R. Foskinis, A. Nenes, A. Papayannis, P. Georgakaki, K. Eleftheriadis, S. Vratolis, M. Gini, M. Komppula, V. Vakkari, M. Tombrou, E. Bossioli, P. Kokkalis
{"title":"Towards reliable retrievals of cloud droplet number for non-precipitating planetary boundary layer clouds and their susceptibility to aerosol","authors":"R. Foskinis, A. Nenes, A. Papayannis, P. Georgakaki, K. Eleftheriadis, S. Vratolis, M. Gini, M. Komppula, V. Vakkari, M. Tombrou, E. Bossioli, P. Kokkalis","doi":"10.3389/frsen.2022.958207","DOIUrl":null,"url":null,"abstract":"Remote sensing has been a key resource for developing extensive and detailed datasets for studying and constraining aerosol-cloud-climate interactions. However, aerosol-cloud collocation challenges, algorithm limitations, as well as difficulties in unraveling dynamic from aerosol-related effects on cloud microphysics, have long challenged precise retrievals of cloud droplet number concentrations. By combining a series of remote sensing techniques and in situ measurements at ground level, we developed a semi-automated approach that can address several retrieval issues for a robust estimation of cloud droplet number for non-precipitating Planetary Boundary Layer (PBL) clouds. The approach is based on satellite retrievals of the PBL cloud droplet number (N d sat ) using the geostationary meteorological satellite data of the Optimal Cloud Analysis (OCA) product, which is obtained by the Spinning Enhanced Visible and InfraRed Imager (SEVIRI) of the European Organization for the Exploitation of Meteorological Satellites (EUMETSAT). The parameters of the retrieval are optimized through closure with droplet number obtained from a combination of ground-based remote sensing data and in situ observations at ground level. More specifically, the remote sensing data are used to retrieve cloud-scale vertical velocity, and the in situ aerosol measurements at ground level were used constrain as input to a state-of-the-art droplet activation parameterization to predict the respective Cloud Condensation Nuclei (CCN) spectra, cloud maximum supersaturation and droplet number concentration (N d ), accounting for the effects of vertical velocity distribution and lateral entrainment. Closure studies between collocated N d and N d sat are then used to evaluate exising droplet spectral width parameters used for the retrieval of droplet number, and determine the optimal values for retrieval. This methodology, used to study aerosol-cloud interactions for non-precipitating clouds formed over the Athens Metropolitan Area (AMA), Greece from March to May 2020, shows that droplet closure can be achieved to within 30%, comparable to the level of closure obtained in many in situ studies. Given this, the ease of applying this approach with satellite data obtained from SEVIRI with high temporal (15 min) and spatial resolution (3.6 km × 4.6 km), opens the possibility of continuous and reliable N d sat , giving rise to high value datasets for aerosol-cloud-climate interaction studies.","PeriodicalId":198378,"journal":{"name":"Frontiers in Remote Sensing","volume":null,"pages":null},"PeriodicalIF":0.0000,"publicationDate":"2022-12-08","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"1","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"Frontiers in Remote Sensing","FirstCategoryId":"1085","ListUrlMain":"https://doi.org/10.3389/frsen.2022.958207","RegionNum":0,"RegionCategory":null,"ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"","JCRName":"","Score":null,"Total":0}
引用次数: 1
Abstract
Remote sensing has been a key resource for developing extensive and detailed datasets for studying and constraining aerosol-cloud-climate interactions. However, aerosol-cloud collocation challenges, algorithm limitations, as well as difficulties in unraveling dynamic from aerosol-related effects on cloud microphysics, have long challenged precise retrievals of cloud droplet number concentrations. By combining a series of remote sensing techniques and in situ measurements at ground level, we developed a semi-automated approach that can address several retrieval issues for a robust estimation of cloud droplet number for non-precipitating Planetary Boundary Layer (PBL) clouds. The approach is based on satellite retrievals of the PBL cloud droplet number (N d sat ) using the geostationary meteorological satellite data of the Optimal Cloud Analysis (OCA) product, which is obtained by the Spinning Enhanced Visible and InfraRed Imager (SEVIRI) of the European Organization for the Exploitation of Meteorological Satellites (EUMETSAT). The parameters of the retrieval are optimized through closure with droplet number obtained from a combination of ground-based remote sensing data and in situ observations at ground level. More specifically, the remote sensing data are used to retrieve cloud-scale vertical velocity, and the in situ aerosol measurements at ground level were used constrain as input to a state-of-the-art droplet activation parameterization to predict the respective Cloud Condensation Nuclei (CCN) spectra, cloud maximum supersaturation and droplet number concentration (N d ), accounting for the effects of vertical velocity distribution and lateral entrainment. Closure studies between collocated N d and N d sat are then used to evaluate exising droplet spectral width parameters used for the retrieval of droplet number, and determine the optimal values for retrieval. This methodology, used to study aerosol-cloud interactions for non-precipitating clouds formed over the Athens Metropolitan Area (AMA), Greece from March to May 2020, shows that droplet closure can be achieved to within 30%, comparable to the level of closure obtained in many in situ studies. Given this, the ease of applying this approach with satellite data obtained from SEVIRI with high temporal (15 min) and spatial resolution (3.6 km × 4.6 km), opens the possibility of continuous and reliable N d sat , giving rise to high value datasets for aerosol-cloud-climate interaction studies.
遥感已成为开发用于研究和限制气溶胶-云-气候相互作用的广泛而详细的数据集的关键资源。然而,气溶胶与云的搭配挑战、算法限制,以及从气溶胶相关的云微物理效应中揭示动态的困难,长期以来一直挑战着云滴数浓度的精确检索。通过结合一系列遥感技术和地面现场测量,我们开发了一种半自动方法,可以解决几个检索问题,以可靠地估计非降水行星边界层(PBL)云的云滴数。该方法基于利用欧洲气象卫星开发组织(EUMETSAT)的旋转增强可见光和红外成像仪(SEVIRI)获得的最优云分析(OCA)产品的地球静止气象卫星数据对PBL云滴数(N d sat)的卫星检索。通过结合地面遥感数据和地面现场观测得到的液滴数,优化了反演参数。更具体地说,遥感数据用于检索云尺度垂直速度,并将地面的原位气溶胶测量作为最先进的液滴激活参数化的输入,以预测各自的云凝结核(CCN)光谱、云最大过饱和度和液滴数浓度(N d),考虑垂直速度分布和横向夹杂的影响。并置的N d和N d sat之间的闭合研究用于评估用于检索液滴数的现有液滴光谱宽度参数,并确定检索的最佳值。该方法用于研究2020年3月至5月希腊雅典大都会区(AMA)上空形成的非降水云的气溶胶-云相互作用,结果表明,液滴的封闭程度可以达到30%以内,与许多原位研究中获得的封闭水平相当。鉴于此,将这种方法应用于SEVIRI获得的高时间(15分钟)和高空间分辨率(3.6 km × 4.6 km)的卫星数据的易用性,开启了连续和可靠的N d卫星的可能性,为气溶胶-云-气候相互作用研究提供了高价值的数据集。