Your search keyword '"K. Plauškaitė"' showing total 8 results

1. Argon offline-AMS source apportionment of organic aerosol over yearly cycles for an urban, rural, and marine site in northern Europe

Author

C. Bozzetti, Y. Sosedova, M. Xiao, K. R. Daellenbach, V. Ulevicius, V. Dudoitis, G. Mordas, S. Byčenkienė, K. Plauškaitė, A. Vlachou, B. Golly, B. Chazeau, J.-L. Besombes, U. Baltensperger, J.-L. Jaffrezo, J. G. Slowik, I. El Haddad, and A. S. H. Prévôt

Subjects

Physics, QC1-999, Chemistry, QD1-999

Abstract

The widespread use of Aerodyne aerosol mass spectrometers (AMS) has greatly improved real-time organic aerosol (OA) monitoring, providing mass spectra that contain sufficient information for source apportionment. However, AMS field deployments remain expensive and demanding, limiting the acquisition of long-term datasets at many sampling sites. The offline application of aerosol mass spectrometry entailing the analysis of nebulized water extracted filter samples (offline-AMS) increases the spatial coverage accessible to AMS measurements, being filters routinely collected at many stations worldwide. PM1 (particulate matter with an aerodynamic diameter + fragment contribution, whose intensity is typically assumed to be equal to that of CO2+. Offline-AMS spectra reveal that the water-soluble CO2+ : CO+ ratio not only shows values systematically > 1 but is also dependent on season, with lower values in winter than in summer. AMS WSOA spectra were analyzed using positive matrix factorization (PMF), which yielded four factors. These factors included biomass burning OA (BBOA), local OA (LOA) contributing significantly only in Vilnius, and two oxygenated OA (OOA) factors, summer OOA (S-OOA) and background OOA (B-OOA), distinguished by their seasonal variability. The contribution of traffic exhaust OA (TEOA) was not resolved by PMF due to both low concentrations and low water solubility. Therefore, the TEOA concentration was estimated using a chemical mass balance approach, based on the concentrations of hopanes, specific markers of traffic emissions. AMS-PMF source apportionment results were consistent with those obtained from PMF applied to marker concentrations (i.e., major inorganic ions, OC / EC, and organic markers including polycyclic aromatic hydrocarbons and their derivatives, hopanes, long-chain alkanes, monosaccharides, anhydrous sugars, and lignin fragmentation products). OA was the largest fraction of PM1 and was dominated by BBOA during winter with an average concentration of 2 µg m−3 (53 % of OM), while S-OOA, probably related to biogenic emissions, was the prevalent OA component during summer with an average concentration of 1.2 µg m−3 (45 % of OM). PMF ascribed a large part of the CO+ explained variability (97 %) to the OOA and BBOA factors. Accordingly, we discuss a new CO+ parameterization as a function of CO2+ and C2H4O2+ fragments, which were selected to describe the variability of the OOA and BBOA factors.

Published

2017

2. Fossil and non-fossil source contributions to atmospheric carbonaceous aerosols during extreme spring grassland fires in Eastern Europe

Author

V. Ulevicius, S. Byčenkienė, C. Bozzetti, A. Vlachou, K. Plauškaitė, G. Mordas, V. Dudoitis, G. Abbaszade, V. Remeikis, A. Garbaras, A. Masalaite, J. Blees, R. Fröhlich, K. R. Dällenbach, F. Canonaco, J. G. Slowik, J. Dommen, R. Zimmermann, J. Schnelle-Kreis, G. A. Salazar, K. Agrios, S. Szidat, I. El Haddad, and A. S. H. Prévôt

Subjects

Physics, QC1-999, Chemistry, QD1-999

Abstract

In early spring the Baltic region is frequently affected by high-pollution events due to biomass burning in that area. Here we present a comprehensive study to investigate the impact of biomass/grass burning (BB) on the evolution and composition of aerosol in Preila, Lithuania, during springtime open fires. Non-refractory submicron particulate matter (NR-PM1) was measured by an Aerodyne aerosol chemical speciation monitor (ACSM) and a source apportionment with the multilinear engine (ME-2) running the positive matrix factorization (PMF) model was applied to the organic aerosol fraction to investigate the impact of biomass/grass burning. Satellite observations over regions of biomass burning activity supported the results and identification of air mass transport to the area of investigation. Sharp increases in biomass burning tracers, such as levoglucosan up to 683 ng m−3 and black carbon (BC) up to 17 µg m−3 were observed during this period. A further separation between fossil and non-fossil primary and secondary contributions was obtained by coupling ACSM PMF results and radiocarbon (14C) measurements of the elemental (EC) and organic (OC) carbon fractions. Non-fossil organic carbon (OCnf) was the dominant fraction of PM1, with the primary (POCnf) and secondary (SOCnf) fractions contributing 26–44 % and 13–23 % to the total carbon (TC), respectively. 5–8 % of the TC had a primary fossil origin (POCf), whereas the contribution of fossil secondary organic carbon (SOCf) was 4–13 %. Non-fossil EC (ECnf) and fossil EC (ECf) ranged from 13–24 and 7–13 %, respectively. Isotope ratios of stable carbon and nitrogen isotopes were used to distinguish aerosol particles associated with solid and liquid fossil fuel burning.

Published

2016

3. Seasonal observation and source apportionment of carbonaceous aerosol from forested rural site (Lithuania)

Author

A. Masalaite, S. Byčenkienė, J. Pauraitė, I. Garbariene, I. el Haddad, C. Bozzetti, J.L. Jaffrezo, J.L. Besombes, K. Plauškaitė-Šukienė, A. Garbaras, J. Šapolaitė, Ž. Ežerinskis, V. Dudoitis, R. Bariseviciute, V. Ulevičius, A.S.H. Prevot, and V. Remeikis

Subjects

Atmospheric Science, General Environmental Science

Published

2022

4. Supplementary material to 'Argon offline-AMS source apportionment of organic aerosol over yearly cycles for an urban, rural and marine site in Northern Europe'

Author

C. Bozzetti, Y. Sosedova, M. Xiao, K. R. Daellenbach, V. Ulevicius, V. Dudoitis, G. Mordas, S. Byčenkienė, K. Plauškaitė, A. Vlachou, B. Golly, B. Chazeau, J.-L. Besombes, U. Baltensperger, J.-L. Jaffrezo, J. G. Slowik, I. El Haddad, and A. S. H. Prévôt

Published

2016

5. Integrated impact of sulphur and nitrogen deposition and ozone on forest ecosystems in Lithuania, 1995–2015

Author

S Byčenkienė, Gintaras Pivoras, Raselė Girgždienė, Gintautas Mozgeris, D Jasinevičienė, Ingrida Augustaitienė, R Matyssek, Almantas Kliučius, M Baumgarten, V Ulevicius, K Plauškaitė, Vitas Marozas, and Algirdas Augustaitis

Subjects

Nitrogen deposition, chemistry.chemical_compound, Ozone, chemistry, Environmental chemistry, Forest ecology, General Engineering, chemistry.chemical_element, Environmental science, Sulfur

Published

2018

6. Atmospheric new particle formation identifier using longitudinal global particle number size distribution data.

Author

Kecorius S, Madueño L, Lovric M, Racic N, Schwarz M, Cyrys J, Casquero-Vera JA, Alados-Arboledas L, Conil S, Sciare J, Ondracek J, Hallar AG, Gómez-Moreno FJ, Ellul R, Kristensson A, Sorribas M, Kalivitis N, Mihalopoulos N, Peters A, Gini M, Eleftheriadis K, Vratolis S, Jeongeun K, Birmili W, Bergmans B, Nikolova N, Dinoi A, Contini D, Marinoni A, Alastuey A, Petäjä T, Rodriguez S, Picard D, Brem B, Priestman M, Green DC, Beddows DCS, Harrison RM, O'Dowd C, Ceburnis D, Hyvärinen A, Henzing B, Crumeyrolle S, Putaud JP, Laj P, Weinhold K, Plauškaitė K, and Byčenkienė S

Abstract

Atmospheric new particle formation (NPF) is a naturally occurring phenomenon, during which high concentrations of sub-10 nm particles are created through gas to particle conversion. The NPF is observed in multiple environments around the world. Although it has observable influence onto annual total and ultrafine particle number concentrations (PNC and UFP, respectively), only limited epidemiological studies have investigated whether these particles are associated with adverse health effects. One plausible reason for this limitation may be related to the absence of NPF identifiers available in UFP and PNC data sets. Until recently, the regional NPF events were usually identified manually from particle number size distribution contour plots. Identification of NPF across multi-annual and multiple station data sets remained a tedious task. In this work, we introduce a regional NPF identifier, created using an automated, machine learning based algorithm. The regional NPF event tag was created for 65 measurement sites globally, covering the period from 1996 to 2023. The discussed data set can be used in future studies related to regional NPF., Competing Interests: Competing interests The authors declare no competing interests. The views expressed are those of the author(s) and not necessarily those of the NIHR, UKHSA or the Department of Health and Social Care., (© 2024. The Author(s).)

Published

2024

7. Source apportionment for indoor air pollution: Current challenges and future directions.

Author

Saraga DΕ, Querol X, Duarte RMBO, Aquilina NJ, Canha N, Alvarez EG, Jovasevic-Stojanovic M, Bekö G, Byčenkienė S, Kovacevic R, Plauškaitė K, and Carslaw N

Abstract

Source apportionment (SA) for indoor air pollution is challenging due to the multiplicity and high variability of indoor sources, the complex physical and chemical processes that act as primary sources, sinks and sources of precursors that lead to secondary formation, and the interconnection with the outdoor environment. While the major indoor sources have been recognized, there is still a need for understanding the contribution of indoor versus outdoor-generated pollutants penetrating indoors, and how SA is influenced by the complex processes that occur in indoor environments. This paper reviews our current understanding of SA, through reviewing information on the SA techniques used, the targeted pollutants that have been studied to date, and their source apportionment, along with limitations or knowledge gaps in this research field. The majority (78 %) of SA studies to date focused on PM chemical composition/size distribution, with fewer studies covering organic compounds such as ketones, carbonyls and aldehydes. Regarding the SA method used, the majority of studies have used Positive Matrix Factorization (31 %), Principal Component Analysis (26 %) and Chemical Mass Balance (7 %) receptor models. The indoor PM sources identified to date include building materials and furniture emissions, indoor combustion-related sources, cooking-related sources, resuspension, cleaning and consumer products emissions, secondary-generated pollutants indoors and other products and activity-related emissions. The outdoor environment contribution to the measured pollutant indoors varies considerably (<10 %- 90 %) among the studies. Future challenges for this research area include the need for optimization of indoor air quality monitoring and data selection as well as the incorporation of physical and chemical processes in indoor air into source apportionment methodology., Competing Interests: Declaration of competing interest The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (Copyright © 2023 Elsevier B.V. All rights reserved.)

Published

2023

8. Evaluation of the anthropogenic black carbon emissions and deposition on Norway spruce and silver birch foliage in the Baltic region.

Author

Byčenkienė S, Pashneva D, Uogintė I, Pauraitė J, Minderytė A, Davulienė L, Plauškaitė K, Skapas M, Dudoitis V, Touqeer G, Andriejauskiene J, Araminienė V, Dzenajavičienė EF, Sicard P, Gudynaitė-Franckevičienė V, Varnagirytė-Kabašinskienė I, Pedišius N, Lemanas E, and Vonžodas T

Subjects

Betula, Carbon analysis, Chlorophyll A, Soot, Air Pollutants analysis, Picea

Abstract

This study investigates potential influence of urban trees on black carbon (BC) removal by Norway spruce and silver birch along with the BC formation, mass concentration in air, and source apportionment. The main sources of BC in urban areas are transport, household and industry. BC concentrations monitored in urban background station in Vilnius (Lithuania) showed that biomass burning was a significant contributor to BC emissions even during warm period of the year. Therefore, BC emission levels were determined for the most common biomass fuels (mixed wood pellets, oak, ash, birch and spruce firewood) and two types of agro-biomass (triticale and rapeseed straw pellets) burned in modern and old heating systems. The highest emissions were obtained for biomass fuels especially birch firewood. BC aerosol particles produced by the condensation mechanism during the combustion processes were found in all samples taken from the leaf surface. The short-term effect of BC exposure on photosynthetic pigments (chlorophyll a and b; and carotenoids) in the foliage of one-year-old Norway spruce and silver birch seedlings was evaluated by the experiment carried out in the phytotron greenhouse. The seedlings showed different short-term responses to BC exposure. All treatments applied in the phytotron greenhouse resulted in lower chlorophyll content in spruce foliage compared to natural conditions but not differed for birch seedlings. However, the exposure of BC particles on the spruce and birch seedlings in the phytotron increased the content of photosynthetic pigments compared to the control seedlings in the phytotron. Overall, urban trees can help improve air quality by reducing BC levels through dry deposition on tree foliage, and needle-like trees are more efficient than broad-leaved trees in capturing BC. Nevertheless, a further study could assess the longer-term effects of BC particles on tree biochemical and chemical reactions., (Copyright © 2021 Elsevier Inc. All rights reserved.)

Published

2022