Vertical variability of the properties of highly aged biomass burning aerosol transported over the southeast Atlantic during CLARIFY-2017
暂无分享,去创建一个
J. Haywood | J. Allan | H. Coe | P. Williams | C. Fox | J. Pitt | S. Abel | Huihui Wu | Nicholas W. Davies | J. Langridge | M. Cotterell | M. Flynn | Jonathan W. Taylor | K. Szpek
[1] P. Formenti,et al. The CLoud–Aerosol–Radiation Interaction and Forcing: Year 2017 (CLARIFY-2017) measurement campaign , 2020, Atmospheric Chemistry and Physics.
[2] C. Flynn,et al. Empirically derived parameterizations of the direct aerosol radiative effect based on ORACLES aircraft observations , 2020, Atmospheric Measurement Techniques.
[3] P. Formenti,et al. Direct and semi-direct radiative forcing of biomass-burning aerosols over the southeast Atlantic (SEA) and its sensitivity to absorbing properties: a regional climate modeling study , 2020, Atmospheric Chemistry and Physics.
[4] M. Wendisch,et al. Influx of African biomass burning aerosol during the Amazonian dry season through layered transatlantic transport of black carbon-rich smoke , 2020, Atmospheric Chemistry and Physics.
[5] J. Haywood,et al. Absorption closure in highly aged biomass burning smoke , 2020, Atmospheric Chemistry and Physics.
[6] M. Christensen,et al. Open cells exhibit weaker entrainment of free-tropospheric biomass burning aerosol into the south-east Atlantic boundary layer , 2020 .
[7] N. Bellouin,et al. Diurnal cycle of the semi-direct effect from a persistent absorbing aerosol layer over marine stratocumulus in large-eddy simulations , 2020, Atmospheric Chemistry and Physics.
[8] P. Zuidema,et al. The diurnal cycle of the smoky marine boundary layer observed during August in the remote southeast Atlantic. , 2019, Atmospheric chemistry and physics.
[9] C. Flynn,et al. Modeling the smoky troposphere of the southeast Atlantic: a comparison to ORACLES airborne observations from September of 2016 , 2019, Atmospheric Chemistry and Physics.
[10] M. Christensen,et al. Open cells can decrease the mixing of free-tropospheric biomass burning aerosol into the south-east Atlantic boundary layer , 2019 .
[11] P. Zieger,et al. A global view on the effect of water uptake on aerosol particle light scattering , 2019, Scientific Data.
[12] S. Kreidenweis,et al. Aging Effects on Biomass Burning Aerosol Mass and Composition: A Critical Review of Field and Laboratory Studies. , 2019, Environmental science & technology.
[13] C. Flynn,et al. Intercomparison of biomass burning aerosol optical properties from in situ and remote-sensing instruments in ORACLES-2016 , 2019, Atmospheric Chemistry and Physics.
[14] B. Vogel,et al. Remote biomass burning dominates southern West African air pollution during the monsoon , 2019, Atmospheric Chemistry and Physics.
[15] M. Andreae. Emission of trace gases and aerosols from biomass burning – an updated assessment , 2019, Atmospheric Chemistry and Physics.
[16] J. Haywood,et al. Transformation and ageing of biomass burning carbonaceous aerosol over tropical South America from aircraft in situ measurements during SAMBBA , 2019, Atmospheric Chemistry and Physics.
[17] P. Zieger,et al. The radiative impact of out-of-cloud aerosol hygroscopic growth during the summer monsoon in southern West Africa , 2019, Atmospheric Chemistry and Physics.
[18] Michael I. Cotterell,et al. Evaluating biases in filter-based aerosol absorption measurements using photoacoustic spectroscopy , 2019, Atmospheric Measurement Techniques.
[19] P. Francis,et al. Observation of absorbing aerosols above clouds over the south-east Atlantic Ocean from the geostationary satellite SEVIRI – Part 1: Method description and sensitivity , 2019, Atmospheric Chemistry and Physics.
[20] J. Haywood,et al. The impact of bath gas composition on the calibration of photoacoustic spectrometers with ozone at discrete visible wavelengths spanning the Chappuis band , 2018, Atmospheric Measurement Techniques.
[21] P. Zuidema,et al. Characteristics of Optically Thin Coastal Florida Cumuli Derived From Surface‐Based Lidar Measurements , 2018, Journal of Geophysical Research: Atmospheres.
[22] J. Beukes,et al. Major secondary aerosol formation in southern African open biomass burning plumes , 2018, Nature Geoscience.
[23] P. Field,et al. Large simulated radiative effects of smoke in the south-east Atlantic , 2018, Atmospheric Chemistry and Physics.
[24] C. Flynn,et al. The Ascension Island Boundary Layer in the Remote Southeast Atlantic is Often Smoky , 2018 .
[25] J. Haywood,et al. On the accuracy of aerosol photoacoustic spectrometer calibrations using absorption by ozone , 2018 .
[26] M. Chin,et al. Biomass burning aerosol transport and vertical distribution over the South African‐Atlantic region , 2017 .
[27] D. Winker,et al. Seasonally transported aerosol layers over southeast Atlantic are closer to underlying clouds than previously reported , 2017, Geophysical research letters.
[28] D. Jaffe,et al. Physical and optical properties of aged biomass burning aerosol from wildfires in Siberia and the Western USA at the Mt. Bachelor Observatory , 2016 .
[29] J. Haywood,et al. Evaluation of biomass burning aerosols in the HadGEM3 climate model with observations from the SAMBBA field campaign , 2016 .
[30] S. Piketh,et al. Smoke and Clouds above the Southeast Atlantic: Upcoming Field Campaigns Probe Absorbing Aerosol’s Impact on Climate , 2016 .
[31] Y. Kondo,et al. Mixing states of light‐absorbing particles measured using a transmission electron microscope and a single‐particle soot photometer in Tokyo, Japan , 2016 .
[32] D. Tanré,et al. Comparison of aerosol optical properties above clouds between POLDER and AeroCom models over the South East Atlantic Ocean during the fire season , 2016 .
[33] P. Zuidema,et al. The role of the southern African easterly jet in modifying the southeast Atlantic aerosol and cloud environments , 2016 .
[34] Jeremy R. Horne,et al. The future of airborne sulfur-containing particles in the absence of fossil fuel sulfur dioxide emissions , 2015, Proceedings of the National Academy of Sciences.
[35] Chul-Un Ro,et al. The Amazon Tall Tower Observatory (ATTO): overview of pilot measurements on ecosystem ecology, meteorology, trace gases, and aerosols , 2015 .
[36] Kostas Tsigaridis,et al. Interannual variability of tropospheric trace gases and aerosols: The role of biomass burning emissions , 2015 .
[37] I. Riipinen,et al. Particulate matter, air quality and climate: Lessons learned and future needs , 2015 .
[38] P. Zuidema,et al. The Convolution of Dynamics and Moisture with the Presence of Shortwave Absorbing Aerosols over the Southeast Atlantic , 2015 .
[39] U. Pöschl,et al. Multiphase chemical kinetics of OH radical uptake by molecular organic markers of biomass burning aerosols: humidity and temperature dependence, surface reaction, and bulk diffusion. , 2015, The journal of physical chemistry. A.
[40] P. Palmer,et al. Size-dependent wet removal of black carbon in Canadian biomass burning plumes , 2014 .
[41] James D. Lee,et al. Airborne observations of IEPOX-derived isoprene SOA in the Amazon during SAMBBA , 2014 .
[42] S. K. Akagi,et al. Aerosol emissions from prescribed fires in the United States: A synthesis of laboratory and aircraft measurements , 2014 .
[43] P. Minnis,et al. Boundary layer regulation in the southeast Atlantic cloud microphysics during the biomass burning season as seen by the A‐train satellite constellation , 2014 .
[44] P. Palmer,et al. Properties and evolution of biomass burning organic aerosol from Canadian boreal forest fires , 2014 .
[45] J. Allan,et al. Assessment of the sensitivity of core/shell parameters derived using the single-particle soot photometer to density and refractive index , 2014 .
[46] Paulo Artaxo,et al. Atmospheric aerosols in Amazonia and land use change: from natural biogenic to biomass burning conditions. , 2013, Faraday discussions.
[47] M. Cubison,et al. Secondary organic aerosol formation and primary organic aerosol oxidation from biomass-burning smoke in a flow reactor during FLAME-3 , 2013 .
[48] J. Trembath. Airborne CCN measurements , 2013 .
[49] D. Lack,et al. On the attribution of black and brown carbon light absorption using the Ångström exponent , 2013 .
[50] S. K. Akagi,et al. Pitfalls with the use of enhancement ratios or normalized excess mixing ratios measured in plumes to characterize pollution sources and aging , 2013 .
[51] M. Gallagher,et al. Development of a cavity-enhanced absorption spectrometer for airborne measurements of CH 4 and CO 2 , 2013 .
[52] B. Weinzierl,et al. Single Particle Soot Photometer intercomparison at the AIDA chamber , 2012 .
[53] S. Martin,et al. Classifying organic materials by oxygen-to-carbon elemental ratio to predict the activation regime of cloud condensation nuclei (CCN). , 2012 .
[54] M. Cubison,et al. Spectral absorption of biomass burning aerosol determined from retrieved single scattering albedo during ARCTAS , 2012 .
[55] T. Diehl,et al. Black carbon vertical profiles strongly affect its radiative forcing uncertainty , 2012 .
[56] S. Lance,et al. Coincidence Errors in a Cloud Droplet Probe (CDP) and a Cloud and Aerosol Spectrometer (CAS), and the Improved Performance of a Modified CDP , 2012 .
[57] A. Weinheimer,et al. Emission characteristics of black carbon in anthropogenic and biomass burning plumes over California during ARCTAS‐CARB 2008 , 2012 .
[58] N. Takegawa,et al. Size dependence of wet removal of black carbon aerosols during transport from the boundary layer to the free troposphere , 2012 .
[59] F. Bréon,et al. Aerosol indirect effect on warm clouds over South-East Atlantic, from co-located MODIS and CALIPSO observations , 2012 .
[60] A. Minikin,et al. Particle sizing calibration with refractive index correction for light scattering optical particle counters and impacts upon PCASP and CDP data collected during the Fennec campaign , 2012 .
[61] P. Zieger,et al. Sensitivity of the Single Particle Soot Photometer to different black carbon types , 2012 .
[62] P. Zieger,et al. Effects of relative humidity on aerosol light scattering: results from different European sites , 2012 .
[63] J. Jimenez,et al. Evaluation of Composition-Dependent Collection Efficiencies for the Aerodyne Aerosol Mass Spectrometer using Field Data , 2012 .
[64] T. Bond,et al. Laboratory-Measured Optical Properties of Inorganic and Organic Aerosols at Relative Humidities up to 95% , 2012 .
[65] J. Seinfeld,et al. Flight-based chemical characterization of biomass burning aerosols within two prescribed burn smoke plumes , 2011 .
[66] A. Weinheimer,et al. Effects of aging on organic aerosol from open biomass burning smoke in aircraft and laboratory studies , 2011 .
[67] R. Engelmann,et al. Further evidence for significant smoke transport from Africa to Amazonia , 2011 .
[68] D. Blake,et al. Emissions of Black Carbon, Organic, and Inorganic Aerosols From Biomass Burning in North America and Asia in 2008 , 2011 .
[69] Jared D. Smith,et al. Carbon oxidation state as a metric for describing the chemistry of atmospheric organic aerosol. , 2011, Nature chemistry.
[70] J. Randerson,et al. Global fire emissions and the contribution of deforestation, savanna, forest, agricultural, and peat fires (1997-2009) , 2010 .
[71] Cynthia A. Randles,et al. Direct and semi-direct impacts of absorbing biomass burning aerosol on the climate of southern Africa: a Geophysical Fluid Dynamics Laboratory GCM sensitivity study , 2010 .
[72] A. Ebel,et al. Temperature Dependent Thermodynamic Model of the System H+-NH4+-Na+-SO42--NO3--Cl--H2O , 2010 .
[73] Michael Flynn,et al. Black carbon measurements in the boundary layer over western and northern Europe , 2010 .
[74] D. Koch,et al. Black carbon semi-direct effects on cloud cover: review and synthesis , 2010 .
[75] I. Barmpadimos,et al. Relating hygroscopicity and composition of organic aerosol particulate matter , 2010 .
[76] M. Steinbacher,et al. Single particle characterization of black carbon aerosols at a tropospheric alpine site in Switzerland , 2010 .
[77] Joshua A. Gordon,et al. Water droplet calibration of the Cloud Droplet Probe (CDP) and in-flight performance in liquid, ice and mixed-phase clouds during ARCPAC , 2010 .
[78] E. Highwood,et al. Airborne measurements of the spatial distribution of aerosol chemical composition across Europe and evolution of the organic fraction , 2010 .
[79] J. Jimenez,et al. A simplified description of the evolution of organic aerosol composition in the atmosphere , 2010 .
[80] D. R. Collins,et al. Evolution of Organic Aerosols in the Atmosphere , 2009, Science.
[81] E. Atlas,et al. Emissions from biomass burning in the Yucatan , 2009 .
[82] P. Massoli,et al. Absorption Enhancement of Coated Absorbing Aerosols: Validation of the Photo-Acoustic Technique for Measuring the Enhancement , 2009 .
[83] Dirk Richter,et al. Organic aerosol formation in urban and industrial plumes near Houston and Dallas, Texas , 2009 .
[84] J. Haywood,et al. Aircraft measurements of biomass burning aerosol over West Africa during DABEX , 2008 .
[85] Gerard Capes,et al. Aging of biomass burning aerosols over West Africa: Aircraft measurements of chemical composition, microphysical properties, and emission ratios , 2008 .
[86] David S. Covert,et al. Bias in Filter-Based Aerosol Light Absorption Measurements Due to Organic Aerosol Loading: Evidence from Ambient Measurements , 2008 .
[87] Qi Zhang,et al. O/C and OM/OC ratios of primary, secondary, and ambient organic aerosols with high-resolution time-of-flight aerosol mass spectrometry. , 2008, Environmental science & technology.
[88] Martin Mohr,et al. Identification of the mass spectral signature of organic aerosols from wood burning emissions. , 2007, Environmental science & technology.
[89] F. Bréon,et al. Injection height of biomass burning aerosols as seen from a spaceborne lidar , 2007 .
[90] Qi Zhang,et al. A case study of urban particle acidity and its influence on secondary organic aerosol. , 2007, Environmental science & technology.
[91] M. Andreae,et al. Mass spectrometric analysis and aerodynamic properties of various types of combustion-related aerosol particles , 2006 .
[92] Beat Schmid,et al. Direct aerosol forcing: Calculation from observables and sensitivities to inputs , 2006 .
[93] M. Deeter,et al. Satellite-observed pollution from Southern Hemisphere biomass burning. , 2006 .
[94] T. Bond,et al. Light Absorption by Carbonaceous Particles: An Investigative Review , 2006 .
[95] J. Haywood,et al. The direct radiative effect of biomass burning aerosols over southern Africa , 2005 .
[96] Stephan Borrmann,et al. A New Time-of-Flight Aerosol Mass Spectrometer (TOF-AMS)—Instrument Description and First Field Deployment , 2005 .
[97] T. Eck,et al. A review of biomass burning emissions part III: intensive optical properties of biomass burning particles , 2004 .
[98] B. Anderson,et al. A comparison of similar aerosol measurements made on the NASA P3-B, DC-8, and NSF C-130 aircraft during TRACE-P and ACE-Asia , 2004 .
[99] P. Crutzen,et al. Comprehensive Laboratory Measurements of Biomass-Burning Emissions: 1. Emissions from Indonesian, African, and Other Fuels , 2003 .
[100] Jim Haywood,et al. Evolution of biomass burning aerosol properties from an agricultural fire in southern Africa , 2003 .
[101] B. Holben,et al. Comparison of aerosol size distributions, radiative properties, and optical depths determined by aircraft observations and Sun photometers during SAFARI 2000 , 2003 .
[102] P. Formenti,et al. The mean physical and optical properties of regional haze dominated by biomass burning aerosol measured from the C-130 aircraft during SAFARI 2000 , 2003 .
[103] Peter V. Hobbs,et al. Effects of humidity on aerosols in southern Africa during the biomass burning season , 2003 .
[104] P. Formenti,et al. Inorganic and carbonaceous aerosols during the Southern African Regional Science Initiative (SAFARI 2000) experiment: Chemical characteristics, physical properties, and emission data for smoke from African biomass burning , 2003 .
[105] M. Andreae,et al. Emission of trace gases and aerosols from biomass burning , 2001 .
[106] G. Martin,et al. A New Boundary Layer Mixing Scheme. Part I: Scheme Description and Single-Column Model Tests , 2000 .
[107] Andreas Volz-Thomas,et al. An improved fast-response vacuum-UV resonance fluorescence CO instrument , 1999 .
[108] J. Seinfeld,et al. Atmospheric Chemistry and Physics: From Air Pollution to Climate Change , 1998 .
[109] D. Blake,et al. Enhancement of acidic gases in biomass burning impacted air masses over Canada , 1994 .
[110] J. Q. Referee. Interactive comment on “Overview: The CLoud-Aerosol-Radiation Interaction and Forcing: Year-2017 (CLARIFY-2017) measurement campaign” , 2020 .
[111] F. Waquet,et al. The Aerosols, Radiation and Clouds in Southern Africa Field Campaign in Namibia: Overview, Illustrative Observations, and Way Forward , 2020 .
[112] P. A. F. ormenti,et al. THE AEROSOLS, R ADIATION AND CLOUDS IN SOUTHERN AFRICA FIELD CAMPAIGN IN NAMIBIA Overview, Illustrative Observations, and Way Forward , 2019 .
[113] M. Wendisch,et al. Influx of African biomass burning aerosol during the Amazonian dry season through layered transatlantic transport of black carbon-rich smoke , 2019 .
[114] C. Flynn,et al. Intercomparison of biomass burning aerosol optical properties from in-situ and remote-sensing instruments in ORACLES-2016 , 2019 .
[115] Efficiencies of Modified Rosemount Housings for sampling Aerosol on a Fast Atmospheric Research Aircraft , 2012 .
[117] D O U G L A,et al. A Case Study of Urban Particle Acidity and Its Influence on Secondary Organic Aerosol , 2007 .
[118] Jingchuan Zhou. Hygroscopic Properties of Atmospheric Aerosol Particles in Various Environments , 2001 .
[119] J. Seinfeld,et al. Atmospheric Chemistry and Physics Changes in Organic Aerosol Composition with Aging Inferred from Aerosol Mass Spectra , 2022 .