Phenomenology of ultrafine particle concentrations and size distribution across urban Europe.
暂无分享,去创建一个
P. Hopke | T. Petäjä | H. Timonen | B. Hoffmann | C. Reche | X. Querol | M. Pandolfi | J. Putaud | C. Hueglin | D. Rich | D. Beddows | A. Wiedensohler | K. Weinhold | F. J. Gómez-Moreno | I. Salma | K. Eleftheriadis | S. Vratolis | Xiansheng Liu | H. Altug | D. C. Green | N. Marchand | O. Favez | B. Chazeau | Jean-Eudes Petit | H. Kaminski | J. Ondrácek | A. Tremper | C. Asbach | H. Manninen | N. Mihalopoulos | M. Norman | N. Ferlay | S. Crumeyrolle | Pedro Trechera | H. Gerwig | S. Bastian | E. Alonso-Blanco | Janne Lampilahti | G. Gille | M. Merkel | P. Kalkavouras | Sebastiao Martins Dos Santos | Noemí Pérez | Máté Vörösmarty | Jarkko V. Niemi | Marjan Savadkoohi | Meritxell Garcia-Marlès | A. Casans | Juan Andrés Casquero-Vera | N. Zikova | Carmen Wolf | R. M. Harrison | Andrés Alaustey | J. Niemi | J. Lampilahti | Benjamin Chazeau
[1] I. Salma,et al. Particle Number Concentration: A Case Study for Air Quality Monitoring , 2022, Atmosphere.
[2] P. Hopke,et al. Source apportionment of particle number concentrations: A global review. , 2022, The Science of the total environment.
[3] L. Ahonen,et al. The standard operating procedure for Airmodus Particle Size Magnifier and nano-Condensation Nucleus Counter , 2022, Journal of Aerosol Science.
[4] J. Apte,et al. Spatiotemporal profiles of ultrafine particles differ from other traffic-related air pollutants: lessons from long-term measurements at fixed sites and mobile monitoring , 2021, Environmental Science: Atmospheres.
[5] F. Pope,et al. A phenomenology of new particle formation (NPF) at 13 European sites , 2021, Atmospheric Chemistry and Physics.
[6] K. Eleftheriadis,et al. Aerosol microphysics and chemistry reveal the COVID19 lockdown impact on urban air quality , 2021, Scientific reports.
[7] T. Petäjä,et al. Measurement report: The influence of traffic and new particle formation on the size distribution of 1–800 nm particles in Helsinki – a street canyon and an urban background station comparison , 2021, Atmospheric Chemistry and Physics.
[8] X. Basagaña,et al. Associations between sources of particle number and mortality in four European cities. , 2021, Environment international.
[9] T. Petäjä,et al. Quantifying traffic, biomass burning and secondary source contributions to atmospheric particle number concentrations at urban and suburban sites. , 2021, The Science of the total environment.
[10] X. Querol,et al. Lessons from the COVID-19 air pollution decrease in Spain: Now what? , 2021, Science of The Total Environment.
[11] F. Pope,et al. Evaluation of aircraft emissions at London Heathrow Airport , 2021, Atmospheric Environment.
[12] Jae Hyun Kim,et al. Global Air Quality and COVID-19 Pandemic: Do We Breathe Cleaner Air? , 2021, Aerosol and Air Quality Research.
[13] T. Hussein,et al. Regional New Particle Formation over the Eastern Mediterranean and Middle East , 2020, Atmosphere.
[14] E. Pisoni,et al. Impacts of the COVID-19 lockdown on air pollution at regional and urban background sites in northern Italy , 2020, Atmospheric Chemistry and Physics.
[15] T. Weidinger,et al. What can we learn about urban air quality with regard to the first outbreak of the COVID-19 pandemic? A case study from central Europe , 2020, Atmospheric Chemistry and Physics.
[16] L. Ahonen,et al. Overview of measurements and current instrumentation for 1–10 nm aerosol particle number size distributions , 2020, Journal of Aerosol Science.
[17] P. Hopke,et al. Source apportionment of particle number size distribution in urban background and traffic stations in four European cities. , 2019, Environment international.
[18] L. Ahonen,et al. Relating high ozone, ultrafine particles, and new particle formation episodes using cluster analysis , 2019, Atmospheric Environment: X.
[19] Maria L. Gini,et al. Particle number size distribution statistics at City-Centre Urban Background, urban background, and remote stations in Greece during summer , 2019, Atmospheric Environment.
[20] Li Li,et al. Ultrafine particles and PM2.5 in the air of cities around the world: Are they representative of each other? , 2019, Environment international.
[21] B. Stephens,et al. Fine and ultrafine particle removal efficiency of new residential HVAC filters. , 2019, Indoor air.
[22] T. Tuch,et al. Variability of black carbon mass concentrations, sub-micrometer particle number concentrations and size distributions: results of the German Ultrafine Aerosol Network ranging from city street to High Alpine locations , 2019, Atmospheric Environment.
[23] D. Michanowicz,et al. Fine-Scale Source Apportionment Including Diesel-Related Elemental and Organic Constituents of PM2.5 across Downtown Pittsburgh , 2018, International journal of environmental research and public health.
[24] T. Petäjä,et al. Atmospheric new particle formation and growth: review of field observations , 2018, Environmental Research Letters.
[25] Ashutosh Kumar Singh,et al. University of Birmingham Interpretation of particle number size distributions measured across an urban area during the FASTER campaign , 2019 .
[26] Jun Zheng,et al. Atmospheric new particle formation from sulfuric acid and amines in a Chinese megacity , 2018, Science.
[27] S. Pryor,et al. Ultrafine particle number concentrations and size distributions around an elevated highway viaduct , 2018, Atmospheric Pollution Research.
[28] T. Tuch,et al. Mobility particle size spectrometers: Calibration procedures and measurement uncertainties , 2018 .
[29] Xavier Querol,et al. Short-term effects of ultrafine particles on daily mortality by primary vehicle exhaust versus secondary origin in three Spanish cities. , 2018, Environment international.
[30] J. Pettersson,et al. Intensification of ice nucleation observed in ocean ship emissions , 2018, Scientific Reports.
[31] L. Soulhac,et al. Source Apportionment and Data Assimilation in Urban Air Quality Modelling for NO2: The Lyon Case Study , 2018 .
[32] Liisa Pirjola,et al. Traffic is a major source of atmospheric nanocluster aerosol , 2017, Proceedings of the National Academy of Sciences.
[33] Alexandra Schneider,et al. Land use regression modeling of ultrafine particles, ozone, nitrogen oxides and markers of particulate matter pollution in Augsburg, Germany. , 2017, The Science of the total environment.
[34] G. Martini,et al. Environmental Research and Public Health Ultrafine Particle Metrics and Research Considerations: Review of the 2015 Ufp Workshop , 2022 .
[35] D. Mann,et al. Magnetite pollution nanoparticles in the human brain , 2016, Proceedings of the National Academy of Sciences.
[36] T. Petäjä,et al. How to reliably detect molecular clusters and nucleation mode particles withNeutral cluster and Air Ion Spectrometer (NAIS) , 2016 .
[37] Paul S. Monks,et al. Ultrafine particles in four European urban environments: Results from a new continuous long-term monitoring network , 2016 .
[38] B. Vogel,et al. Ultrafine particles over Germany – an aerial survey , 2016 .
[39] Bart Degraeuwe,et al. Impact of passenger car NOx emissions and NO2 fractions on urban NO2 pollution – Scenario analysis for the city of Antwerp, Belgium , 2016 .
[40] A. Ding,et al. Aerosol size distribution and new particle formation in the western Yangtze River Delta of China: 2 years of measurements at the SORPES station , 2015 .
[41] Håkan Pleijel,et al. Variation and co-variation of PM10, particle number concentration, NOx and NO2 in the urban air – Relationships with wind speed, vertical temperature gradient and weather type , 2015 .
[42] Tomaž Katrašnik,et al. Black carbon, particle number concentration and nitrogen oxide emission factors of random in-use vehicles measured with the on-road chasing method , 2015 .
[43] Bert Brunekreef,et al. Land Use Regression Models for Ultrafine Particles and Black Carbon Based on Short-Term Monitoring Predict Past Spatial Variation. , 2015, Environmental science & technology.
[44] Chun Lin,et al. Identifying drivers for the intra-urban spatial variability of airborne particulate matter components and their interrelationships , 2015 .
[45] L. Morawska,et al. Traffic and nucleation events as main sources of ultrafine particles in high-insolation developed world cities , 2015 .
[46] Árpád Farkas,et al. Lung burden and deposition distribution of inhaled atmospheric urban ultrafine particles as the first step in their health risk assessment , 2015 .
[47] Martina S. Ragettli,et al. Short-term associations between traffic-related noise, particle number and traffic flow in three European cities , 2015 .
[48] D. Massabò,et al. Spatial and seasonal variability of carbonaceous aerosol across Italy , 2014 .
[49] Parham Azimi,et al. Estimates of HVAC filtration efficiency for fine and ultrafine particles of outdoor origin , 2014 .
[50] Z. Németh,et al. Spatial extension of nucleating air masses in the Carpathian Basin , 2014 .
[51] L. Morawska,et al. Ultrafine particles in cities. , 2014, Environment international.
[52] T. Petäjä,et al. Chemistry of atmospheric nucleation: on the recent advances on precursor characterization and atmospheric cluster composition in connection with atmospheric new particle formation. , 2014, Annual review of physical chemistry.
[53] T. Petäjä,et al. Characterization of parameters influencing the spatio-temporal variability of urban particle number size distributions in four European cities , 2013 .
[54] S. Weichenthal,et al. A randomized double-blind crossover study of indoor air filtration and acute changes in cardiorespiratory health in a First Nations community. , 2013, Indoor air.
[55] R. Harrison,et al. On the spatial distribution and evolution of ultrafine particles in Barcelona , 2013 .
[56] Julia C. Fussell,et al. Size, source and chemical composition as determinants of toxicity attributable to ambient particulate matter , 2012 .
[57] Frank Drewnick,et al. Investigation of gaseous and particulate emissions from various marine vessel types measured on the banks of the Elbe in Northern Germany , 2012 .
[58] David C. Carslaw,et al. Trends in NOx and NO2 emissions from road traffic in Great Britain , 2012 .
[59] I. Beverland,et al. Correlations of particle number concentrations and metals with nitrogen oxides and other traffic-related air pollutants in Glasgow and London , 2012 .
[60] Karl Ropkins,et al. openair - An R package for air quality data analysis , 2012, Environ. Model. Softw..
[61] R. Harrison,et al. New considerations for PM, Black Carbon and particle number concentration for air quality monitoring across different European cities , 2011 .
[62] R. Harrison,et al. PMF analysis of wide-range particle size spectra collected on a major highway. , 2011, Environmental science & technology.
[63] Lidia Morawska,et al. A review of commuter exposure to ultrafine particles and its health effects , 2011 .
[64] Chunsheng Zhao,et al. Mobility particle size spectrometers: harmonization of technical standards and data structure to facilitate high quality long-term observations of atmospheric particle number size distributions , 2010 .
[65] Zoran Ristovski,et al. Observation of new particle formation in subtropical urban environment , 2010 .
[66] M. D. Maso,et al. Production, growth and properties of ultrafine atmospheric aerosol particles in an urban environment , 2010 .
[67] A. Valavanidis,et al. Airborne Particulate Matter and Human Health: Toxicological Assessment and Importance of Size and Composition of Particles for Oxidative Damage and Carcinogenic Mechanisms , 2008, Journal of environmental science and health. Part C, Environmental carcinogenesis & ecotoxicology reviews.
[68] R. Baumann,et al. Experimental studies on particle emissions from cruising ship, their characteristic properties, transformation and atmospheric lifetime in the marine boundary layer , 2008 .
[69] S. Rodríguez,et al. The contributions of “minimum primary emissions” and “new particle formation enhancements” to the particle number concentration in urban air , 2007 .
[70] Christer Johansson,et al. Spatial & temporal variations of PM10 and particle number concentrations in urban air , 2007, Environmental monitoring and assessment.
[71] T. Petäjä,et al. Sub-micron atmospheric aerosols in the surroundings of Marseille and Athens: physical characterization and new particle formation , 2006 .
[72] Annette Peters,et al. Translocation and potential neurological effects of fine and ultrafine particles a critical update , 2006, Particle and Fibre Toxicology.
[73] Alan M. Jones,et al. Multisite study of particle number concentrations in urban air. , 2005, Environmental science & technology.
[74] G. Oberdörster,et al. Nanotoxicology: An Emerging Discipline Evolving from Studies of Ultrafine Particles , 2005, Environmental health perspectives.
[75] Andrey Khlystov,et al. Nucleation Events During the Pittsburgh Air Quality Study: Description and Relation to Key Meteorological, Gas Phase, and Aerosol Parameters Special Issue of Aerosol Science and Technology on Findings from the Fine Particulate Matter Supersites Program , 2004 .
[76] W. Kreyling,et al. Translocation of Inhaled Ultrafine Particles to the Brain , 2004, Inhalation toxicology.
[77] W. Kreyling,et al. TRANSLOCATION OF ULTRAFINE INSOLUBLE IRIDIUM PARTICLES FROM LUNG EPITHELIUM TO EXTRAPULMONARY ORGANS IS SIZE DEPENDENT BUT VERY LOW , 2002, Journal of toxicology and environmental health. Part A.
[78] Yifang Zhu,et al. Study of ultrafine particles near a major highway with heavy-duty diesel traffic , 2002 .
[79] Yifang Zhu,et al. Concentration and Size Distribution of Ultrafine Particles Near a Major Highway , 2002, Journal of the Air & Waste Management Association.
[80] B. Wehner,et al. Particle number size distributions in a street canyon and their transformation into the urban-air background: measurements and a simple model study , 2002 .
[81] K. Donaldson,et al. INFLAMMATION CAUSED BY PARTICLES AND FIBERS , 2002, Inhalation toxicology.
[82] Richard C. Flagan,et al. History of Electrical Aerosol Measurements , 1998 .