Your search keyword '"Ferrare, Richard A."' showing total 3 results

1. Large-Eddy Simulations of Marine Boundary Layer Clouds Associated with Cold-Air Outbreaks during the ACTIVATE Campaign. Part II: Aerosol–Meteorology–Cloud Interaction

Author

Li, Xiang-Yu, Wang, Hailong, Chen, Jingyi, Endoe, Satoshi, Kirschler, Simon, Voigt, Christiane, Crosbie, Ewan C., Ziemba, Luke D., Painemal, David, Cairns, Brian, Hair, Johnathan W., Corral, Andrea F., Robinson, Claire E., Dadashazar, Hossein, Sorooshian, Armin, Chen, Gao, Ferrare, Richard Anthony, Kleb, Mary M., Liu, Hongyu, Moore, Richard H., Scarino, Amy Jo, Shook, Michael A., Shingler, Taylor J., Thornhill, Kenneth Lee, Tornow, Florian, Xiao, Heng, and Zeng, Xubin

Subjects

Atmospheric Science, Cloud forcing, Cloud microphysics, Cloud radiative effects

Abstract

Aerosol effects on micro/macrophysical properties of marine stratocumulus clouds over the western North Atlantic Ocean (WNAO) are investigated using in situ measurements and large-eddy simulations (LES) for two cold-air outbreak (CAO) cases (28 February and 1 March 2020) during the Aerosol Cloud Meteorology Interactions over the Western Atlantic Experiment (ACTIVATE). The LES is able to reproduce the vertical profiles of liquid water content (LWC), effective radius reff and cloud droplet number concentration Nc from fast cloud droplet probe (FCDP) in situ measurements for both cases. Furthermore, we show that aerosols affect cloud properties (Nc, reff, and LWC) via the prescribed bulk hygroscopicity of aerosols () and aerosol size distribution characteristics. Nc, reff, and liquid water path (LWP) are positively correlated to and aerosol number concentration (Na) while cloud fractional cover (CFC) is insensitive to and aerosol size distributions for the two cases. The realistic changes to aerosol size distribution (number concentration, width, and the geometrical diameter) with the same meteorology state allow us to investigate aerosol effects on cloud properties without meteorological feedback. We also use the LES results to evaluate cloud properties from two reanalysis products, ERA5 and MERRA-2. Compared to LES, the ERA5 is able to capture the time evolution of LWP and total cloud coverage within the study domain during both CAO cases while MERRA-2 underestimates them.

Published

2023

2. Aerosol-Cloud-Meteorology Interaction Airborne Field Investigations: Using Lessons Learned from the US West Coast in the Design of ACTIVATE off the US East Coast

Author

Sorooshian, Armin, Anderson, Bruce, Bauer, Susanne E., Braun, Rachel A., Cairns, Brian, Crosbie, Ewan, Dadashazar, Hossein, Diskin, Glenn, Ferrare, Richard, Flagan, Richard C., Hair, Johnathan, Hostetler, Chris, Jonsson, Haflidi H., Kleb, Mary M., Liu, Hongyu, MacDonald, Alexander B., McComiskey, Allison, Moore, Richard, Painemal, David, Russell, Lynn M., Seinfeld, John H., Shook, Michael, Smith, William L., Thornhill, Kenneth, Tselioudis, George, Wang, Hailong, Zeng, Xubin, Zhang, Bo, Ziemba, Luke, Zuidema, Paquita, and Naval Postgraduate School (U.S.)

Abstract

The article of record as published may be found at http://dx.doi.org/10.1175/BAMS-D-18-0100.1 We report on a multiyear set of airborne field campaigns (2005–16) off the California coast to examine aerosols, clouds, and meteorology, and how lessons learned tie into the upcoming NASA Earth Venture Suborbital (EVS-3) campaign: Aerosol Cloud meTeorology Interactions oVer the western ATlantic Experiment (ACTIVATE; 2019–23). The largest uncertainty in estimating global anthropogenic radiative forcing is associated with the interactions of aerosol particles with clouds, which stems from the variability of cloud systems and the multiple feedbacks that affect and hamper efforts to ascribe changes in cloud properties to aerosol perturbations. While past campaigns have been limited in flight hours and the ability to fly in and around clouds, efforts sponsored by the Office of Naval Research have resulted in 113 single aircraft flights (>500 flight hours) in a fixed region with warm marine boundary layer clouds. All flights used nearly the same payload of instruments on a Twin Otter to fly below, in, and above clouds, producing an unprecedented dataset. We provide here i) an overview of statistics of aerosol, cloud, and meteorological conditions encountered in those campaigns and ii) quantification of model-relevant metrics associated with aerosol–cloud interactions leveraging the high data volume and statistics. Based on lessons learned from those flights, we describe the pragmatic innovation in sampling strategy (dual-aircraft approach with combined in situ and remote sensing) that will be used in ACTIVATE to generate a dataset that can advance scientific understanding and improve physical parameterizations for Earth system and weather forecasting models, and for assessing next-generation remote sensing retrieval algorithms. NASA 80NSSC19K0442 Office of Naval Research N00014-11-1-0783 Office of Naval Research N00014-10-1-0811 Office of Naval Research N00014-10-1-0200 Office of Naval Research N00014-04-1-0118 Office of Naval Research N00014-16-1-2567 Office of Naval Research N00014-04-1-0018 Office of Naval Research N00014-08-1-0465 National Science Foundation AGS-1013423 National Science Foundation AGS-1008848 U.S. Department of Energy DE-AC05-76RLO1830

Published

2019

3. An overview of the ORACLES (ObseRvations of Aerosols above CLouds and their intEractionS) project: aerosol-cloud-radiation interactions in the southeast Atlantic basin

Author

Redemann, Jens, Wood, Robert, Zuidema, Paquita, Doherty, Sarah J., Luna, Bernadette, LeBlanc, Samuel E., Diamond, Michael S., Shinozuka, Yohei, Chang, Ian Y., Ueyama, Rei, Pfister, Leonhard, Ryoo, Ju-Mee, Dobracki, Amie N., da Silva, Arlindo M., Longo, Karla M., Kacenelenbogen, Meloe S., Flynn, Connor J., Pistone, Kristina, Knox, Nichola M., Piketh, Stuart J., Haywood, James M., Formenti, Paola, Mallet, Marc, Stier, Philip, Ackerman, Andrew S., Bauer, Susanne E., Fridlind, Ann M., Carmichael, Gregory R., Saide, Pablo E., Ferrada, Gonzalo A., Howell, Steven G., Freitag, Steffen, Cairns, Brian, Holben, Brent N., Knobelspiesse, Kirk D., Tanelli, Simone, L'Ecuyer, Tristan S., Dzambo, Andrew M., Sy, Ousmane O., McFarquhar, Greg M., Poellot, Michael R., Gupta, Siddhant, O'Brien, Joseph R., Nenes, Athanasios, Kacarab, Mary, Wong, Jenny P. S., Small-Griswold, Jennifer D., Thornhill, Kenneth L., Noone, David, Podolske, James R., Schmidt, K. Sebastian, Pilewskie, Peter, Chen, Hong, Cochrane, Sabrina P., Sedlacek, Arthur J., Lang, Timothy J., Stith, Eric, Segal-Rozenhaimer, Michal, Ferrare, Richard A., Burton, Sharon P., Hostetler, Chris A., Diner, David J., Seidel, Felix C., Platnick, Steven E., Myers, Jeffrey S., Meyer, Kerry G., Spangenberg, Douglas A., Maring, Hal, and Gao, Lan

Abstract

Southern Africa produces almost a third of the Earth's biomass burning (BB) aerosol particles, yet the fate of these particles and their influence on regional and global climate is poorly understood. ORACLES (ObseRvations of Aerosols above CLouds and their intEractionS) is a 5-year NASA EVS-2 (Earth Venture Suborbital-2) investigation with three intensive observation periods designed to study key atmospheric processes that determine the climate impacts of these aerosols. During the Southern Hemisphere winter and spring (June-October), aerosol particles reaching 3-5 km in altitude are transported westward over the southeast Atlantic, where they interact with one of the largest subtropical stratocumulus (Sc) cloud decks in the world. The representation of these interactions in climate models remains highly uncertain in part due to a scarcity of observational constraints on aerosol and cloud properties, as well as due to the parameterized treatment of physical processes. Three ORACLES deployments by the NASA P-3 aircraft in September 2016, August 2017, and October 2018 (totaling similar to 350 science flight hours), augmented by the deployment of the NASA ER-2 aircraft for remote sensing in September 2016 (totaling similar to 100 science flight hours), were intended to help fill this observational gap. ORACLES focuses on three fundamental science themes centered on the climate effects of African BB aerosols: (a) direct aerosol radiative effects, (b) effects of aerosol absorption on atmospheric circulation and clouds, and (c) aerosol-cloud microphysical interactions. This paper summarizes the ORACLES science objectives, describes the project implementation, provides an overview of the flights and measurements in each deployment, and highlights the integrative modeling efforts from cloud to global scales to address science objectives. Significant new findings on the vertical structure of BB aerosol physical and chemical properties, chemical aging, cloud condensation nuclei, rain and precipitation statistics, and aerosol indirect effects are emphasized, but their detailed descriptions are the subject of separate publications. The main purpose of this paper is to familiarize the broader scientific community with the ORACLES project and the dataset it produced.