar Research Institute (KOPRI), Solar and Cosmic Ray Research Laboratory [Moscow], P. N. Lebedev Physical Institute of the Russian Academy of Sciences [Moscow] (LPI RAS), Russian Academy of Sciences [Moscow] (RAS)-Russian Academy of Sciences [Moscow] (RAS), NERC National Centre for Earth Observation (NCEO), Natural Environment Research Council (NERC), Faculty of Physics [Vienna], Universität Wien, Center for Atmospheric Particle Studies [Pittsburgh] (CAPS), Carnegie Mellon University [Pittsburgh] (CMU), Helsingin yliopisto = Helsingfors universitet = University of Helsinki, and University of Beira Interior [Portugal] (UBI)

Subjects

0301 basic medicine, 010504 meteorology & atmospheric sciences, Climate, education, Forcing (mathematics), History, 18th Century, Atmospheric sciences, complex mixtures, History, 21st Century, 01 natural sciences, [SPI.AUTO]Engineering Sciences [physics]/Automatic, Troposphere, Atmosphere, 03 medical and health sciences, BIOGENIC, Humans, Cloud condensation nuclei, Computer Simulation, Industrial Development, Aerosol, 0105 earth and related environmental sciences, Aerosols, Air Pollutants, Models, Statistical, Multidisciplinary, [SPI.FLUID]Engineering Sciences [physics]/Reactive fluid environment, Uncertainty, FORCING, AEROSOL, History, 19th Century, respiratory system, History, 20th Century, Radiative forcing, CLIMATE, 030104 developmental biology, 13. Climate action, Climatology, Physical Sciences, Cloud albedo, Environmental science, Particle, Biogenic, Forcing

Abstract

International audience; The magnitude of aerosol radiative forcing caused by anthropogenic emissions depends on the baseline state of the atmosphere under Q:11 pristine preindustrial conditions. Measurements in the European Organisation for Nuclear Research (CERN) CLOUD chamber show that particle formation in atmospheric conditions can occur solely from Q:12 biogenic vapors. Here, we evaluate the potential effect of this source of particles on preindustrial cloud condensation nucleus (CCN) concentrations and aerosol cloud radiative forcing over the industrial period.Model simulations show that the pure biogenic particle formation mechanism has a much larger relative effect on CCN concentrations in the preindustrial atmosphere than in the present atmosphere because of the lower aerosol concentrations. Consequently, preindustrial cloud albedo is increased more than under present day conditions, and therefore, the cooling forcing of anthropogenic aerosols is reduced. Q:13 The mechanism increases CCN concentrations by 20–100% over a large fraction of the preindustrial lower atmosphere, and the magnitude of annual global mean radiative forcing caused by changes of cloud albedo since 1750 is reduced by 0.22 W m−² (27%) to −0.60 W m−².Model uncertainties, relatively slow formation rates, and limited available ambient measurements make it difficult to establish the significance of a mechanism that has its dominant effect under preindustrial conditions. Our simulations predict more particle formation in the Amazon than is observed. However, the first observation of pure organic nucleation has now been reported for the free troposphere. Given the potentially significant effect on anthropogenic forcing, effort should be made to better understand such naturally driven aerosol processes.

Published

2016

17. The effect of acid–base clustering and ions on the growth of atmospheric nano-particles

Author

Taina Ruuskanen, Ismael K. Ortega, Francesco Riccobono, Jonathan Duplissy, Lars Ahlm, Taina Yli-Juuti, Jenni Kontkanen, Antti Onnela, F. Bianchi, Serge Mathot, Mario Simon, Richard C. Flagan, Tuomo Nieminen, Jaeseok Kim, Michael J. Lawler, Paul E. Wagner, Sebastian Ehrhart, Neil M. Donahue, Markku Kulmala, Hanna Vehkamäki, Andrew J. Downard, Martin Breitenlechner, Simon Schallhart, António Tomé, Urs Baltensperger, Juha Kangasluoma, Kenneth S. Carslaw, Petri Vaattovaara, Arnaud P. Praplan, Matti P. Rissanen, Nina Sarnela, Douglas R. Worsnop, Jani Hakala, Werner Jud, Aron Vrtala, Annele Virtanen, Alessandro Franchin, R. Schnitzhofer, Eimear M. Dunne, Daniela Wimmer, Alexey Adamov, Armin Hansel, Mikko Sipilä, Paul M. Winkler, Joao Almeida, Andreas Kürten, Roberto Guida, Josef Dommen, Tuija Jokinen, Filipe Duarte Santos, Georgios Tsagkogeorgas, Tinja Olenius, Jasmin Tröstl, Veli-Matti Kerminen, Siegfried Schobesberger, Christina Williamson, Joachim Curtius, Agnieszka Kupc, Jasper Kirkby, António Amorim, James N. Smith, Ilona Riipinen, Markus Leiminger, Tuukka Petäjä, Linda Rondo, Helmi Keskinen, Katrianne Lehtipalo, Oona Kupiainen-Määttä, Ari Laaksonen, Department of Physics, Aerosol-Cloud-Climate -Interactions (ACCI), Helsinki Institute of Physics, and Polar and arctic atmospheric research (PANDA)

Subjects

Atmospheric chemistry, 010504 meteorology & atmospheric sciences, PHASE SULFURIC-ACID, SIZE RANGE, IONIZATION MASS-SPECTROMETRY, Science, Nucleation, General Physics and Astronomy, Nanoparticle, 010501 environmental sciences, 114 Physical sciences, 01 natural sciences, Article, General Biochemistry, Genetics and Molecular Biology, law.invention, Atmosphere, BOREAL FOREST, Ammonia, chemistry.chemical_compound, law, ddc:550, Cloud condensation nuclei, RATES, 1172 Environmental sciences, 0105 earth and related environmental sciences, AMMONIA, Multidisciplinary, Chemistry, fungi, AEROSOL, food and beverages, General Chemistry, Biogeochemistry, CLOUD CHAMBER, Aerosol, 13. Climate action, Chemical physics, NEUTRAL CLUSTER, Other, Cloud chamber, NUCLEATION

Abstract

The growth of freshly formed aerosol particles can be the bottleneck in their survival to cloud condensation nuclei. It is therefore crucial to understand how particles grow in the atmosphere. Insufficient experimental data has impeded a profound understanding of nano-particle growth under atmospheric conditions. Here we study nano-particle growth in the CLOUD (Cosmics Leaving OUtdoors Droplets) chamber, starting from the formation of molecular clusters. We present measured growth rates at sub-3 nm sizes with different atmospherically relevant concentrations of sulphuric acid, water, ammonia and dimethylamine. We find that atmospheric ions and small acid-base clusters, which are not generally accounted for in the measurement of sulphuric acid vapour, can participate in the growth process, leading to enhanced growth rates. The availability of compounds capable of stabilizing sulphuric acid clusters governs the magnitude of these effects and thus the exact growth mechanism. We bring these observations into a coherent framework and discuss their significance in the atmosphere., The growth rates of freshly formed aerosol particles influence what fraction of these can reach sizes large enough to affect cloud formation and climate. Here, the authors show that the nano-particle growth in a sulphuric acid containing system can be enhanced by the presence of ions or small acid-base clusters.

Published

2016

18. Global atmospheric particle formation from CERN CLOUD measurements

Author

Graham Mann, Jonathan Duplissy, Neil M. Donahue, Mikko Sipilä, Daniela Wimmer, Joachim Curtius, Kenneth S. Carslaw, Pasi Miettinen, Paul M. Winkler, Joao Almeida, Matti P. Rissanen, Nina Sarnela, Kamalika Sengupta, F. Bianchi, Michael J. Lawler, António Tomé, Jani Hakala, Markku Kulmala, Eimear M. Dunne, Vladimir Makhmutov, Katrianne Lehtipalo, Douglas R. Worsnop, Alexandru Rap, Kirsty J. Pringle, Ismael K. Ortega, Jasper Kirkby, Francois Benduhn, Peter Barmet, Athanasios Nenes, Alessandro Franchin, Yuri Stozkhov, Josef Dommen, Tuija Jokinen, Agnieszka Kupc, Sebastian Ehrhart, Andreas Kürten, Martin Heinritzi, Mario Simon, Jasmin Tröstl, Armin Hansel, Antony D. Clarke, James N. Smith, Paul E. Wagner, Linda Rondo, Francesco Riccobono, Richard C. Flagan, Joonas Merikanto, Antti Onnela, Serge Mathot, Hamish Gordon, Siegfried Schobesberger, Christina Williamson, N. A. D. Richards, Roberto Guida, Carly Reddington, Alexey Adamov, Juha Kangasluoma, Martin Breitenlechner, Urs Baltensperger, University of Leeds, CERN [Genève], Institute for Atmospheric and Environmental Sciences [Frankfurt/Main] (IAU), Goethe-University Frankfurt am Main, Helsinki Institute of Physics (HIP), Helsingin yliopisto = Helsingfors universitet = University of Helsinki, ONERA - The French Aerospace Lab [Palaiseau], ONERA-Université Paris Saclay (COmUE), Laboratoire de Physique des Lasers, Atomes et Molécules - UMR 8523 (PhLAM), Université de Lille-Centre National de la Recherche Scientifique (CNRS), Laboratory of Atmospheric Chemistry [Paul Scherrer Institute] (LAC), Paul Scherrer Institute (PSI), Institue for Advanced Sustainability Studies, Leopold Franzens University, University of Hawaii, Center for Atmospheric Particle Studies [Pittsburgh] (CAPS), Carnegie Mellon University [Pittsburgh] (CMU), California Institute of Technology (CALTECH), Institut für Ionenphysik und Angewandte Physik - Institute for Ion Physics and Applied Physics [Innsbruck], Leopold Franzens Universität Innsbruck - University of Innsbruck, Department of Physics [Helsinki], Falculty of Science [Helsinki], Helsingin yliopisto = Helsingfors universitet = University of Helsinki-Helsingin yliopisto = Helsingfors universitet = University of Helsinki, Faculty of Physics [Vienna], Universität Wien, University of Eastern Finland, Solar and Cosmic Ray Research Laboratory [Moscow], P. N. Lebedev Physical Institute of the Russian Academy of Sciences [Moscow] (LPI RAS), Russian Academy of Sciences [Moscow] (RAS)-Russian Academy of Sciences [Moscow] (RAS), Institute for Environmental Research & Sustainable Development, National Observatory of Athens (NOA), School of Earth and Atmospheric Sciences [Atlanta], Georgia Institute of Technology [Atlanta], Institute of Chemical Engineering Sciences - Hellas [Crete] (ICE-HT), Foundation for Research and Technology - Hellas (FORTH), CENTRA-SIM, IDL-Faculdade de Ciencias da Universidade de Lisboa, Aerodyne Research Inc., University of Helsinki, and University of Helsinki-University of Helsinki

Subjects

atmospheric chemistry, 010504 meteorology & atmospheric sciences, aerosol, GLOBAL MODELING, Nucleation, 010501 environmental sciences, ammonia, 01 natural sciences, 7. Clean energy, chemistry.chemical_compound, SDG 13 - Climate Action, laboratory method, measurement method, cosmic ray, Physics::Atmospheric and Oceanic Physics, concentration (composition), Multidisciplinary, sulfuric acid, [SPI.FLUID]Engineering Sciences [physics]/Reactive fluid environment, Sulfuric acid, particle size, simulation, astronomy, priority journal, Chemical physics, global perspective, reaction kinetics, NUCLEATION, organic compound, aerosol formation, Mineralogy, Cosmic ray, Article, Ion, Atmosphere, Ammonia, gas, controlled study, flux chamber, 0105 earth and related environmental sciences, atmospheric particle, Aerosol, CLIMATE, chemistry, kinetics, 13. Climate action, atmosphere, Particle, ion, measurement

Abstract

New particle formation in the atmosphere produces around half of the cloud condensation nuclei that seed cloud droplets. Such particles have a pivotal role in determining the properties of clouds and the global radiation balance. Dunne et al. used the CLOUD (Cosmics Leaving Outdoor Droplets) chamber at CERN to construct a model of aerosol formation based on laboratory measured nucleation rates. They found that nearly all nucleation involves either ammonia or biogenic organic compounds. Furthermore in the present day atmosphere cosmic ray intensity cannot meaningfully affect climate via nucleation.Science this issue p. 1119Fundamental questions remain about the origin of newly formed atmospheric aerosol particles because data from laboratory measurements have been insufficient to build global models. In contrast gas phase chemistry models have been based on laboratory kinetics measurements for decades. We built a global model of aerosol formation by using extensive laboratory measurements of rates of nucleation involving sulfuric acid ammonia ions and organic compounds conducted in the CERN CLOUD (Cosmics Leaving Outdoor Droplets) chamber. The simulations and a comparison with atmospheric observations show that nearly all nucleation throughout the present day atmosphere involves ammonia or biogenic organic compounds in addition to sulfuric acid. A considerable fraction of nucleation involves ions but the relatively weak dependence on ion concentrations indicates that for the processes studied variations in cosmic ray intensity do not appreciably affect climate through nucleation in the present day atmosphere.U http://science.sciencemag.org/content/sci/354/6316/1119.full.pdf

Published

2016

19. The role of low-volatility organic compounds in initial particle growth in the atmosphere

Author

Armin Hansel, Ottmar Möhler, Jasmin Tröstl, Claudia Fuchs, Lars Ahlm, Mikko Sipilä, James N. Smith, Paul M. Winkler, Matti P. Rissanen, Antonio Dias, Joao Almeida, Sophia Brilke, Chao Yan, Martin Gysel, Markus Leiminger, Alessandro Franchin, Pasi Miettinen, Martin Breitenlechner, Robert Wagner, Jasper Kirkby, Urs Baltensperger, Michael J. Lawler, Jonathan Duplissy, Richard C. Flagan, Linda Rondo, Ilona Riipinen, Tuomo Nieminen, Antti Onnela, Penglin Ye, Carla Frege, Ernest Weingartner, Felix Piel, Roberto Guida, Siegfried Schobesberger, Christina Williamson, Juha Kangasluoma, Mario Simon, Tuija Jokinen, Ugo Molteni, Anne-Kathrin Bernhammer, Sebastian Ehrhart, Joachim Curtius, Kenneth S. Carslaw, António Tomé, Nina Sarnela, Douglas R. Worsnop, Christopher R. Hoyle, Tuukka Petäjä, Wayne Chuang, Annele Virtanen, Markku Kulmala, Alexey Adamov, Ari Laaksonen, Heikki Junninen, Daniela Wimmer, F. Bianchi, Gerhard Steiner, Andreas Kürten, Katrianne Lehtipalo, Kamalika Sengupta, J. S. Craven, Josef Dommen, Neil M. Donahue, Jaeseok Kim, Helmi Keskinen, Andrea Christine Wagner, Manuel Krapf, Martin Heinritzi, Serge Mathot, and Hamish Gordon

Subjects

Atmospheric chemistry, 010504 meteorology & atmospheric sciences, General Science & Technology, Nucleation, Mineralogy, 010501 environmental sciences, 01 natural sciences, Article, law.invention, law, medicine, ddc:550, Cloud condensation nuclei, Growth rate, Chemical Physics and Chemistry, 0105 earth and related environmental sciences, Multidisciplinary, Chemistry, medicine.disease, Aerosol, 13. Climate action, Chemical physics, Differential mobility analyzer, Thermodynamics, Cloud chamber, Vapours

Abstract

About half of present-day cloud condensation nuclei originate from atmospheric nucleation, frequently appearing as a burst of new particles near midday1. Atmospheric observations show that the growth rate of new particles often accelerates when the diameter of the particles is between one and ten nanometres2,3. In this critical size range, new particles are most likely to be lost by coagulation with pre-existing particles4, thereby failing to form new cloud condensation nuclei that are typically 50 to 100 nanometres across. Sulfuric acid vapour is often involved in nucleation but is too scarce to explain most subsequent growth5,6, leaving organic vapours as the most plausible alternative, at least in the planetary boundary layer7,8,9,10. Although recent studies11,12,13 predict that low-volatility organic vapours contribute during initial growth, direct evidence has been lacking. The accelerating growth may result from increased photolytic production of condensable organic species in the afternoon2, and the presence of a possible Kelvin (curvature) effect, which inhibits organic vapour condensation on the smallest particles (the nano-Köhler theory)2,14, has so far remained ambiguous. Here we present experiments performed in a large chamber under atmospheric conditions that investigate the role of organic vapours in the initial growth of nucleated organic particles in the absence of inorganic acids and bases such as sulfuric acid or ammonia and amines, respectively. Using data from the same set of experiments, it has been shown15 that organic vapours alone can drive nucleation. We focus on the growth of nucleated particles and find that the organic vapours that drive initial growth have extremely low volatilities (saturation concentration less than 10−4.5 micrograms per cubic metre). As the particles increase in size and the Kelvin barrier falls, subsequent growth is primarily due to more abundant organic vapours of slightly higher volatility (saturation concentrations of 10−4.5 to 10−0.5 micrograms per cubic metre). We present a particle growth model that quantitatively reproduces our measurements. Furthermore, we implement a parameterization of the first steps of growth in a global aerosol model and find that concentrations of atmospheric cloud concentration nuclei can change substantially in response, that is, by up to 50 per cent in comparison with previously assumed growth rate parameterizations., Nature, 533 (7604), ISSN:0028-0836, ISSN:1476-4687

Published

2016

20. Discrimination of water, ice and aerosols by light polarisation in the CLOUD experiment

Author

António Tomé, Robert Wagner, Carla Frege, Martin Schnaiter, Antonio Dias, Neil M. Donahue, Thomas Bjerring Kristensen, Paul Connolly, Jasmin Tröstl, Chao Yan, Jasper Kirkby, Leonid Nichman, Niko Florian Höppel, Jonathan Duplissy, F. Bianchi, James Dorsey, Ottmar Möhler, Christina Williamson, Andrea Christine Wagner, F. Stratmann, Christopher R. Hoyle, Emma Järvinen, Gerhard Steiner, Claudia Fuchs, Harald Saathoff, Sebastian Ehrhart, Martin Heinritzi, Hamish Gordon, Richard C. Flagan, Mario Simon, Martin Gallagher, and K. Ignatius

Subjects

010504 meteorology & atmospheric sciences, Backscatter, Ice crystals, Spectrometer, Chemistry, 010402 general chemistry, Atmospheric sciences, 01 natural sciences, 0104 chemical sciences, Aerosol, Troposphere, 13. Climate action, Liquid water content, Phase (matter), ddc:550, Particle, Physics::Atmospheric and Oceanic Physics, 0105 earth and related environmental sciences

Abstract

Cloud microphysical processes involving the ice phase in tropospheric clouds are among the major uncertainties in cloud formation, weather and General Circulation Models (GCMs). The simultaneous detection of aerosol particles, liquid droplets, and ice crystals, especially in the small cloud-particle size range below 50 μm, remains challenging in mixed phase, often unstable ice-water phase environments. The Cloud Aerosol Spectrometer with Polarisation (CASPOL) is an airborne instrument that has the ability to detect such small cloud particles and measure their effects on the backscatter polarisation state. Here we operate the versatile Cosmics-Leaving-OUtdoor-Droplets (CLOUD) chamber facility at the European Organisation for Nuclear Research (CERN) to produce controlled mixed phase and other clouds by adiabatic expansions in an ultraclean environment, and use the CASPOL to discriminate between different aerosols, water and ice particles. In this paper, optical property measurements of mixed phase clouds and viscous Secondary Organic Aerosol (SOA) are presented. We report observations of significant liquid – viscous SOA particle polarisation transitions under dry conditions using CASPOL. Cluster analysis techniques were subsequently used to classify different types of particles according to their polarisation ratios during phase transition. A classification map is presented for water droplets, organic aerosol (e.g., SOA and oxalic acid), crystalline substances such as ammonium sulphate, and volcanic ash. Finally, we discuss the benefits and limitations of this classification approach for atmospherically relevant concentration and mixtures with respect to the CLOUD 8–9 campaigns and its potential contribution to Tropical Troposphere Layer (TTL) analysis.

Published

2015

21. Molecular understanding of sulphuric acid-amine particle nucleation in the atmosphere

Author

Yuri Stozhkov, R. Schnitzhofer, Ville Loukonen, Ilona Riipinen, Oona Kupiainen-Määttä, Johannes Leppä, Joao Almeida, Henning Henschel, Armin Hansel, Taina Ruuskanen, Vladimir Makhmutov, Maija Kajos, Petri Vaattovaara, Serge Mathot, Andreas Kürten, Katrianne Lehtipalo, Ari Laaksonen, Theo Kurtén, Markku Kulmala, Ernest Weingartner, Jasper Kirkby, Matthew J. McGrath, Martin Heinritzi, Tuomo Nieminen, Agnieszka Kupc, Heikki Junninen, Daniela Wimmer, Simon Schallhart, Annele Virtanen, António Tomé, Richard C. Flagan, Helmi Keskinen, Matti P. Rissanen, Ismael K. Ortega, Taina Yli-Juuti, Jonathan Duplissy, Penglin Ye, Alexander N. Kvashin, Josef Dommen, Neil M. Donahue, Yrjö Viisanen, F. Bianchi, Joachim Curtius, Alexey Adamov, Hanna Vehkamäki, Kenneth S. Carslaw, Sebastian Ehrhart, Markus Leiminger, Nina Sarnela, Francesco Riccobono, Douglas R. Worsnop, Arnaud P. Praplan, Jasmin Tröstl, Georgios Tsagkogeorgas, Tinja Olenius, Frank Stratmann, Tuija Jokinen, Eimear M. Dunne, Filipe Duarte Santos, Siegfried Schobesberger, Christina Williamson, Heike Wex, Antti Onnela, Mario Simon, Paul E. Wagner, Jani Hakala, Roberto Guida, Mikko Sipilä, Juha Kangasluoma, Aron Vrtala, A. David, António Amorim, Andrew J. Downard, Martin Breitenlechner, Urs Baltensperger, John H. Seinfeld, Tuukka Petäjä, Alessandro Franchin, Linda Rondo, Department of Physics, Department of Chemistry, Helsinki Institute of Physics, and Aerosol-Cloud-Climate -Interactions (ACCI)

Subjects

Greenhouse Effect, Atmospheric chemistry, 010504 meteorology & atmospheric sciences, FORMATION EVENTS, IONIZATION MASS-SPECTROMETRY, Nucleation, Nanoparticle, 010501 environmental sciences, Atmospheric sciences, 01 natural sciences, ddc:550, NANOPARTICLES, SDG 13 - Climate Action, WATER, Astrophysics::Solar and Stellar Astrophysics, Sulfur Dioxide, Human Activities, Amines, Physics::Atmospheric and Oceanic Physics, Multidisciplinary, Chemistry, 3. Good health, AEROSOL NUCLEATION, Astrophysics::Earth and Planetary Astrophysics, Vapours, Dimethylamines, DIMETHYLAMINE, 114 Physical sciences, Article, Atmosphere, BOREAL FOREST, medicine, Cloud condensation nuclei, RATES, ALIPHATIC-AMINES, Chemical Physics and Chemistry, 0105 earth and related environmental sciences, AMMONIA, Scattering, Sulfuric Acids, medicine.disease, Aerosol, Chemical engineering, Models, Chemical, 13. Climate action, Quantum Theory, Particulate Matter, Cosmic Radiation

Abstract

Amines at typical atmospheric concentrations of a only few molecules per trillion air molecules combine with sulphuric acid to form highly stable aerosol particles at rates similar to those observed in the lower atmosphere. Supplementary information The online version of this article (doi:10.1038/nature12663) contains supplementary material, which is available to authorized users., Atmospheric chemistry of anthropogenic amines Amines emitted into the atmosphere from anthropogenic sources are thought to enhance nucleation from trace atmospheric vapours, stimulate particle formation and influence the development and properties of clouds. Direct evidence for this under atmospheric conditions has been lacking; however, this study, using the CLOUD (Cosmics Leaving OUtdoor Droplets) chamber at CERN, demonstrates that amines at atmospherically relevant concentrations can sufficiently increase nucleation rates to be able to account for the particle formation rates observed in the atmospheric environment. Supplementary information The online version of this article (doi:10.1038/nature12663) contains supplementary material, which is available to authorized users., Nucleation of aerosol particles from trace atmospheric vapours is thought to provide up to half of global cloud condensation nuclei1. Aerosols can cause a net cooling of climate by scattering sunlight and by leading to smaller but more numerous cloud droplets, which makes clouds brighter and extends their lifetimes2. Atmospheric aerosols derived from human activities are thought to have compensated for a large fraction of the warming caused by greenhouse gases2. However, despite its importance for climate, atmospheric nucleation is poorly understood. Recently, it has been shown that sulphuric acid and ammonia cannot explain particle formation rates observed in the lower atmosphere3. It is thought that amines may enhance nucleation4,5,6,7,8,9,10,11,12,13,14,15,16, but until now there has been no direct evidence for amine ternary nucleation under atmospheric conditions. Here we use the CLOUD (Cosmics Leaving OUtdoor Droplets) chamber at CERN and find that dimethylamine above three parts per trillion by volume can enhance particle formation rates more than 1,000-fold compared with ammonia, sufficient to account for the particle formation rates observed in the atmosphere. Molecular analysis of the clusters reveals that the faster nucleation is explained by a base-stabilization mechanism involving acid–amine pairs, which strongly decrease evaporation. The ion-induced contribution is generally small, reflecting the high stability of sulphuric acid–dimethylamine clusters and indicating that galactic cosmic rays exert only a small influence on their formation, except at low overall formation rates. Our experimental measurements are well reproduced by a dynamical model based on quantum chemical calculations of binding energies of molecular clusters, without any fitted parameters. These results show that, in regions of the atmosphere near amine sources, both amines and sulphur dioxide should be considered when assessing the impact of anthropogenic activities on particle formation. Supplementary information The online version of this article (doi:10.1038/nature12663) contains supplementary material, which is available to authorized users.

Published

2013

22. Constraints on global aerosol number concentration, SO2 and condensation sink in UKESM1 using ATom measurements

Author

Hamish Gordon, Ananth Ranjithkumar, Nathan Luke Abraham, Kirsty J. Pringle, Andrew W. Rollins, Christina Williamson, Charles A. Brock, A. Kupc, and Kenneth S. Carslaw

Subjects

0303 health sciences, Atmospheric Science, geography, geography.geographical_feature_category, 010504 meteorology & atmospheric sciences, Particle number, Nucleation, Atmospheric sciences, 01 natural sciences, Sink (geography), Aerosol, Trace gas, Troposphere, 03 medical and health sciences, Boundary layer, 13. Climate action, Mixing ratio, Environmental science, 030304 developmental biology, 0105 earth and related environmental sciences

Abstract

Understanding the vertical distribution of aerosol helps to reduce the uncertainty in the aerosol life cycle and therefore in the estimation of the direct and indirect aerosol forcing. To improve our understanding, we use measurements from four deployments of the Atmospheric Tomography (ATom) field campaign (ATom1–4) which systematically sampled aerosol and trace gases over the Pacific and Atlantic oceans with near pole-to-pole coverage. We evaluate the UK Earth System Model (UKESM1) against ATom observations in terms of joint biases in the vertical profile of three variables related to new particle formation: total particle number concentration (NTotal), sulfur dioxide (SO2) mixing ratio and the condensation sink. The NTotal, SO2 and condensation sink are interdependent quantities and have a controlling influence on the vertical profile of each other; therefore, analysing them simultaneously helps to avoid getting the right answer for the wrong reasons. The simulated condensation sink in the baseline model is within a factor of 2 of observations, but the NTotal and SO2 show much larger biases mainly in the tropics and high latitudes. We performed a series of model sensitivity tests to identify atmospheric processes that have the strongest influence on overall model performance. The perturbations take the form of global scaling factors or improvements to the representation of atmospheric processes in the model, for example by adding a new boundary layer nucleation scheme. In the boundary layer (below 1 km altitude) and lower troposphere (1–4 km), inclusion of a boundary layer nucleation scheme (Metzger et al., 2010) is critical to obtaining better agreement with observations. However, in the mid (4–8 km) and upper troposphere (> 8 km), sub-3 nm particle growth, pH of cloud droplets, dimethyl sulfide (DMS) emissions, upper-tropospheric nucleation rate, SO2 gas-scavenging rate and cloud erosion rate play a more dominant role. We find that perturbations to boundary layer nucleation, sub-3 nm growth, cloud droplet pH and DMS emissions reduce the boundary layer and upper tropospheric model bias simultaneously. In a combined simulation with all four perturbations, the SO2 and condensation sink profiles are in much better agreement with observations, but the NTotal profile still shows large deviations, which suggests a possible structural issue with how nucleation or gas/particle transport or aerosol scavenging is handled in the model. These perturbations are well-motivated in that they improve the physical basis of the model and are suitable for implementation in future versions of UKESM.