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#Arctic #Ny-Alesund #polarmoon #polarmoon #Arctic #Ny-Alesund #polarmoon #PolarRegions #PolarRegions ?ngström exponent absorption Angstrom coefficient absorption coefficients ACTRIS AERONET AERONET-cimel aerosol aerosol characterization aerosol climatology aerosol concentration aerosol events aerosol hygroscopicity aerosol inversion Aerosol model validation aerosol optical depth aerosol optical properties Aerosol particles aerosol pollen event aerosol products aerosol profiles Aerosol Properties Aerosol radiative effects aerosol radiative properties Aerosol vertical distribution Aerosol vertical profiles Aerosols Aerosols; Atmospheric optics agua precipitable AI Air mass back trajectories Air pollution air quality index aircraft algorithms all-sky camera Angstrom Exponent annual cycle Antarctic Antarctica AOD Arctic Arctic Haze Arctic pollution artic ash-sulphuric interactions asymptotic theory athmospheric aerosols atmosphere Atmospheric Aerosol atmospheric aerosols atmospheric composition Atmospheric correction atmospheric gases aureole scans Australian fires balloon-borne measurements biomass burning Biomass burning urban industrial Black carbon brazil Brewer BSRN caecenet caelis calibration Calibration Facility calibration transfer Calitoo sunphotometer campaign CAMS Caribbean area ceilometer Ceilometer data pre-processing ciclo anual CIMEL climatology cloud cover cloud effect efficiency (CEE) cloud effects on solar radiation (CRE) at surface cloud modification factor cloud optical depth (COD) cloud radiative effect clouds CNN Coarse and fine modes COCCON COCCON-España Columnar aerosol data Columnar and surface aerosols columnar optical properties Comparison convolutional neural network cuba Cumbre Vieja volcanic eruption cumulus and stratocumulus desert dust desert mineral dust didáctica diffuse dimming/brightening direct radiation discrete ordinate method doppler Double tropopause events DSCOVR dust dust episodes early instrumental data efecto gloria EKO MS-711 spectroradiometer Enhancement effect EPIC ESA Europe European Artic fire Fires fotómetros solares FTIR GAME GAW GHG global analysis GNSS GPS GRASP GRASP algorithm greenhouse gases hand-held sunphotometer HDR High dynamic range High turbidity episodes higroscopicity hygroscopic icenet ICP-MS image analylis image identification in-situ insolation Integrated water vapor integrating sphere intercomparison inverse methods inversion inversion products IWV Izaña Izaña Atmospheric Observatory La Palma langley Langley ratio method LIDAR Light scattering Lightning LIME long-range transport long-term AOD observations long-term characterization long-term comparison long-term trends long-wave Longwave radiative effect lunar irradiance lunar photometry marambio matrix operator method matrix Riccati equations matrix-exponential Measurement Mediterranean campaign MEGEI-MAD meteorology microphysical properties microwave radiometer Microwave radiometry Mining exploitation model MODIS MODIS–AQUA Monte-Carlo method moon moon light polarization Morphological characterization of aerosol MPPD model multi-instrument analysis NAFDI Nanoparticles NDACC FTIR Nephelometer NILU-UV radiometer nubes nuevos métodos Ny-Alesund OMI optical properties Ozone ozone radiative forcing particle formation pbl PFR Phase center variations; GPS; Water vapor photometer photometer calibration photometry physical properties planetary bounday layer PM10 threshold polar polar aerosol Polar Regions polarization polarmoon POLARUBI pollutant pollution polynomials precipitable water vapour procesados pulmonary deposition PWV PWV; PWV; atmospheric water vapor content; diurnal regime; GPS PWV; GPS Quality Assurance Quality Control Radiation radiativa effect Radiative forcing Radiative transfer radiative transfer simulations radiometer radiometry radiosonde Radiosondes reanalysis reanalysis data remote sensing retrieval ROLO Saharan Air Layer Saharan mineral dust Satellite Satellite remote sensing SAUNA campaign Scattering searchlight seasonal trends SEM SEM-EDX sensor satellinte shortwave global horizontal irradiance SIOS sky camera sky images sky radiance SLOPE smoke smoke ageing Solar radiation sondeos Sourthwestern Europe Spain spectral direct irradiance spectrometry spectrophotometer spectroradiometer spectroscopy star photometry stars stellar photometry stratospheric aerosol stratospheric density Sulphur dioxide Sun photometer sun photometry sun-photometer Sun-sky photometer sun-sky photometry sunphotometer Surface and columnar aerosol data surface solar radiation Svalbard técnicas de aceleración computacional temperature tesis transferencia radiativa Transport Troposphere tropospheric aerosol ultraviolet radiation urban UV UV irradiance UV-visible irradiance UVI Vaisala ceilometer Validation vapor de agua Vegetation Index Vegetation monitoring volcanic aerosol volcanic eruption Volcanic sulphates Water vapor water vapour ZEN-R52 Radiometer zenith sky radiance

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2024
1.	Sandra Graßl; Christoph Ritter; Jonas Wilsch; Richard Herrmann; Lionel Doppler; Roberto Román From Polar Day to Polar Night: A Comprehensive Sun and Star Photometer Study of Trends in Arctic Aerosol Properties in Ny-Ålesund, Svalbard Journal Article In: Remote Sensing, vol. 16, no. 19, 2024, ISSN: 2072-4292. Abstract \| Links \| BibTeX \| Tags: aerosol optical depth, Angstrom Exponent, Arctic Haze, long-range transport, long-term AOD observations, polar aerosol, seasonal trends @article{Graßl2024, title = {From Polar Day to Polar Night: A Comprehensive Sun and Star Photometer Study of Trends in Arctic Aerosol Properties in Ny-Ålesund, Svalbard}, author = {Sandra Graßl and Christoph Ritter and Jonas Wilsch and Richard Herrmann and Lionel Doppler and Roberto Román}, url = {https://www.mdpi.com/2072-4292/16/19/3725}, doi = {10.3390/rs16193725}, issn = {2072-4292}, year = {2024}, date = {2024-07-22}, urldate = {2024-01-01}, journal = {Remote Sensing}, volume = {16}, number = {19}, abstract = {The climate impact of Arctic aerosols, like the Arctic Haze, and their origin are not fully understood. Therefore, long-term aerosol observations in the Arctic are performed. In this study, we present a homogenised data set from a sun and star photometer operated in the European Arctic, in Ny-Ålesund, Svalbard, of the 20 years from 2004–2023. Due to polar day and polar night, it is crucial to use observations of both instruments. Their data is evaluated in the same way and follows the cloud-screening procedure of AERONET. Additionally, an improved method for the calibration of the star photometer is presented. We found out, that autumn and winter are generally more polluted and have larger particles than summer. While the monthly median Aerosol Optical Depth (AOD) decreases in spring, the AOD increases significantly in autumn. A clear signal of large particles during the Arctic Haze can not be distinguished from large aerosols in winter. With autocorrelation analysis, we found that AOD events usually occur with a duration of several hours. We also compared AOD events with large-scale processes, like large-scale oscillation patterns, sea ice, weather conditions, or wildfires in the Northern Hemisphere but did not find one single cause that clearly determines the Arctic AOD. Therefore the observed optical depth is a superposition of different aerosol sources.}, keywords = {aerosol optical depth, Angstrom Exponent, Arctic Haze, long-range transport, long-term AOD observations, polar aerosol, seasonal trends}, pubstate = {published}, tppubtype = {article} } Close The climate impact of Arctic aerosols, like the Arctic Haze, and their origin are not fully understood. Therefore, long-term aerosol observations in the Arctic are performed. In this study, we present a homogenised data set from a sun and star photometer operated in the European Arctic, in Ny-Ålesund, Svalbard, of the 20 years from 2004–2023. Due to polar day and polar night, it is crucial to use observations of both instruments. Their data is evaluated in the same way and follows the cloud-screening procedure of AERONET. Additionally, an improved method for the calibration of the star photometer is presented. We found out, that autumn and winter are generally more polluted and have larger particles than summer. While the monthly median Aerosol Optical Depth (AOD) decreases in spring, the AOD increases significantly in autumn. A clear signal of large particles during the Arctic Haze can not be distinguished from large aerosols in winter. With autocorrelation analysis, we found that AOD events usually occur with a duration of several hours. We also compared AOD events with large-scale processes, like large-scale oscillation patterns, sea ice, weather conditions, or wildfires in the Northern Hemisphere but did not find one single cause that clearly determines the Arctic AOD. Therefore the observed optical depth is a superposition of different aerosol sources. Close https://www.mdpi.com/2072-4292/16/19/3725 doi:10.3390/rs16193725 Close
2023
2.	Celia Herrero del Barrio; David Mateos; Roberto Román; Ramiro González; Sara Herrero-Anta; Daniel González-Fernández; Abel Calle; Carlos Toledano; Victoria Eugenia Cachorro; Ángel Máximo De Frutos Baraja Analysis of Daytime and Night-Time Aerosol Optical Depth from Solar and Lunar Photometry in Valladolid (Spain) Journal Article In: Remote Sensing, vol. 15, no. 22, 2023, ISSN: 2072-4292. Abstract \| Links \| BibTeX \| Tags: aerosol climatology, aerosol optical depth, Angstrom Exponent, caelis, lunar photometry @article{rs15225362, title = {Analysis of Daytime and Night-Time Aerosol Optical Depth from Solar and Lunar Photometry in Valladolid (Spain)}, author = {Celia Herrero del Barrio and David Mateos and Roberto Román and Ramiro González and Sara Herrero-Anta and Daniel González-Fernández and Abel Calle and Carlos Toledano and Victoria Eugenia Cachorro and Ángel Máximo De Frutos Baraja}, url = {https://www.mdpi.com/2072-4292/15/22/5362}, doi = {10.3390/rs15225362}, issn = {2072-4292}, year = {2023}, date = {2023-01-01}, urldate = {2023-01-01}, journal = {Remote Sensing}, volume = {15}, number = {22}, abstract = {Aerosol optical depth (AOD) at night-time has become a hot topic in recent years due to the development of new instruments recording accurate ground-based lunar irradiance measurements, and the development of calibration methods and extraterrestrial irradiance models adapted to lunar photometry. This study uses all daytime and night-time AOD data available at Valladolid (Spain) from October 2016 to March 2022 in order to analyze its behavior and the added contribution of night data. The annual, monthly and daily AOD evolution is studied comparing daytime and night-time values and checking the correlation between them. For this purpose, the daily averages are computed, showing an annual pattern, with low AOD values throughout the year (mean value of AOD at 440 nm: 0.122), where winter months have the lower and summer the higher values, as observed in previous studies. All these AOD values are modulated by frequent desert dust events over the Iberian Peninsula, with a strong influence on daily and monthly mean values in February and March, where the strongest desert outbreaks occurred. The added new data confirm these results and the good correlation between daytime and night-time data. Also, a complete daily evolution is shown, observing that AOD and Ångström exponent (AE) mean values vary by only ±0.02 in 24 h, with a maximum value at 06:00 UTC and minimum at 18:00 UTC for both parameters.}, keywords = {aerosol climatology, aerosol optical depth, Angstrom Exponent, caelis, lunar photometry}, pubstate = {published}, tppubtype = {article} } Close Aerosol optical depth (AOD) at night-time has become a hot topic in recent years due to the development of new instruments recording accurate ground-based lunar irradiance measurements, and the development of calibration methods and extraterrestrial irradiance models adapted to lunar photometry. This study uses all daytime and night-time AOD data available at Valladolid (Spain) from October 2016 to March 2022 in order to analyze its behavior and the added contribution of night data. The annual, monthly and daily AOD evolution is studied comparing daytime and night-time values and checking the correlation between them. For this purpose, the daily averages are computed, showing an annual pattern, with low AOD values throughout the year (mean value of AOD at 440 nm: 0.122), where winter months have the lower and summer the higher values, as observed in previous studies. All these AOD values are modulated by frequent desert dust events over the Iberian Peninsula, with a strong influence on daily and monthly mean values in February and March, where the strongest desert outbreaks occurred. The added new data confirm these results and the good correlation between daytime and night-time data. Also, a complete daily evolution is shown, observing that AOD and Ångström exponent (AE) mean values vary by only ±0.02 in 24 h, with a maximum value at 06:00 UTC and minimum at 18:00 UTC for both parameters. Close https://www.mdpi.com/2072-4292/15/22/5362 doi:10.3390/rs15225362 Close
2021
3.	Barreto, A.; García, O.E.; Schneider, M.; García, R.D.; Hase, F.; Sepúlveda, E.; Almansa, A.F.; Cuevas, E.; Blumenstock, T. Spectral Aerosol Optical Depth and Angstrom Exponent From Ground-Based Fourier Transform Infrared Spectrometry Conference Innovation in Atmospheric Sciences Virtual Workshop Online, 2021. BibTeX \| Tags: aerosol optical depth, Angstrom Exponent, FTIR @conference{Barreto2021, title = {Spectral Aerosol Optical Depth and Angstrom Exponent From Ground-Based Fourier Transform Infrared Spectrometry}, author = {Barreto, A. and García, O.E. and Schneider, M. and García, R.D. and Hase, F. and Sepúlveda, E. and Almansa, A.F. and Cuevas, E. and Blumenstock, T.}, year = {2021}, date = {2021-05-18}, address = {Online}, organization = {Innovation in Atmospheric Sciences Virtual Workshop}, keywords = {aerosol optical depth, Angstrom Exponent, FTIR}, pubstate = {published}, tppubtype = {conference} } Close

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