Your search keyword '"J A G Orza"' showing total 10 results

1. Measurement report: Receptor modeling for source identification of urban fine and coarse particulate matter using hourly elemental composition

Author

M. Reizer, G. Calzolai, K. Maciejewska, J. A. G. Orza, L. Carraresi, F. Lucarelli, and K. Juda-Rezler

Subjects

Physics, QC1-999, Chemistry, QD1-999

Abstract

The elemental composition of the fine (PM2.5) and coarse (PM2.5−10) fraction of atmospheric particulate matter was measured at an hourly time resolution by the use of a streaker sampler during a winter period at a Central European urban background site in Warsaw, Poland. A combination of multivariate (Positive Matrix Factorization) and wind- (Conditional Probability Function) and trajectory-based (Cluster Analysis) receptor models was applied for source apportionment. It allowed for the identification of five similar sources in both fractions, including sulfates, soil dust, road salt, and traffic- and industry-related sources. Another two sources, i.e., Cl-rich and wood and coal combustion, were solely identified in the fine fraction. In the fine fraction, aged sulfate aerosol related to emissions from domestic solid fuel combustion in the outskirts of the city was the largest contributing source to fine elemental mass (44 %), while traffic-related sources, including soil dust mixed with road dust, road dust, and traffic emissions, had the biggest contribution to the coarse elemental mass (together accounting for 83 %). Regional transport of aged aerosols and more local impact of the rest of the identified sources played a crucial role in aerosol formation over the city. In addition, two intensive Saharan dust outbreaks were registered on 18 February and 8 March 2016. Both episodes were characterized by the long-range transport of dust at 1500 and 3000 m over Warsaw and the concentrations of the soil component being 7 (up to 3.5 µg m−3) and 6 (up to 6.1 µg m−3) times higher than the mean concentrations observed during non-episodes days (0.5 and 1.1 µg m−3) in the fine and coarse fractions, respectively. The set of receptor models applied to the high time resolution data allowed us to follow, in detail, the daily evolution of the aerosol elemental composition and to identify distinct sources contributing to the concentrations of the different PM fractions, and it revealed the multi-faceted nature of some elements with diverse origins in the fine and coarse fractions. The hourly resolution of meteorological conditions and air mass back trajectories allowed us to follow the transport pathways of the aerosol as well.

Published

2021

2. Near-real-time processing of a ceilometer network assisted with sun-photometer data: monitoring a dust outbreak over the Iberian Peninsula

Author

A. Cazorla, J. A. Casquero-Vera, R. Román, J. L. Guerrero-Rascado, C. Toledano, V. E. Cachorro, J. A. G. Orza, M. L. Cancillo, A. Serrano, G. Titos, M. Pandolfi, A. Alastuey, N. Hanrieder, and L. Alados-Arboledas

Subjects

Physics, QC1-999, Chemistry, QD1-999

Abstract

The interest in the use of ceilometers for optical aerosol characterization has increased in the last few years. They operate continuously almost unattended and are also much less expensive than lidars; hence, they can be distributed in dense networks over large areas. However, due to the low signal-to-noise ratio it is not always possible to obtain particle backscatter coefficient profiles, and the vast number of data generated require an automated and unsupervised method that ensures the quality of the profiles inversions. In this work we describe a method that uses aerosol optical depth (AOD) measurements from the AERONET network that it is applied for the calibration and automated quality assurance of inversion of ceilometer profiles. The method is compared with independent inversions obtained by co-located multiwavelength lidar measurements. A difference smaller than 15 % in backscatter is found between both instruments. This method is continuously and automatically applied to the Iberian Ceilometer Network (ICENET) and a case example during an unusually intense dust outbreak affecting the Iberian Peninsula between 20 and 24 February 2016 is shown. Results reveal that it is possible to obtain quantitative optical aerosol properties (particle backscatter coefficient) and discriminate the quality of these retrievals with ceilometers over large areas. This information has a great potential for alert systems and model assimilation and evaluation.

Published

2017

3. The Extreme North African Haboob in October 2008: High‐Resolution Simulation of Organized Moist Convection in the Lee of the Atlas, Dust Recirculation and Poleward Transport

Author

S. Dhital, M. L. Kaplan, J. A. G. Orza, and S. Fiedler

Subjects

Atmospheric Science, Geophysics, Space and Planetary Science, Earth and Planetary Sciences (miscellaneous)

Published

2022

4. PSCF and CWT methods as a tool to identify potential sources of

Author

I, Berriban, M, Azahra, E, Chham, M A, Ferro-García, A, Milena-Pérez, A, Nouayti, J A G, Orza, E, Brattich, L, Tositti, F, Piñero-García, T, El Bardouni, H, Ziani, H, El Yaakoubi, and M, El Barbari

Subjects

Aerosols, Air Pollutants, Lead, Radiation Monitoring, Spain, Humans, Particulate Matter, Seasons, Environmental Monitoring

Abstract

This research is focused on studying the preferred source regions and the pathways of the air masses with high particulate concentrations impacting on the activity concentrations of

Published

2022

5. Influence of meteorological input data on backtrajectory cluster analysis – a seven-year study for southeastern Spain

Author

V. Galiano, J. A. G. Orza, M. Cabello, and G. Ruiz

Subjects

Science, Physics, QC1-999, Meteorology. Climatology, QC851-999

Abstract

Backtrajectory differences and clustering sensitivity to the meteorological input data are studied. Trajectories arriving in Southeast Spain (Elche), at 3000, 1500 and 500 m for the 7-year period 2000–2006 have been computed employing two widely used meteorological data sets: the NCEP/NCAR Reanalysis and the FNL data sets. Differences between trajectories grow linearly at least up to 48 h, showing faster growing after 72 h. A k-means cluster analysis performed on each set of trajectories shows differences in the identified clusters (main flows), partially because the number of clusters of each clustering solution differs for the trajectories arriving at 3000 and 1500 m. Trajectory membership to the identified flows is in general more sensitive to the input meteorological data than to the initial selection of cluster centroids.

Published

2008

6. Air mass origin and its influence over the aerosol size distribution: a study in SE Spain

Author

M. Cabello, J. A. G. Orza, and V. Galiano

Subjects

Science, Physics, QC1-999, Meteorology. Climatology, QC851-999

Abstract

A k-means cluster analysis of 96 hour trajectories arriving in Southeast (SE) Spain at 3000, 1500 and 500 m for the 7-year period 2000–2006 has been performed to identify and describe the main flows arriving at the study area. The dependence of the aerosol size distribution on the air mass origin has been studied by using non-parametric statistics. There are statistically significant differences on aerosol size distribution and meteorological variables at surface level according to the identified clusters.

Published

2008

7. Influence of stratospheric air masses on radiotracers and ozone over the central Mediterranean

Author

E. Brattich, J. A. G. Orza, P. Cristofanelli, P. Bonasoni, L. Tositti

Published

2017

8. 3rd Iberian Meeting on Aerosol Science and Technology (RICTA 2015)

Author

Maria João Costa and J A G Orza

Subjects

Aerosols, Geography, Meteorology, Scientific career, Library science, Conference, Aerosol composition, Aerosol

Abstract

The Third Iberian Meeting on Aerosol Science and Technology (RICTA 2015) was held in the city of Elche (province of Alicante, Spain) from 29 June to 1 July 2015, at Centro de Congresos Ciutat d'Elx. This event was organized and hosted by the Statistical and Computational Physics Laboratory (SCOLAb) of Universidad Miguel Hernandez under the auspices of AECyTA, the Spanish Association for Aerosol Science and Technology Research. As in previous editions, the participation of young researchers was especially welcome, with the organization of the VI Summer School on Aerosol Science and Technology and awards for the best poster and PhD thesis, in recognition of outstanding research or presentations focusing on aerosols, during the early stage of their scientific career. RICTA 2015 aims to present the latest research and advances on the field of aerosols, as well as fostering interaction among the Portuguese and Spanish communities. The meeting gathered over 70 participants from 7 different countries, covering a wide range of aerosol science and technology. It included invited lectures, keynote talks, and several specialized sessions on different issues related to atmospheric aerosols, radiation, instrumentation, fundamental aerosol science, bioaerosols and health effects. The editors would like to express their sincere gratitude to all the participants, in particular, those who contributed to this special issue by submitting their papers to convey the current science discussed at RICTA 2015. In this special issue a series of peer-reviewed papers that cover a wide range of topics are presented: aerosol formation, emission, as well as aerosol composition in terms of physical and optical properties, spatial/temporal distribution of aerosol parameters, aerosol modeling and atmospheric effects, as well as instrumentation devoted to aerosol measurements. Finally, we also thank the referees for their valuable revision of these papers.

Published

2015

9. Trends in the aerosol load properties over south eastern Italy.

Author

J A G Orza and M R Perrone

Published

2015

10. African dust impact on aerosol concentrations at twoheights (2250 and 650 masl) in SE Spain

Author

Orza, J. A. G., Gómez Cascales, P. J., Ferro García, M. A., M Expósito Suárez, V., Milena Pérez, A., Martínez Martínez, B. R., Chham, E., Piñero García, F., Cazorla, A., Alados-Arboledas, L., Olmo, F. J., Erika Brattich, Laura Tositti, Camacho, A., Hernández-Ceballos, M. A., Martiny, N., and J. A. G. Orza, P.J. Gómez Cascales, M.A. Ferro García, V.M Expósito Suárez, A. Milena Pérez, B.R.Martínez Martínez, E. Chham, F. Piñero García, A.Cazorla, L. Alados-Arboledas, F.J. Olmo, E. Brattich, L.Tositti, A. Camacho, M.A.Hernández-Ceballos, N. Martiny

Subjects

Saharan dust, PM10, Sierra Nevada

Abstract

The simultaneous aerosol sampling at two heights in southern Spain may provide valuable information on the vertical structure of the dust transport from North Africa to the Iberian Peninsula. It also allows the characterization of the ambient air at two sites with distinct anthropogenic influence. This work presents the results obtained from the first field campaign of the FRESA project (Impact of dust-laden African air masses and of stratospheric air masses in the Iberian Peninsula. Role of the Atlas Mountains), performed in the period July-November 2017 at El Albergue Universitario in Sierra Nevada (2550 m a.s.l.) and the city of Granada (650 m a.s.l.). The two sites were instrumented with a low-volume sampler with PM10 inlet for daily sampling and mass and chemical composition characterization, a high-volume sampler for total suspended particles (TSP) for weekly sampling and radionuclide activity determination, and with a GRIMM 365 optical particle counter that provides continuously the aerosol size distribution. In Sierra Nevada, daily PM10 concentrations ranged from 0 to 104 µg m-3 depending mainly on the origin and features of the air masses that reach this high-elevation site. Levels overpassed 50 µg m-3 during 5 days and were lower than 20 µg m-3 for 90 days over a total of 124 sampling days. The impact of dust-laden African airflows at this site is particularly intense as dust is transported in most of the cases within welldefined low mid-tropospheric layers. The associated episodic concentrations exceeded 40 µg m-3 . In turn, clean subsiding airflows associated to the polar jet strongly reduced concentrations. In Granada, daily PM10 concentrations are moderately high with values generally between 20 and 40 µg m3 before the first snows fall over Sierra Nevada. Levels were over 50 µg m-3 on 2 days and below 20 µg m-3 on 32 days over a total of 103 sampling days. The highest concentrations do not reach the peaks found at Sierra Nevada. The impact of anthropogenic aerosols of local origin, which are accumulated during highstability conditions, and also of regional origin (both from the Mediterranean and from the SW Iberian Peninsula) is significant. The contribution of African dust outbreaks superimposes to background ambient air concentrations and in some events the increase is observed one day after the African dust impacts over Sierra Nevada. After the first snowfall of the year in Sierra Nevada, there’s a change in wind regime, PM10 levels drop and only accumulation periods or African dust events are able to increase concentrations at levels similar to those detected before. The diurnal pattern of PM10 and particle number concentrations (both of the fine and the coarse fractions) at Granada presents the two typical peaks in the morning and evening; there’s one peak at 16 Local Time - LT in Sierra Nevada. Particle concentrations are smaller in the colder period than in the warmer one, primarily due to the much higher concentrations in the coarse fraction (> 1 µm) in summertime. However, the fine fraction (submicronic) presents a stronger morning peak (centered about 10 LT) in the colder period and also concentrations are slightly higher at about 20-21 LT. Trajectories (calculated 96-hour backward in time starting at 00, 06, 12 and 18 UTC with HYSPLIT using ERAInterim data of 0.5 degree resolution) show that air flows are quite often decoupled at the two altitudes. Dust-laden African flows reached Sierra Nevada on 33 days; of these, dust was advected poleward over the Atlas near the Algerian-Moroccan border on 19 days and on the remaining 14 it followed a pathway over the Atlantic close to the Moroccan coast. However, only on 3 days large-scale flows of African origin reached Granada. In turn, airflows reaching Granada passed previously over the western Mediterranean Sea on 32 days while only on 3 days Mediterranean flows reached Sierra Nevada. Moreover, the total residence time over North Africa of the air parcels reaching Sierra Nevada amounts 9474 hours, and during the corresponding days the total residence time over the Mediterranean of the parcels reaching Granada is 10,055 hours. In contrast, the residence time of the air masses arriving to Granada after residing over Africa is only of 56 hours. This implies that during African dust outbreaks the air masses reaching the study area at the lowest levels do not have African origin but have resided over the Mediterranean, and it is in accordance with Cabello et al. (2017) for Málaga and Orza et al. (submitted) for the whole Spanish Mediterranean. Chemical analysis of the PM10 samples (in progress) will provide the first direct experimental evidence of this fact. The identification of episodes was done by analysing the fine and coarse fractions registered with the Grimm OPCs at the two sites and by the aerosol optical depth (AOD) and Angström exponent (AE) from the AERONET station of IISTA-CEAMA in Granada, in combination with back-trajectories. The low availability of satellite information (Dust RGB product and MODIS aerosol properties) is a major limitation at the study area. A number of distinct episodes can be identified: strong African dust impact at Sierra Nevada while Granada is heavily polluted by anthropogenic aerosols (1 August 2017); strong African dust impact at Sierra Nevada which is observed the following day in Granada (15-16 August 2017); African dust outbreaks impacting simultaneously both sites (e.g., 25 November 2017); episode of accumulation of pollutants at Granada whilst very low concentrations are registered at Sierra Nevada (19-24 November 2017); impact of remote fires at both sites (27 July and 9 September 2017) and fair air quality at both sites (e.g., 16 September 2017). Differences in the onset and duration of the African dust episodes are found between the two sites as well as between the surface and the columnar measurements.