Your search keyword '"Gkikas, Antonis"' showing total 9 results

1. Correction: Korras-Carraca et al. Global Clear-Sky Aerosol Speciated Direct Radiative Effects over 40 Years (1980–2019). Atmosphere 2021, 12 , 1254.

Author

Korras-Carraca, Marios-Bruno, Gkikas, Antonis, Matsoukas, Christos, and Hatzianastassiou, Nikolaos

Subjects

*AEROSOLS, *HUMAN resources departments

Abstract

A correction has been made to Funding: This research has been co-financed by the Operational Program "Human Resources Development, Education and Lifelong Learning" and is co-financed by the European Union (European Social Fund) and Greek national funds. A correction has been made to Acknowledgments: This research is implemented through the Operational Program "Human Resources Development, Education and Lifelong Learning". Global Clear-Sky Aerosol Speciated Direct Radiative Effects over 40 Years (1980-2019). [Extracted from the article]

Published

2022

2. Global Clear-Sky Aerosol Speciated Direct Radiative Effects over 40 Years (1980–2019).

Author

Korras-Carraca, Marios-Bruno, Gkikas, Antonis, Matsoukas, Christos, and Hatzianastassiou, Nikolaos

Subjects

*AEROSOLS, *SURFACE of the earth, *GLOBAL warming, *CARBON-black, *RADIATIVE transfer, *SULFUR cycle

Abstract

We assess the 40-year climatological clear-sky global direct radiative effect (DRE) of five main aerosol types using the MERRA-2 reanalysis and a spectral radiative transfer model (FORTH). The study takes advantage of aerosol-speciated, spectrally and vertically resolved optical properties over the period 1980–2019, to accurately determine the aerosol DREs, emphasizing the attribution of the total DREs to each aerosol type. The results show that aerosols radiatively cool the Earth's surface and heat its atmosphere by 7.56 and 2.35 Wm−2, respectively, overall cooling the planet by 5.21 Wm−2, partly counterbalancing the anthropogenic greenhouse global warming during 1980–2019. These DRE values differ significantly in terms of magnitude, and even sign, among the aerosol types (sulfate and black carbon aerosols cool and heat the planet by 1.88 and 0.19 Wm−2, respectively), the hemispheres (larger NH than SH values), the surface cover type (larger land than ocean values) or the seasons (larger values in local spring and summer), while considerable inter-decadal changes are evident. These DRE differences are even larger by up to an order of magnitude on a regional scale, highlighting the important role of the aerosol direct radiative effect for local and global climate. [ABSTRACT FROM AUTHOR]

Published

2021

3. Dust Climatology of Turkey as a Part of the Eastern Mediterranean Basin via 9-Year CALIPSO-Derived Product.

Author

Aslanoğlu, S. Yeşer, Proestakis, Emmanouil, Gkikas, Antonis, Güllü, Gülen, and Amiridis, Vassilis

Subjects

*DUST, *CLIMATOLOGY, *PARTICULATE matter, *INNER cities, *AEROSOLS, *CLIMATE change

Abstract

Turkey is located in the heart of complex transition geography between Eurasia and the Middle East. In the grand scheme, the so-called eastern Mediterranean Basin is located almost in the middle of the dusty belt, and is a hot spot of climate change. The downstream location of dust-carrying winds from close desert sources reveals Turkey as an open plane to particulate matter exposure throughout the year. In order to clarify this phenomenon, this paper aims to determine the desert dust climatology of Turkey via CALIPSO onboard Lidar. This prominent instrument enables us to understand clouds, aerosols and their types, and related climatic systems, with its valuable products. In this study, a 9-year CALIPSO-derived pure dust product dataset was formed to explain horizontal and vertical distributions, transport heights and case incidences. The results indicated that the pure dust extinction coefficient increased as the location shifted from west to east. Moreover, in the same direction of west to east, the dominant spring months changed to summer and autumn. Mountain range systems surrounding Anatolia were the main obstacles against lofted and buoyant dust particles travelling to northern latitudes. Even if high ridges accumulated mass load on the southern slopes, they also enabled elevated particles to reach the ground level of the inner cities. [ABSTRACT FROM AUTHOR]

Published

2022

4. The Development of METAL-WRF Regional Model for the Description of Dust Mineralogy in the Atmosphere.

Author

Solomos, Stavros, Spyrou, Christos, Barreto, Africa, Rodríguez, Sergio, González, Yenny, Neophytou, Marina K. A., Mouzourides, Petros, Bartsotas, Nikolaos S., Kalogeri, Christina, Nickovic, Slobodan, Vukovic Vimic, Ana, Vujadinovic Mandic, Mirjam, Pejanovic, Goran, Cvetkovic, Bojan, Amiridis, Vassilis, Sykioti, Olga, Gkikas, Antonis, and Zerefos, Christos

Subjects

*DUST, *REGIONAL development, *MINERAL dusts, *MINERALOGY, *ATMOSPHERIC aerosols, *IRON, *DUST measurement

Abstract

The mineralogical composition of airborne dust particles is an important but often neglected parameter for several physiochemical processes, such as atmospheric radiative transfer and ocean biochemistry. We present the development of the METAL-WRF module for the simulation of the composition of desert dust minerals in atmospheric aerosols. The new development is based on the GOCART-AFWA dust module of WRF-Chem. A new wet deposition scheme has been implemented in the dust module alongside the existing dry deposition scheme. The new model includes separate prognostic fields for nine (9) minerals: illite, kaolinite, smectite, calcite, quartz, feldspar, hematite, gypsum, and phosphorus, derived from the GMINER30 database and also iron derived from the FERRUM30 database. Two regional model sensitivity studies are presented for dust events that occurred in August and December 2017, which include a comparison of the model versus elemental dust composition measurements performed in the North Atlantic (at Izaña Observatory, Tenerife Island) and in the eastern Mediterranean (at Agia Marina Xyliatos station, Cyprus Island). The results indicate the important role of dust minerals, as dominant aerosols, for the greater region of North Africa, South Europe, the North Atlantic, and the Middle East, including the dry and wet depositions away from desert sources. Overall, METAL-WRF was found to be capable of reproducing the relative abundances of the different dust minerals in the atmosphere. In particular, the concentration of iron (Fe), which is an important element for ocean biochemistry and solar absorption, was modeled in good agreement with the corresponding measurements at Izaña Observatory (22% overestimation) and at Agia Marina Xyliatos site (4% overestimation). Further model developments, including the implementation of newer surface mineralogical datasets, e.g., from the NASA-EMIT satellite mission, can be implemented in the model to improve its accuracy. [ABSTRACT FROM AUTHOR]

Published

2023

5. Fully Dynamic High–Resolution Model for Dispersion of Icelandic Airborne Mineral Dust.

Author

Cvetkovic, Bojan, Dagsson-Waldhauserová, Pavla, Petkovic, Slavko, Arnalds, Ólafur, Madonna, Fabio, Proestakis, Emmanouil, Gkikas, Antonis, Vukovic Vimic, Ana, Pejanovic, Goran, Rosoldi, Marco, Ceburnis, Darius, Amiridis, Vassilis, Lisá, Lenka, Nickovic, Slobodan, and Nikolic, Jugoslav

Subjects

*MINERAL dusts, *DUST, *PARTICULATE matter, *AIR quality, *DYNAMIC models, *PARTICLE size distribution, *DISPERSION (Chemistry)

Abstract

Icelandic topsoil sediments, as confirmed by numerous scientific studies, represent the largest and the most important European source of mineral dust. Strong winds, connected with the intensive cyclonic circulation in the North Atlantic, induce intense emissions of mineral dust from local sources all year and carry away these fine aerosol particles for thousands of kilometers. Various impacts of airborne mineral dust particles on local air quality, human health, transportation, climate and marine ecosystems motivated us to design a fully dynamic coupled atmosphere–dust numerical modelling system in order to simulate, predict and quantify the Icelandic mineral dust process including: local measurements and source specification over Iceland. In this study, we used the Dust Regional Atmospheric Model (DREAM) with improved Icelandic high resolution dust source specification and implemented spatially variable particle size distribution, variable snow cover and soil wetness. Three case studies of intense short- and long-range transport were selected to evaluate the model performance. Results demonstrated the model's capability to forecast major transport features, such as timing, and horizontal and vertical distribution of the processes. This modelling system can be used as an operational forecasting system, but also as a reliable tool for assessing climate and environmental Icelandic dust impacts. [ABSTRACT FROM AUTHOR]

Published

2022

6. Carbonaceous Aerosols in Contrasting Atmospheric Environments in Greek Cities: Evaluation of the EC-tracer Methods for Secondary Organic Carbon Estimation.

Author

Kaskaoutis, Dimitris G., Grivas, Georgios, Theodosi, Christina, Tsagkaraki, Maria, Paraskevopoulou, Despina, Stavroulas, Iasonas, Liakakou, Eleni, Gkikas, Antonis, Hatzianastassiou, Nikolaos, Wu, Cheng, Gerasopoulos, Evangelos, and Mihalopoulos, Nikolaos

Subjects

*CARBONACEOUS aerosols, *ATMOSPHERIC aerosols, *BIOMASS burning, *WOOD combustion, *ATMOSPHERIC composition, *EVALUATION methodology

Abstract

This study examines the carbonaceous-aerosol characteristics at three contrasting urban environments in Greece (Ioannina, Athens, and Heraklion), on the basis of 12 h sampling during winter (January to February 2013), aiming to explore the inter-site differences in atmospheric composition and carbonaceous-aerosol characteristics and sources. The winter-average organic carbon (OC) and elemental carbon (EC) concentrations in Ioannina were found to be 28.50 and 4.33 µg m−3, respectively, much higher than those in Heraklion (3.86 µg m−3 for OC and 2.29 µg m−3 for EC) and Athens (7.63 µg m−3 for OC and 2.44 µg m−3 for EC). The winter OC/EC ratio in Ioannina (6.53) was found to be almost three times that in Heraklion (2.03), indicating a larger impact of wood combustion, especially during the night, whereas in Heraklion, emissions from biomass burning were found to be less intense. Estimations of primary and secondary organic carbon (POC and SOC) using the EC-tracer method, and specifically its minimum R-squared (MRS) variant, revealed large differences between the sites, with a prevalence of POC (67–80%) in Ioannina and Athens and with a larger SOC fraction (53%) in Heraklion. SOC estimates were also obtained using the 5% and 25% percentiles of the OC/EC data to determine the (OC/EC)pri, leading to results contrasting to the MRS approach in Ioannina (70–74% for SOC). Although the MRS method provides generally more robust results, it may significantly underestimate SOC levels in environments highly burdened by biomass burning, as the fast-oxidized semi-volatile OC associated with combustion sources is classified in POC. Further analysis in Athens revealed that the difference in SOC estimates between the 5% percentile and MRS methods coincided with the semi-volatile oxygenated organic aerosol as quantified by aerosol mass spectrometry. Finally, the OC/Kbb+ ratio was used as tracer for decomposition of the POC into fossil-fuel and biomass-burning components, indicating the prevalence of biomass-burning POC, especially in Ioannina (77%). [ABSTRACT FROM AUTHOR]

Published

2020

7. A Decade of Aerosol Optical Properties Measurements over Athens, Greece.

Author

Raptis, Ioannis-Panagiotis, Kazadzis, Stelios, Amiridis, Vassilis, Gkikas, Antonis, Gerasopoulos, Evangelos, and Mihalopoulos, Nikolaos

Subjects

*OPTICAL measurements, *ATMOSPHERIC boundary layer, *CLIMATOLOGY, *AEROSOLS, *OPTICAL properties, *BIOMASS burning, *CARBONACEOUS aerosols

Abstract

Long-term ground-based measurements of aerosol optical properties in Athens, Greece, for the period 2008–2018 performed by the National Observatory of Athens are used in order to investigate the aerosol climatology of the area. In this study, we utilize quality-assured measurements of the aerosol optical depth (AOD), Single Scattering Albedo (SSA) and Ångström exponent obtained by CIMEL photometers in the framework of the Aerosol Robotic Network (AERONET) to extract the seasonality and the trends of aerosols in the region. Higher aerosol loads are found during spring and summer months. A 1.1% per year decrease for AOD at 440 nm and 0.4% decrease per year for SSA during the studied period are recorded. Collocated and synchronous PM10 values, for a five-year period, are used in order to study ground-level conditions. Also, the Planetary Boundary Layer Height from ERA-5 is used to investigate the stratification of the particles. The classification of aerosols using AERONET data is performed to separate dust, biomass burning, polluted urban, marine and continental dominant aerosol mixtures. Also, the characterization of AOD provided by Copernicus Atmosphere Monitoring Service (CAMS) is investigated. Finally, seasonal AOD trends recorded from AERONET from satellite sensors (MODIS-Aqua/MODIS-Terra) and estimated by CAMS are examined, and significant differences have been found. [ABSTRACT FROM AUTHOR]

Published

2020

8. A Climatological Satellite Assessment of Absorbing Carbonaceous Aerosols on a Global Scale.

Author

Hatzianastassiou, Nikolaos, Kalaitzi, Nikoleta, Gavrouzou, Maria, Gkikas, Antonis, Korras-Carraca, Marios-Bruno, and Mihalopoulos, Nikolaos

Subjects

*CARBONACEOUS aerosols, *BIOMASS burning, *TROPICAL forests, *TAIGAS, *REMOTE-sensing images, *CITIES & towns

Abstract

A global climatology of absorbing carbonaceous aerosols (ACA) for the period 2005–2015 is obtained by using satellite MODIS (Moderate Resolution Imaging Spectroradiometer)-Aqua and OMI (Ozone Monitoring Instrument)-Aura aerosol optical properties and by applying an algorithm. The algorithm determines the frequency of presence of ACA (black and brown carbon) over the globe at 1° × 1° pixel level and on a daily basis. The results of the algorithm indicate high frequencies of ACA (up to 19 days/month) over world regions with extended biomass burning, such as the tropical forests of southern and central Africa, South America and equatorial Asia, over savannas, cropland areas or boreal forests, as well as over urban and rural areas with intense anthropogenic activities, such as the eastern coast of China or the Indo-Gangetic plain. A clear seasonality of the frequency of occurrence of ACA is evident, with increased values during June–October over southern Africa, during July–November over South America, August–November over Indonesia, November–March over central Africa and November–April over southeastern Asia. The estimated seasonality of ACA is in line with the known annual patterns of worldwide biomass-burning emissions, while other features such as the export of carbonaceous aerosols from southern Africa to the southeastern Atlantic Ocean are also successfully reproduced by the algorithm. The results indicate a noticeable interannual variability and tendencies of ACA over specific world regions during 2005–2015, such as statistically significant increasing frequency of occurrence over southern Africa and eastern Asia. [ABSTRACT FROM AUTHOR]

Published

2019

9. From Tropospheric Folding to Khamsin and Foehn Winds: How Atmospheric Dynamics Advanced a Record-Breaking Dust Episode in Crete.

Author

Solomos, Stavros, Kalivitis, Nikos, Mihalopoulos, Nikos, Amiridis, Vassilis, Kouvarakis, Giorgos, Gkikas, Antonis, Binietoglou, Ioannis, Tsekeri, Alexandra, Kazadzis, Stelios, Kottas, Michael, Pradhan, Yaswant, Proestakis, Emmanouil, Nastos, Panagiotis T., and Marenco, Franco

Subjects

*TROPOSPHERE, *FOHN, *ATMOSPHERIC models, *SURFACE contamination, *ATMOSPHERIC circulation

Abstract

A record-breaking dust episode took place in Crete on 22 March 2018. The event was characterized by surface concentrations exceeding 1 mg m−3 for a period of 4–7 h, reaching record values higher than 6 mg m−3 at the background station of Finokalia. We present here a detailed analysis of the atmospheric dynamical processes during this period, to identify the main reasons for such extreme dust advection over Crete. At the synoptic scale, the weakening of the polar vortex and the meridional transport of polar air masses at upper tropospheric layers resulted in a strong jet streak over north Africa and Central Mediterranean and corresponding tropospheric folding that brought cold stratospheric air in mid and upper troposphere. Cyclogenesis occurred at the Gulf of Sirte in Libya, resulting in strong winds over the north-east parts of Libya, enhancing particle emissions. The dust plume traveled at low altitude (0.5–3 km) along the warm conveyor belt preceding the depression cold front. This type of dusty southerly wind is commonly known as “Khamsin”. As the flow approached Crete, Foehn winds at the lee side of the island favored the downward mixing of dust towards the surface, resulting in local maxima of PM10 in Heraklion and Finokalia. The analysis is based on the combination of high-resolution WRF-Chem simulations reaching up to 1 × 1 km grid space over Crete, ground-based and satellite remote sensing of the dust plumes (PollyXT LiDAR, MSG-SEVIRI, MODIS) and detailed surface aerosol in situ measurements at urban (Heraklion, Chania, Greece) and background (Finokalia) stations in Crete. [ABSTRACT FROM AUTHOR]

Published

2018