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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.	Celia Herrero del Barrio; Roberto Román; Ramiro González; Alberto Cazorla; Marcos Herreras-Giralda; Juan Carlos Antuña-Sánchez; Francisco Molero; Francisco Navas-Guzmán; Antonio Serrano; María Ángeles Obregón; Yolanda Sola; Marco Pandolfi; Sara Herrero-Anta; Daniel González-Fernández; Jorge Muñiz-Rosado; David Mateos; Abel Calle; Carlos Toledano; Victoria E. Cachorro; Ángel M. de Frutos CAECENET: An automatic system processing photometer and ceilometer data from different networks to provide columnar and vertically-resolved aerosol properties Journal Article In: PloS one, vol. 19, no. 12, pp. e0311990, 2024. Links \| BibTeX \| Tags: aerosol, caecenet, ceilometer, Sun photometer @article{delBarrio2024h, title = {CAECENET: An automatic system processing photometer and ceilometer data from different networks to provide columnar and vertically-resolved aerosol properties}, author = {Celia Herrero del Barrio and Roberto Román and Ramiro González and Alberto Cazorla and Marcos Herreras-Giralda and Juan Carlos Antuña-Sánchez and Francisco Molero and Francisco Navas-Guzmán and Antonio Serrano and María Ángeles Obregón and Yolanda Sola and Marco Pandolfi and Sara Herrero-Anta and Daniel González-Fernández and Jorge Muñiz-Rosado and David Mateos and Abel Calle and Carlos Toledano and Victoria E. Cachorro and Ángel M. de Frutos}, doi = {10.1371/journal.pone.0311990}, year = {2024}, date = {2024-12-27}, urldate = {2024-12-27}, journal = {PloS one}, volume = {19}, number = {12}, pages = {e0311990}, publisher = {Public Library of Science San Francisco, CA USA}, keywords = {aerosol, caecenet, ceilometer, Sun photometer}, pubstate = {published}, tppubtype = {article} } Close doi:10.1371/journal.pone.0311990 Close
2.	S. Pulimeno; M. Mazzola; A. Lupi; V. Vitale; C. Toledano; N. Kouremeti; S. Kazadzis Assessing Sun-Photometer Performance: Insights from an Intercomparison Campaign in Valladolid, Spain Conference 2024 Annual Meeting of the European Meteorological Society (EMS 2024), 2-6 Sep 2024 Barcelona, Spain, 2024. BibTeX \| Tags: intercomparison, Sun photometer @conference{Pulimeno2024, title = {Assessing Sun-Photometer Performance: Insights from an Intercomparison Campaign in Valladolid, Spain}, author = {S. Pulimeno and M. Mazzola and A. Lupi and V. Vitale and C. Toledano and N. Kouremeti and S. Kazadzis}, year = {2024}, date = {2024-09-02}, urldate = {2024-09-02}, address = {Barcelona, Spain}, organization = {2024 Annual Meeting of the European Meteorological Society (EMS 2024), 2-6 Sep 2024}, keywords = {intercomparison, Sun photometer}, pubstate = {published}, tppubtype = {conference} } Close
2022
3.	Javier Vaquero-Martínez; André F. Bagorrilha; Manuel Antón; Juan C. Antuña-Marrero; Victoria E. Cachorro Comparison of CIMEL sun-photometer and ground-based GNSS integrated water vapor over south-western European sites Journal Article In: Atmospheric Research, vol. 275, pp. 106217, 2022, ISSN: 0169-8095. Abstract \| Links \| BibTeX \| Tags: Comparison, GNSS, Sun photometer, sun-photometer, Water vapor @article{Vaquero-Martínez2022, title = {Comparison of CIMEL sun-photometer and ground-based GNSS integrated water vapor over south-western European sites}, author = {Javier Vaquero-Martínez and André F. Bagorrilha and Manuel Antón and Juan C. Antuña-Marrero and Victoria E. Cachorro}, url = {https://www.sciencedirect.com/science/article/pii/S0169809522002034}, doi = {https://doi.org/10.1016/j.atmosres.2022.106217}, issn = {0169-8095}, year = {2022}, date = {2022-09-01}, urldate = {2022-01-01}, journal = {Atmospheric Research}, volume = {275}, pages = {106217}, abstract = {This work analyzes the integrated water vapor (IWV) measured at six Aerosol Robotic Network (AERONET) stations with nearby global navigation satellite system (GNSS) in the Iberian Peninsula for the period 2007–2018. It is shown that both instruments have a high correlation (R2 > 0.91), with small mbe below 1.5 mm and standard deviation (SD) below 2 mm. However, some dependences have been observed when MBE and SD are represented in bins of three variables: IWV, solar zenith angle (SZA), and aerosol optical depth (AOD). The greater or lesser amount of water vapor in the atmosphere seemed to be the more influential variable, increasing dry bias and SD with increasing IWV. Moreover, high SZA values were related to SD increases. A clear seasonal cycle for Cimel–GNSS differences was observed which was mainly related to IWV seasonal cycle. Additionally, AOD did not show a remarkable influence on Cimel–GNSS differences. Finally, the monthly differences are also analyzed with metadata information about Cimel device ID numbers, showing that, for long-term studies, this information can be very valuable.}, keywords = {Comparison, GNSS, Sun photometer, sun-photometer, Water vapor}, pubstate = {published}, tppubtype = {article} } Close This work analyzes the integrated water vapor (IWV) measured at six Aerosol Robotic Network (AERONET) stations with nearby global navigation satellite system (GNSS) in the Iberian Peninsula for the period 2007–2018. It is shown that both instruments have a high correlation (R2 > 0.91), with small mbe below 1.5 mm and standard deviation (SD) below 2 mm. However, some dependences have been observed when MBE and SD are represented in bins of three variables: IWV, solar zenith angle (SZA), and aerosol optical depth (AOD). The greater or lesser amount of water vapor in the atmosphere seemed to be the more influential variable, increasing dry bias and SD with increasing IWV. Moreover, high SZA values were related to SD increases. A clear seasonal cycle for Cimel–GNSS differences was observed which was mainly related to IWV seasonal cycle. Additionally, AOD did not show a remarkable influence on Cimel–GNSS differences. Finally, the monthly differences are also analyzed with metadata information about Cimel device ID numbers, showing that, for long-term studies, this information can be very valuable. Close https://www.sciencedirect.com/science/article/pii/S0169809522002034 doi:https://doi.org/10.1016/j.atmosres.2022.106217 Close
4.	Juan Carlos Antuña-Marrero; Roberto Román; Victoria E. Cachorro; David Mateos; Carlos Toledano; Abel Calle; Juan Carlos Antuña-Sánchez; Javier Vaquero-Martínez; Manuel Antón; Ángel M. Frutos Baraja Integrated water vapor over the Arctic: Comparison between radiosondes and sun photometer observations Journal Article In: Atmospheric Research, vol. 270, pp. 106059, 2022, ISSN: 0169-8095. Abstract \| Links \| BibTeX \| Tags: AERONET, Arctic, Integrated water vapor, radiosonde, Sun photometer @article{Antuña-Marrero2022, title = {Integrated water vapor over the Arctic: Comparison between radiosondes and sun photometer observations}, author = {Juan Carlos Antuña-Marrero and Roberto Román and Victoria E. Cachorro and David Mateos and Carlos Toledano and Abel Calle and Juan Carlos Antuña-Sánchez and Javier Vaquero-Martínez and Manuel Antón and Ángel M. Frutos Baraja}, url = {https://www.sciencedirect.com/science/article/pii/S016980952200045X}, doi = {https://doi.org/10.1016/j.atmosres.2022.106059}, issn = {0169-8095}, year = {2022}, date = {2022-02-02}, urldate = {2022-01-01}, journal = {Atmospheric Research}, volume = {270}, pages = {106059}, abstract = {The amplification of global warming because of the feedbacks associated with the increase in atmospheric moisture and the decrease in sea ice and snow cover in the Arctic is currently the focus of scientists, policy makers and society. The amplification of global warming is the response to increases in precipitation originally caused by climate change. Arctic predominant increases in specific humidity and precipitation have been documented by observations. In comparison, evapotranspiration in the Arctic is poorly known, in part, because the spatial and temporal sparsity of accurate in situ and remote sensing observations. Although more than 20 observations sites in the Arctic are available, where AERONET sun photometer integrated water vapor (IWV) measurements have been conducted, that information have been barely used. Here, we present a comparison of IWV observations from radiosondes and AERONET sun photometers at ten sites located across the Arctic with the goal to document the feasibility of that set of observations to contribute to the ongoing and future research on polar regions. Sun photometer IWV observations are averaged for three-time windows; 30 min, 6 and 24 h. The predominant dry bias of AERONET IWV observations with respect to radiosondes, identified at tropical and midlatitudes, is also present in the Arctic. The statistics of the comparison show robust results at eight of the ten sites, with precision and accuracy magnitudes below 8 and 2% respectively. The possible causes of the less robust results at the other two sites are discussed. In addition, the impact of selecting other temporal coincidence windows in the average sun photometer IWV used in the comparison were tested. Auto-correlation in diurnal sun photometer IWV could produce appreciable bias in the statistics used for the comparison. We suggest using only one pair of values per day, consisting in the daily mean IWV sun photometer and the IWV radiosonde observation value. This feature should be valid also for comparison of IWV from sun photometer and other instruments. Maximum 10% error level of IWV from sun photometer observations, when compared with radiosondes, have been found for the Arctic. It is in the same order of magnitude than at tropical and middle latitudes locations. It has been demonstrated the feasibility of AERONET IWV observations in the Arctic for research on this variable. AERONET standard instruments and its centralized-standard processing algorithm allow its IWV observations to be considered a relative standard dataset for the re-calibration of other instrumental IWV observations assuming radiosondes as the absolute standard dataset.}, keywords = {AERONET, Arctic, Integrated water vapor, radiosonde, Sun photometer}, pubstate = {published}, tppubtype = {article} } Close The amplification of global warming because of the feedbacks associated with the increase in atmospheric moisture and the decrease in sea ice and snow cover in the Arctic is currently the focus of scientists, policy makers and society. The amplification of global warming is the response to increases in precipitation originally caused by climate change. Arctic predominant increases in specific humidity and precipitation have been documented by observations. In comparison, evapotranspiration in the Arctic is poorly known, in part, because the spatial and temporal sparsity of accurate in situ and remote sensing observations. Although more than 20 observations sites in the Arctic are available, where AERONET sun photometer integrated water vapor (IWV) measurements have been conducted, that information have been barely used. Here, we present a comparison of IWV observations from radiosondes and AERONET sun photometers at ten sites located across the Arctic with the goal to document the feasibility of that set of observations to contribute to the ongoing and future research on polar regions. Sun photometer IWV observations are averaged for three-time windows; 30 min, 6 and 24 h. The predominant dry bias of AERONET IWV observations with respect to radiosondes, identified at tropical and midlatitudes, is also present in the Arctic. The statistics of the comparison show robust results at eight of the ten sites, with precision and accuracy magnitudes below 8 and 2% respectively. The possible causes of the less robust results at the other two sites are discussed. In addition, the impact of selecting other temporal coincidence windows in the average sun photometer IWV used in the comparison were tested. Auto-correlation in diurnal sun photometer IWV could produce appreciable bias in the statistics used for the comparison. We suggest using only one pair of values per day, consisting in the daily mean IWV sun photometer and the IWV radiosonde observation value. This feature should be valid also for comparison of IWV from sun photometer and other instruments. Maximum 10% error level of IWV from sun photometer observations, when compared with radiosondes, have been found for the Arctic. It is in the same order of magnitude than at tropical and middle latitudes locations. It has been demonstrated the feasibility of AERONET IWV observations in the Arctic for research on this variable. AERONET standard instruments and its centralized-standard processing algorithm allow its IWV observations to be considered a relative standard dataset for the re-calibration of other instrumental IWV observations assuming radiosondes as the absolute standard dataset. Close https://www.sciencedirect.com/science/article/pii/S016980952200045X doi:https://doi.org/10.1016/j.atmosres.2022.106059 Close

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