Search

Your search keyword '"Skofronick-Jackson, Gail"' showing total 170 results
Start Over Author "Skofronick-Jackson, Gail"

Refine your results

more »

more »

more »

more »
170 results on '"Skofronick-Jackson, Gail"'

1. Chasing Snowstorms : The Investigation of Microphysics and Precipitation for Atlantic Coast-Threatening Snowstorms (IMPACTS) Campaign

Author

McMurdie, Lynn A., Heymsfield, Gerald M., Yorks, John E., Braun, Scott A., Skofronick-Jackson, Gail, Rauber, Robert M., Yuter, Sandra, Colle, Brian, McFarquhar, Greg M., Poellot, Michael, Novak, David R., Lang, Timothy J., Kroodsma, Rachael, McLinden, Matthew, Oue, Mariko, Kollias, Pavlos, Kumjian, Matthew R., Greybush, Steven J., Heymsfield, Andrew J., Finlon, Joseph A., McDonald, Victoria L., and Nicholls, Stephen

Published
2022

2. The Global Precipitation Measurement (GPM) Mission

Author

Kidd, Christopher, Takayabu, Yukari N., Skofronick-Jackson, Gail M., Huffman, George J., Braun, Scott A., Kubota, Takuji, Turk, F. Joseph, Stoffel, Markus, Series Editor, Cramer, Wolfgang, Advisory Editor, Luterbacher, Urs, Advisory Editor, Toth, F., Advisory Editor, Levizzani, Vincenzo, editor, Kidd, Christopher, editor, Kirschbaum, Dalia B., editor, Kummerow, Christian D., editor, Nakamura, Kenji, editor, and Turk, F. Joseph, editor

Published
2020
Full Text
View/download PDF

6. Advanced Concepts on Remote Sensing of Precipitation at Multiple Scales

Author

Sorooshian, Soroosh, AghaKouchak, Amir, Arkin, Phillip, Eylander, John, Foufoula-Georgiou, Efi, Harmon, Russell, Hendrickx, Jan M. H, Imam, Bisher, Kuligowski, Robert, Skahill, Brian, and Skofronick-Jackson, Gail

Subjects
data sets, extreme events, extreme precipitation, false alarm ratio, global coverage, high spatial resolution, new sources, PERSIANN, precipitation extremes, precipitation products, reference data, reliable estimates, satellite products, water resources management
Published
2011

7. Advancing the Remote Sensing of Precipitation

Author

Sorooshian, Soroosh, AghaKouchak, Amir, Arkin, Phillip, Eylander, John, Foufoula-Georgiou, Efi, Harmon, Russell, Hendrickx, Jan MH, Imam, Bisher, Kuligowski, Robert, Skahill, Brian, and Skofronick-Jackson, Gail

Subjects
Astronomical and Space Sciences, Atmospheric Sciences, Physical Geography and Environmental Geoscience, Meteorology & Atmospheric Sciences
Abstract

Satellite-based global precipitation data has addressed the limitations of rain gauges and weather radar systems in forecasting applications and for weather and climate studies. Inspite of this ability, a number of issues that require the development of advanced concepts to address key challenges in satellite-based observations of precipitation were identified during the Advanced Concepts Workshop on Remote Sensing of Precipitation at Multiple Scales at the University of California. These include quantification of uncertainties of individual sensors and their propagation into multisensor products warrants a great deal of research. The development of metrics for validation and uncertainty analysis are of great importance. Bias removal, particularly probability distribution function (PDF)-based adjustment, deserves more in-depth research. Development of a near-real-time probabilistic uncertainty model for satellitebased precipitation estimates is highly desirable.

Published
2011

8. THE GLOBAL PRECIPITATION MEASUREMENT (GPM) MISSION FOR SCIENCE AND SOCIETY

Author

Skofronick-Jackson, Gail, Petersen, Walter A., Berg, Wesley, Kidd, Chris, Stocker, Erich F., Kirschbaum, Dalia B., Kakar, Ramesh, Braun, Scott A., Huffman, George J., Iguchi, Toshio, Kirstetter, Pierre E., Kummerow, Christian, Meneghini, Robert, Oki, Riko, Olson, William S., Takayabu, Yukari N., Furukawa, Kinji, and Wilheit, Thomas

Published
2017

11. The Joint Aeolus Tropical Atlantic Campaign 2021/2022 Overview– Atmospheric Science and Satellite Validation in the Tropics

Author

Fehr, Thorsten, primary, McCarthy, Will, additional, Amiridis, Vassilis, additional, Baars, Holger, additional, von Bismarck, Jonas, additional, Borne, Maurus, additional, Chen, Shuyi, additional, Flamant, Cyrille, additional, Marenco, Franco, additional, Knipperz, Peter, additional, Koopman, Rob, additional, Lemmerz, Christian Lemmerz, additional, Marinou, Eleni, additional, Močnik, Griša, additional, Parrinello, Tommaso, additional, Piña, Aaron, additional, Reitebuch, Oliver, additional, Skofronick-Jackson, Gail, additional, Zawislak, Jonathan, additional, and Zenk, Cordula, additional

Published
2023
Full Text
View/download PDF

12. Convective Processes Experiment – Aerosol and Winds (CPEX-AW): Virtual and Field Campaigns

Author

Chen, Shuyi, primary, Mazza, Edoardo, additional, Savarin, Ajda, additional, Kerns, Brandon, additional, Zipser, Ed, additional, Hristova-Veleva, Svetla, additional, Sy, Ousmane, additional, Tanelli, Simone, additional, Su, Hu, additional, Kavaya, Michael, additional, Nehrir, Amin, additional, Pu, Zhaoxia, additional, and Skofronick-Jackson, Gail, additional

Published
2023
Full Text
View/download PDF

20. Successes with the Global Precipitation Measurement (GPM) Mission

Author

Skofronick-Jackson, Gail, Huffman, George, Stocker, Erich, and Petersen, Walter

Subjects
Meteorology And Climatology
Abstract

Water is essential to our planet Earth. Knowing when, where and how precipitation falls is crucial for understanding the linkages between the Earth's water and energy cycles and is extraordinarily important for sustaining life on our planet during climate change. The Global Precipitation Measurement (GPM) Core Observatory spacecraft launched February 27, 2014, is the anchor to the GPM international satellite mission to unify and advance precipitation measurements from a constellation of research and operational sensors to provide "next-generation" precipitation products. GPM is currently a partnership between NASA and the Japan Aerospace Exploration Agency (JAXA). Status and successes in terms of spacecraft, instruments, retrieval products, validation, and impacts for science and society will be presented. Precipitation, microwave, satellite

Published
2016

23. Performance of the Goddard Multiscale Modeling Framework with Goddard Ice Microphysical Schemes

Author

Chern, Jiun-Dar, Tao, Wei-Kuo, Lang, Stephen E, Matsui, Toshihisa, Li, J.-L, Mohr, Karen I, Skofronick-Jackson, Gail M, and Peters-Lidard, Christa D

Subjects
Meteorology And Climatology
Abstract

The multiscale modeling framework (MMF), which replaces traditional cloud parameterizations with cloud-resolving models (CRMs) within a host atmospheric general circulation model (GCM), has become a new approach for climate modeling. The embedded CRMs make it possible to apply CRM-based cloud microphysics directly within a GCM. However, most such schemes have never been tested in a global environment for long-term climate simulation. The benefits of using an MMF to evaluate rigorously and improve microphysics schemes are here demonstrated. Four one-moment microphysical schemes are implemented into the Goddard MMF and their results validated against three CloudSat/CALIPSO cloud ice products and other satellite data. The new four-class (cloud ice, snow, graupel, and frozen drops/hail) ice scheme produces a better overall spatial distribution of cloud ice amount, total cloud fractions, net radiation, and total cloud radiative forcing than earlier three-class ice schemes, with biases within the observational uncertainties. Sensitivity experiments are conducted to examine the impact of recently upgraded microphysical processes on global hydrometeor distributions. Five processes dominate the global distributions of cloud ice and snow amount in long-term simulations: (1) allowing for ice supersaturation in the saturation adjustment, (2) three additional correction terms in the depositional growth of cloud ice to snow, (3) accounting for cloud ice fall speeds, (4) limiting cloud ice particle size, and (5) new size-mapping schemes for snow and graupel. Despite the cloud microphysics improvements, systematic errors associated with subgrid processes, cyclic lateral boundaries in the embedded CRMs, and momentum transport remain and will require future improvement.

Published
2016
Full Text
View/download PDF

24. The Joint ESA-NASA Tropical Campaign Activity - Aeolus Calibration/Validation and Science in the Topics

Author

Fehr, Thorsten, Skofronick-Jackson, Gail, Amiridis, Vassilis, von Bismarck, Jonas, Chen, Shuyi, Flamant, Cyrille, Koopman, Rob, Lemmerz, Christian, Močnik, Griša, Parrinello, Tommaso, Piña, Aaron, Straume, Anne Grete, Earth Observation Programmes Directorate [Noordwijk], European Space Agency (ESA), NASA Science Mission Directorate (SMD), NASA, Institute for Astronomy, Astrophysics, Space Applications and Remote Sensing [Penteli] (IAASARS), National Observatory of Athens (NOA), Earth Observation Programmes Directorate [Frascati], Department of Atmospheric Sciences [Seattle], University of Washington [Seattle], TROPO - LATMOS, Laboratoire Atmosphères, Milieux, Observations Spatiales (LATMOS), Sorbonne Université (SU)-Université de Versailles Saint-Quentin-en-Yvelines (UVSQ)-Centre National de la Recherche Scientifique (CNRS)-Institut national des sciences de l'Univers (INSU - CNRS)-Sorbonne Université (SU)-Université de Versailles Saint-Quentin-en-Yvelines (UVSQ)-Centre National de la Recherche Scientifique (CNRS)-Institut national des sciences de l'Univers (INSU - CNRS), DLR Institut für Physik der Atmosphäre (IPA), Deutsches Zentrum für Luft- und Raumfahrt [Oberpfaffenhofen-Wessling] (DLR), and University of Nova Gorica

Subjects
[PHYS.PHYS.PHYS-AO-PH]Physics [physics]/Physics [physics]/Atmospheric and Oceanic Physics [physics.ao-ph]
Abstract

International audience; The Tropics are covering around 40% of the globe and are home to approximately 40% of the world population. However, numerical weather prediction (NWP) for this region still remains challenging due to the lack of basic observations and incomplete understanding of atmospheric processes, also affecting extratropical storm developments. As a result, the largest impact of the ESA’s Aeolus satellite observations on NWP is expected in the Tropics where only a very limited number of wind profile observations from the ground can be performed.An especially important case relating to the predictability of tropical weather system is the outflow of Saharan dust, its interaction with cloud micro-physics and the overall impact on the development of tropical storms over the Atlantic Ocean. The region of the coast of West Africa uniquely allows the study of the Saharan Aerosol layer, African Easterly Waves and Jets, Tropical Easterly Jet, as well as the deep convection in ITCZ and their relation to the formation of convective systems and the transport of dust.Together with international partners, ESA and NASA are currently implementing a joint Tropical campaign from July to August 2021 with its base in Cape Verde. The campaign objective is to provide information on the validation and preparation of the ESA missions Aeolus and EarthCARE, respectively, as well as supporting a range of related science objectives for the investigation in the interactions between African Easterly and other tropical waves with the mean flow, dust and their impact on the development of convective systems; the structure and variability of the marine boundary layer in relation to initiation and lifecycle of the convective cloud systems within and across the ITCZ; and impact of wind, aerosol, clouds, and precipitation effects on long range dust transport and air quality over the western Atlantic.The campaign comprises a unique combination of both strong airborne and ground-based elements collocated on Cape Verde. The airborne component with wind and aerosol lidars, cloud radars, in-situ instrumentation and additional observations includes the NASA DC-8 with science activities coordinated by the U. of Washington, the German DLR Falcon-20, the French Safire Falcon-20 with activities led by LATMOS, and the Slovenian Aerovizija Advantic WT-10 light aircraft in cooperation with the U. Novo Gorica. The ground-based component led by the National Observatory of Athens is a collaboration of more than 25 European teams providing in-situ and remote sensing aerosol and cloud measurements with a wide range of lidar, radar and radiometer systems, as well as drone observatins by the Cyprus Institute.In preparation for the field campaign, the NASA and ESA management and science teams are closely collaborating with regular coordination meetings, in particular in coordinating the shift of the activity by one year due to the COVID-19 pandemic. The time gained has been used to further consolidate the planning, and in particular with a dry-run campaign organized by NASA with European participation where six virtual flights were conducted in July 2020.

Published
2021
Full Text
View/download PDF

25. The Joint Aeolus Tropical Atlantic Campaign - First Results for Aeolus Calibration/Validation and Science in the Tropics

Author

Skofronick-Jackson, Gail, Fehr, Thorsten, Althausen, Dietrich, Amiridis, Vassilis, Baars, Holger, von Bismarck, Jonas, Borne, Maurus, Casal, Tânia, Cazenave, Quitterie, Chen, Shuyi, Engelmann, Ronny, Flamant, Cyrille, Gaetani, Marco, Geiß, Alexander, Gómez Maqueo Anaya, Sofia, Knipperz, Peter, Kollias, Pavlos, Koopman, Rob, Krisna, Trismono, Lemmerz, Christian, Lux, Oliver, Marinou, Eleni, Marksteiner, Uwe, Močnik, Griša, Nemuc, Anca, Parrinello, Tommaso, Paschou, Peristera, Piña, Aaron, Pirloaga, Razvan, Rahm, Stephan, Reitebuch, Oliver, Schäfler, Andreas, Siomos, Nikos, Skupin, Annett, Straume, Anne, Tran, Viet, Vaziri, Pouya, Wandinger, Ulla, Wehr, Tobias, Weiler, Fabian, Wernham, Denny, Witschas, Benjamin, Zenk, Cordula, Cardon, Catherine, NASA Science Mission Directorate (SMD), NASA, European Space Research and Technology Centre (ESTEC), European Space Agency (ESA), Leibniz Institute for Tropospheric Research (TROPOS), Institute for Astronomy, Astrophysics, Space Applications and Remote Sensing [Penteli] (IAASARS), National Observatory of Athens (NOA), European Space Research Institute (ESRIN), Karlsruhe Institute of Technology (KIT), TROPO - LATMOS, Laboratoire Atmosphères, Milieux, Observations Spatiales (LATMOS), Sorbonne Université (SU)-Université de Versailles Saint-Quentin-en-Yvelines (UVSQ)-Centre National de la Recherche Scientifique (CNRS)-Institut national des sciences de l'Univers (INSU - CNRS)-Sorbonne Université (SU)-Université de Versailles Saint-Quentin-en-Yvelines (UVSQ)-Centre National de la Recherche Scientifique (CNRS)-Institut national des sciences de l'Univers (INSU - CNRS), Department of Atmospheric Sciences [Seattle], University of Washington [Seattle], Istituto Universitario di Studi Superiori (IUSS), DLR Institut für Physik der Atmosphäre (IPA), Deutsches Zentrum für Luft- und Raumfahrt [Oberpfaffenhofen-Wessling] (DLR), University of Nova Gorica, National Institute of Research and Development for Optoelectronics (INOE), Agence Spatiale Européenne (ESA), and Helmholtz Centre for Ocean Research [Kiel] (GEOMAR)

Subjects
[PHYS.PHYS.PHYS-AO-PH]Physics [physics]/Physics [physics]/Atmospheric and Oceanic Physics [physics.ao-ph], [PHYS.PHYS.PHYS-AO-PH] Physics [physics]/Physics [physics]/Atmospheric and Oceanic Physics [physics.ao-ph]
Abstract

International audience; ESA’s Aeolus satellite observations are expected to have the biggest impact for the improvement of numerical weather prediction in the Tropics. An especially important case relating to the evolution, dynamics, and predictability of tropical weather systems is the outflow of Saharan dust, its interaction with cloud microphysics and impact on the development of tropical storms over the Atlantic Ocean. The Atlantic Ocean off the coast of West Africa and the eastern Caribbean uniquely allows the study of the Saharan Aerosol layer, African Easterly Waves and Jet, Tropical Easterly Jet, as well as the deep convection in the Intertropical Convergence Zone and their relation to the formation of convective systems, and the long-range transport of dust and its impact on air quality. The Joint Aeolus Tropical Atlantic Campaign (JATAC) deployed on Cabo Verde and the US Virgin Islands is addressing the validation and preparation of the ESA missions Aeolus, EarthCARE and WIVERN, as well as supporting the related science objectives raised above. The JATAC campaign started in July 2021 with the deployment of ground-based instruments at the Ocean Science Center Mindelo (OSCM, Cabo Verde), including the EVE lidar, the PollyXT lidar, a W-band Doppler cloud radar and a sunphotometer. By mid-August, the CPEX-AW campaign started their operations from the US Virgin Islands with NASA’s DC-8 flying laboratory in the Western Tropical Atlantic and Caribbean with the Doppler Aerosol Wind Lidar (DAWN), Airborne Precipitation and Cloud Radar (APR-3), the Water Vapor DIAL and HSRL (HALO), a microwave sounder (HAMSR) and dropsondes. In September, a European aircraft fleet was deployed to Sal (Cabo Verde) with the DLR Falcon-20 carrying the Aeolus Airborne Demonstrator (A2D) and the 2-µm Doppler wind lidar, and the Safire Falcon-20 carrying the high-spectral-resolution Doppler lidar (LNG), the RASTA Doppler cloud radar, in-situ cloud and aerosol instruments among others. The Aerovizija Advantic WT-10 light aircraft with filter-photometers and nephelometers for in-situ aerosol characterisation was operating in close coordination with the ground-based observations from Mindelo. More than 35 flights of the four aircraft were performed. 17 Aeolus orbits were underflown, four of which completed by simultaneous observations of three aircraft, with a perfect collocation of Aeolus and the ground-based observation for two cases. Several flights by the NASA DC-8 and the Safire Falcon-20 have been dedicated to cloud microphysics and dust events. The EVE lidar has been operating on a regular basis, while the PollyXT and several other ground-based instruments were continuously operating during the campaign period. For further characterisation of the atmosphere, radiosondes were launched up to twice daily from Sal airport. Additionally, there were radiosonde launches from western Puerto Rico and northern St Croix, US Virgin Islands. The JATAC was supported by dedicated numerical weather and dust simulations supporting the forecasting efforts needed for successful planning of the flights and addressing open science questions. While the airborne activities were completed end September, the ground-based observations are continuing into 2022. The paper will present an overview and initial results of JATAC. In memory of our colleague and friend Gail.

Published
2021

26. Update on Activities of the U.S. National Academies' Committee on Radio Frequencies

Author

Moghaddam, Mahta, primary, Van Zee, Liese, additional, Livesey, Nathaniel, additional, Gergely, Tomas, additional, Baker, Nancy, additional, Emerson, Darrel, additional, Emerv, William, additional, Entekhabi, Dara, additional, Erickson, Philip J., additional, Johnson, Kelsey, additional, Masters, Karen, additional, Paine, Scott, additional, Schinzel, Frank, additional, and Skofronick-Jackson, Gail, additional

Published
2021
Full Text
View/download PDF

27. Airborne lidar observations of wind, water vapor, and aerosol profiles during the NASA Aeolus calibration and validation (Cal/Val) test flight campaign

Author

Bedka, Kristopher M., primary, Nehrir, Amin R., additional, Kavaya, Michael, additional, Barton-Grimley, Rory, additional, Beaubien, Mark, additional, Carroll, Brian, additional, Collins, James, additional, Cooney, John, additional, Emmitt, G. David, additional, Greco, Steven, additional, Kooi, Susan, additional, Lee, Tsengdar, additional, Liu, Zhaoyan, additional, Rodier, Sharon, additional, and Skofronick-Jackson, Gail, additional

Published
2021
Full Text
View/download PDF

28. Aeolus Calibration, Validation and Science Post-Launch Campaigns

Author

Fehr, Thorsten, primary, Amiridis, Vassilis , additional, von Bismarck, Jonas, additional, Bley, Sebastian, additional, Flamant, Cyrille, additional, Hertzog, Albert, additional, Lemmerz, Christian, additional, Močnik, Griša, additional, Parrinello, Tommaso, additional, Skofronick-Jackson, Gail, additional, and Straume, Anne Grete, additional

Published
2021
Full Text
View/download PDF

29. The Joint ESA-NASA Tropical Campaign Activity – Aeolus Calibration/Validation and Science in the Topics

Author

Fehr, Thorsten, primary, Skofronick-Jackson, Gail, additional, Amiridis, Vassilis, additional, von Bismarck, Jonas, additional, Chen, Shuyi, additional, Flamant, Cyrille, additional, Koopman, Rob, additional, Lemmerz, Christian, additional, Močnik, Griša, additional, Parrinello, Tommaso, additional, Piña, Aaron, additional, and Straume, Anne Grete, additional

Published
2021
Full Text
View/download PDF

31. Extreme Lake-Effect Snow from a GPM Microwave Imager Perspective: Observational Analysis and Precipitation Retrieval Evaluation

Author

Milani, Lisa, primary, Kulie, Mark S., additional, Casella, Daniele, additional, Kirstetter, Pierre E., additional, Panegrossi, Giulia, additional, Petkovic, Veljko, additional, Ringerud, Sarah E., additional, Rysman, Jean-François, additional, Sanò, Paolo, additional, Wang, Nai-Yu, additional, You, Yalei, additional, and Skofronick-Jackson, Gail, additional

Published
2021
Full Text
View/download PDF

32. Intercomparison of millimeter-wave radiative transfer models

Author

Kim, Min-Jeong, Skofronick-Jackson, Gail M., and Weinman, James A.

Subjects
Remote sensing -- Research, Business, Earth sciences, Electronics and electrical industries
Abstract

This study analyzes the performance at millimeterwave frequencies of five radiative transfer models, i.e., the Eddington second-order approximation with and without [delta]-scaling, the Neumann iterative method with and without geometric series approximation, and the Monte Carlo method. Three winter time precipitation profiles are employed. The brightness temperatures calculated by the Monte Carlo method, which considers all scattering angles, are considered as benchmarks in this study. Brightness temperature differences generated by the other models and sources of those differences are examined. In addition, computation speeds of the radiative transfer calculations are also compared. Results show that the required number of quadrature angles to generate brightness temperatures consistent with the Monte Carlo method within 0.5 K varies between two and six. At least second to 15th orders of multiple scattering, depending on the significance of scattering, are required for the Neumann iterative method to represent accurately the inhomogeneous vertical structure of the scattering and absorbing components of precipitating clouds at millimeter-wave frequencies. The [delta]-scaling in the Eddington second-order approximation improves brightness temperatures significantly at nadir for cloud profiles that contain snow due to the correction for strong scattering, while it did not make any difference at 53 [degrees] off-nadir. The computational time comparisons show that the Neumann iterative method generates accurate brightness temperatures with better computational efficiency than the Monte Carlo method for cloud profiles with weak scattering. However, it can consume computational time that is even greater than the Monte Carlo method for some millimeter-wave frequencies and cloud profiles with strong scattering. A geometric series approximation can improve computational efficiency of the Neumann iterative method for those profiles. In view of the ease of introducing scaled parameters into the Eddington second-order approximation, good computational time efficiency, and better than within 2 K accuracy when compared with the Monte Carlo method, we recommend its use for brightness temperature calculations at millimeter-waves in precipitating atmospheres. Index Terms--Delta-scaling, Eddington second-order approximation, millimeter-wave, Monte Carlo method, Neumann iterative method, radiative transfer model.

Published
2004

33. A physical model to determine snowfall over land by microwave radiometry

Author

Skofronick-Jackson, Gail M., Kim, Min-Jeong, Weinman, James A., and Chang, Dong-Eon

Subjects
Microwave devices -- Usage, Remote sensing -- Usage, Snow -- Observations, Radiation -- Measurement, Radiation -- Usage, Electromagnetic waves -- Scattering, Electromagnetic waves -- Observations, Business, Earth sciences, Electronics and electrical industries
Abstract

Falling snow is an important component of global precipitation in extratropical regions. This paper describes the methodology and results of physically based retrievals of snow falling over land surfaces. Because microwave brightness temperatures emitted by snow-covered surfaces are highly variable, precipitating snow above such surfaces is difficult to observe using window channels that occur at low frequencies (v < 100 GHz). Furthermore, at frequencies v [less than or equal to] 37 GHz, sensitivity to liquid hydrometeors is dominant. These problems are mitigated at high frequencies (v > 100 GHz) where water vapor screens the surface emission, and sensitivity to frozen hydrometeors is significant. However, the scattering effect of snowfall in the atmosphere at those higher frequencies is also impacted by water vapor in the upper atmosphere. The theory of scattering by randomly oriented dry snow particles at high microwave frequencies appears to be better described by regarding snow as a concatenation of 'equivalent' ice spheres rather than as a sphere with the effective dielectric constant of an air-ice mixture. An equivalent sphere snow scattering model was validated against high-frequency attenuation measurements. Satellite-based high-frequency observations from an Advanced Microwave Sounding Unit (AMSU-B) instrument during the March 5-6, 2001 New England blizzard were used to retrieve snowfall over land. Vertical distributions of snow, temperature, and relative humidity profiles were derived from the Mesoscale Model (MM5) cloud model. Those data were applied and modified in a radiative transfer model that derived brightness temperatures consistent with the AMSU-B observations. The retrieved snowfall distribution was validated with radar reflectivity measurements obtained from a ground-based radar network. Index Terms--Electromagnetic scattering, estimation, millimeter-wave radiometry, remote sensing, satellite, snow.

Published
2004

34. Detection Thresholds of Falling Snow From Satellite-Borne Active and Passive Sensors

Author

Skofronick-Jackson, Gail M, Johnson, Benjamin T, and Munchak, S. Joseph

Subjects
Meteorology And Climatology, Earth Resources And Remote Sensing
Abstract

There is an increased interest in detecting and estimating the amount of falling snow reaching the Earths surface in order to fully capture the global atmospheric water cycle. An initial step toward global spaceborne falling snow algorithms for current and future missions includes determining the thresholds of detection for various active and passive sensor channel configurations and falling snow events over land surfaces and lakes. In this paper, cloud resolving model simulations of lake effect and synoptic snow events were used to determine the minimum amount of snow (threshold) that could be detected by the following instruments: the W-band radar of CloudSat, Global Precipitation Measurement (GPM) Dual-Frequency Precipitation Radar (DPR)Ku- and Ka-bands, and the GPM Microwave Imager. Eleven different nonspherical snowflake shapes were used in the analysis. Notable results include the following: 1) The W-band radar has detection thresholds more than an order of magnitude lower than the future GPM radars; 2) the cloud structure macrophysics influences the thresholds of detection for passive channels (e.g., snow events with larger ice water paths and thicker clouds are easier to detect); 3) the snowflake microphysics (mainly shape and density)plays a large role in the detection threshold for active and passive instruments; 4) with reasonable assumptions, the passive 166-GHz channel has detection threshold values comparable to those of the GPM DPR Ku- and Ka-band radars with approximately 0.05 g *m(exp -3) detected at the surface, or an approximately 0.5-1.0-mm * h(exp -1) melted snow rate. This paper provides information on the light snowfall events missed by the sensors and not captured in global estimates.

Published
2013
Full Text
View/download PDF

35. Influence of microphysical cloud parameterizations on microwave brightness temperatures

Author

Skofronick-Jackson, Gail M., Gasiewski, Albin J., and Wang, James R.

Subjects
Earth sciences -- Research, Clouds -- Research, Radiation -- Measurement, Remote sensing -- Research, Snow -- Research, Business, Earth sciences, Electronics and electrical industries
Abstract

The microphysical parameterization of clouds and rain cells plays a central role in atmospheric forward radiative transfer models used in calculating microwave brightness temperatures. The absorption and scattering properties of a hydrometeor-laden atmosphere are governed by particle phase, size distribution, aggregate density, shape, and dielectric constant. This study investigates the sensitivity of brightness temperatures with respect to the microphysical cloud parameterization. Calculated wideband (6-410 GHz) brightness temperatures were studied for four evolutionary stages of an oceanic convective storm using a five-phase hydrometeor model in a planar-stratified scattering-based radiative transfer model. Five other microphysical cloud parameterizations were compared to the baseline calculations to evaluate brightness temperature sensitivity to gross changes in the hydrometeor size distributions and the ice-air-water ratios in the frozen or partly frozen phase. The comparison shows that enlarging the raindrop size or adding water to the partly frozen hydrometeor mix warms brightness temperatures by as much as 55 K at 6 GHz. The cooling signature caused by ice scattering intensifies with increasing ice concentrations and at higher frequencies. An additional comparison to measured Convection and Moisture Experiment (CAMEX-3) brightness temperatures shows that in general all but two parameterizations produce calculated [T.sub.B]s that fall within the CAMEX-3 observed minima and maxima. The exceptions are for parameterizations that enhance the scattering characteristics of frozen hydrometeors. Index Terms--Clouds, electromagnetic scattering, millimeter wave radiometry, rain, remote sensing, snow.

Published
2002

36. Airborne Lidar Observations of Wind, Water Vapor, and Aerosol Profiles During The NASA Aeolus Cal/Val Test Flight Campaign

Author

Bedka, Kristopher M., primary, Nehrir, Amin R., additional, Kavaya, Michael, additional, Barton-Grimley, Rory, additional, Beaubien, Mark, additional, Carroll, Brian, additional, Collins, James, additional, Cooney, John, additional, Emmitt, G. David, additional, Greco, Steven, additional, Kooi, Susan, additional, Lee, Tsengdar, additional, Liu, Zhaoyan, additional, Rodier, Sharon, additional, and Skofronick-Jackson, Gail, additional

Published
2020
Full Text
View/download PDF

38. Aeolus Calibration, Validation and Science Campaigns

Author

Fehr, Thorsten, primary, Amiridis, Vassilis, additional, Bley, Sebastian, additional, Cocquerez, Philippe, additional, Lemmerz, Christian, additional, Močnik, Griša, additional, Skofronick-Jackson, Gail, additional, and Straume, Anne Grete, additional

Published
2020
Full Text
View/download PDF

39. Surface and Atmospheric Contributions to Passive Microwave Brightness Temperatures for Falling Snow Events

Author

Skofronick-Jackson, Gail and Johnson, Benjamin T

Subjects
Geophysics
Abstract

Physically based passive microwave precipitation retrieval algorithms require a set of relationships between satellite -observed brightness temperatures (TBs) and the physical state of the underlying atmosphere and surface. These relationships are nonlinear, such that inversions are ill ]posed especially over variable land surfaces. In order to elucidate these relationships, this work presents a theoretical analysis using TB weighting functions to quantify the percentage influence of the TB resulting from absorption, emission, and/or reflection from the surface, as well as from frozen hydrometeors in clouds, from atmospheric water vapor, and from other contributors. The percentage analysis was also compared to Jacobians. The results are presented for frequencies from 10 to 874 GHz, for individual snow profiles, and for averages over three cloud-resolving model simulations of falling snow. The bulk structure (e.g., ice water path and cloud depth) of the underlying cloud scene was found to affect the resultant TB and percentages, producing different values for blizzard, lake effect, and synoptic snow events. The slant path at a 53 viewing angle increases the hydrometeor contributions relative to nadir viewing channels. Jacobians provide the magnitude and direction of change in the TB values due to a change in the underlying scene; however, the percentage analysis provides detailed information on how that change affected contributions to the TB from the surface, hydrometeors, and water vapor. The TB percentage information presented in this paper provides information about the relative contributions to the TB and supplies key pieces of information required to develop and improve precipitation retrievals over land surfaces.

Published
2011
Full Text
View/download PDF

40. Passive Microwave Remote Sensing of Falling Snow and Associated GPM Field Campaigns

Author

Skofronick-Jackson, Gail

Subjects
Earth Resources And Remote Sensing
Abstract

Retrievals of falling snow from space represent one of the next important challenges for the atmospheric, hydrological, and energy budget scientific communities. Historically, retrievals of falling snow have been difficult due to the relative insensitivity of satellite rain-based channels as used in the past. We emphasize the use of high frequency passive microwave channels (85-200 GHz) since these are more sensitive to the ice in clouds and have been used to estimate falling snow from space. While satellite-based remote sensing provides global coverage of falling snow events and the science is relatively new, retrievals are still undergoing development with challenges remaining. There are several current satellite sensors, though not specifically designed for estimating falling snow, are capable of measuring snow from space. These include NOAA's AMSU-B, the MHS sensors, and CloudSat radar. They use high frequency (greater than 85 GHz) passive and active microwave and millimeter-wave channels that are sensitive to the scattering from ice and snow particles in the atmosphere. Sensors with water vapor channels near 183 GHz center line provide opaqueness to the Earth's surface features that can contaminate the falling snow signatures, especially over snow covered surface. In addition, the Global Precipitation Measurement (GPM) mission scheduled for launch in 2013 is specifically designed to measure both liquid rain and frozen snow precipitation. Since falling snow from space is the next precipitation measurement challenge from space, information must be determined in order to guide retrieval algorithm development for these current and future missions. This information includes thresholds of detection for various sensor channel configurations, snow event system characteristics, and surface types. For example, can a lake effect snow system with low cloud tops having an ice water content (IWC) at the surface of 1.0 gram per cubic meter be detected? If this information is known, we can focus retrieval efforts on detectable storms and concentrate advances on achievable results. In this work, the focus is to determine thresholds of detection for falling snow for various snow conditions over land and lake surfaces. The results rely on simulated Weather Research Forecasting (WRF) simulations of falling snow cases [9] since simulations provide all the information to determine the measurements from space and the ground truth. This analysis relies on data from the Canadian CloudSat/CALIPSO Validation Program (C3VP) field campaign held from October 31, 2006 through March 1, 2007. In January 2012 GPM will return to the C3VP area for the GPM Cold Precipitation Experiment (GCPEx). This presentation will describe the thresholds-of-detection procedure and results, as well as the field campaign details.

Published
2011

41. GPM Mission Overview

Author

Hou, Arthur Y and Skofronick-Jackson, Gail

Subjects
Meteorology And Climatology
Abstract

The Global Precipitation Measurement (GPM) Mission is an international satellite mission to unify and advance precipitation measurements from a constellation of research and operational sensors to provide "next-generation" precipitation products. Relative to current global rainfall products, GPM data products will be characterized by: (1) more accurate instantaneous precipitation measurements (especially for light rain and cold-season solid/snow precipitation), (2) more frequent sampling by an expanded constellation of microwave radiometers that include operational humidity sounders over land, (3) inter-calibrated microwave brightness temperatures from constellation radiometers within a unified framework, and (4) physical-based precipitation retrievals from constellation radiometers using a common a priori cloud hydrometeor database derived from GPM Core sensor measurements. The cornerstone of the GPM mission is the deployment of a Core Observatory in a unique 65 degree non-Sun-synchronous orbit to serve as a physics observatory and a calibration reference to improve precipitation measurements by a constellation of dedicated and operational passive microwave sensors. The Core Observatory will carry a KulKa-band Dual-frequency Precipitation Radar (DPR) and a multi-channel (10-183 GHz) GPM Microwave Radiometer (GMI). The combined use ofDPR and GMI measurements will place greater constraints on possible solutions to radiometer retrievals to improve the accuracy and consistency of precipitation retrievals from all constellation radiometers. As a science mission with integrated application goals, GPM is designed to (1) advance precipitation measurement capability from space through combined use of active and passive microwave sensors, (2) advance the knowledge of the global water/energy cycle and freshwater availability through better description of the space-time variability of global precipitation, and (3) improve weather, climate, and hydrological prediction capabilities through more accurate and frequent measurements of instantaneous precipitation rates and time-integrated rainfall accumulation. An overview of the GPM mission concept and science activities in the United States, together with an update on international collaborations in radiometer intercalibration and ground validation, will be presented.

Published
2011

42. Land Surface Emission Modeling to Support Physical Precipitation Retrievals

Author

Peters-Lidard, Christina D, Harrison, Kenneth, Kumar, Sujay, Ferraro, Ralph, and Skofronick-Jackson, Gail

Subjects
Meteorology And Climatology
Abstract

Land surface modeling and data assimilation can provide dynamic land surface state variables necessary to support physical precipitation retrieval algorithms over land. It is well-known that surface emission, particularly over the range of frequencies to be included in the Global Precipitation Measurement Mission (GPM), is sensitive to land surface states, including soil properties, vegetation type and greenness, soil moisture, surface temperature, and snow cover, density, and grain size. In order to investigate the robustness of both the land surface model states and the microwave emissivity and forward radiative transfer models, we have undertaken a multi-site investigation as part of the NASA Precipitation Measurement Missions (PMM) Land Surface Characterization. Working Group.

Published
2010

43. Global Precipitation Measurement

Author

Hou, Arthur Y, Skofronick-Jackson, Gail, Kummerow, Christian D, and Shepherd, James Marshall

Subjects
Meteorology And Climatology
Abstract

This chapter begins with a brief history and background of microwave precipitation sensors, with a discussion of the sensitivity of both passive and active instruments, to trace the evolution of satellite-based rainfall techniques from an era of inference to an era of physical measurement. Next, the highly successful Tropical Rainfall Measuring Mission will be described, followed by the goals and plans for the Global Precipitation Measurement (GPM) Mission and the status of precipitation retrieval algorithm development. The chapter concludes with a summary of the need for space-based precipitation measurement, current technological capabilities, near-term algorithm advancements and anticipated new sciences and societal benefits in the GPM era.

Published
2008

44. Nonspherical and Spherical Characterization of Ice in Hurricane Erin for Wideband Passive Microwave Comparisons

Author

Skofronick-Jackson, Gail, Holthaus, Eric, Albers, Cerese, and Kim, Min-Jeong

Subjects
Meteorology And Climatology
Abstract

In order to better understand the characteristics of frozen cloud particles in hurricane systems, computed brightness temperatures were compared with radiometric observations of Hurricane Erin (2001) from the NASA ER-2 aircraft. The focus was oil the frozen particle microphysics and the high frequencies (2 85 GHz) that are particularly sensitive to frozen particles. Frozen particles in hurricanes are an indicator of increasing hurricane intensity. In fact "hot towers" associated with increasing hurricane intensity are composed of frozen ice cloud particles. (They are called hot towers because their column of air is warmer than the surrounding air temperature, but above about 5-7 km to the tops of the towers at 15-19 km, the cloud particles are frozen.) This work showed that indeed, one can model information about cloud ice particle characteristics and indicated that nonspherical ice shapes, instead of spherical particles, provided the best match to the observations. Overall, this work shows that while non-spherical particles show promise, selecting and modeling a proper ice particle parameterization can be difficult and additional in situ measurements are needed to define and validate appropriate parameterizations. This work is important for developing Global Precipitation Measurement (GPM) mission satellite algorithms for the retrieval of ice characteristics both above the melting layer, as in Hurricane Erin, and for ice particles that reach the surface as falling snow.

Published
2007

45. The Development Of Enabling Technologies For Submillimeter-Wave Remote Sensing of Ice Clouds From Space

Author

Racette, Paul, Wang, James R, Ackerman, Steven, Skofronick-Jackson, Gail, Evans, K. Frank, and O'CStarr, David

Subjects
Earth Resources And Remote Sensing
Abstract

This paper presents the chronological development of technologies and techniques that have led to a satellite mission concept aimed at quantifying the temporal and spatial distributions of upper tropospheric ice clouds. The Submillimeter-wave and Infrared Ice Cloud Experiment (SIRICE) is an Earth System Science Pathfinder mission concept designed to improve our understanding of the upper tropospheric water cycle and its coupling to the Earth s radiation budget. Ice outflow from convective storm systems is known to play an important role in regional energy budgets; however, ice generation and subsequent precipitation and sublimation are poorly quantified. SIRICE will provide measurements of ice cloud distributions and microphysical properties which are needed for understanding the crucial link between the hydrologic and energy cycles. The SIRICE measurement platform is comprised of two integrated instruments, the Submillimeter/millimeter-wave radiometer (SM4) and the Infrared Cloud Ice Radiometer (IRCIR). The primary instrument is the SM4, a conical scanner that provides a 1600 km swath of the Earth's surface at 53 degree incidence. The SM4 has 6 linearly polarized receivers measuring 12 spectral bands centered at 183 GHz, 325 GHz, 448 GHz, 643 GHz and 874 GHz; two receivers at 643 GHz measure horizontal and vertical polarizations. Submillimeter-wavelengths are well suited to the remote sensing of ice clouds due to the relative size of the wavelengths to particle sizes. Upwelling emission from lower tropospheric water vapor is scattered by the ice clouds thus causing a brightness temperature depression at submillimeter wavelengths. The IRCIR is a push broom imager with approximately 1500 km swath and spectral channels at 11 and 12 micrometers. This combination of coincident infrared and submillimeter-wavelength measurements were chosen because of its ability to provide retrieval of ice water path and median particle size for a wide range of ice clouds from thin cirrus to thick anvil structures. Over the past decade there has been a parallel development of submillimeter-wave technologies, demonstration instruments, and remote sensing techniques that have led to the present SIRICE mission concept. Mapping of these developmental paths reveals the origins, rational and maturity of features of the SIRICE payload such as its channel selection, compact design, and multipoint calibration. This presentation traces the evolution of the SIRICE mission concept from the early 1990's to its present status.

Published
2006

46. Multisensor Observation and Simulation of Snowfall During the 2003 Wakasa Bay Field Experiment

Author

Johnson, Benjamin T, Petty, Grant W, Skofronick-Jackson, Gail, and Wang, James W

Subjects
Meteorology And Climatology
Abstract

This research seeks to assess and improve the accuracy of microphysical assumptions used in satellite passive microwave radiative transfer models and retrieval algorithms by exploiting complementary observations from satellite radiometers, such as TRMM/AMSR-E/GPM, and coincident aircraft instruments, such as the next generation precipitation radar (PR-2). We focus in particular on aircraft data obtained during the Wakasa Bay field experiment, Japan 2003, pertaining to surface snowfall events. The observations of vertical profiles of reflectivity and Doppler-derived fall speeds are used in conjunction with the radiometric measurements to identify 1-D profiles of precipitation particle types, sizes, and concentrations that are consistent with the observations.

Published
2005

47. Scattering Properties and Brightness Temperatures Associated with Solid Precipitation

Author

Skofronick-Jackson, Gail M and Kim, Min-Jeong

Subjects
Meteorology And Climatology
Abstract

In the past few years, early solid precipitation detection and retrieval algorithms have been developed and shown to be applicable for snowing clouds and blizzards. NOAA has an operational snow versus rain classifier based on AMSU-B observations. Solid precipitation retrieval algorithms reported in the literature over the past two years include those that rely on neural nets, statistics, or physical relationships. All of the algorithms require the use of millimeter-wave radiometer observations. The millimeter-wave frequencies are especially sensitive to the scattering and emission properties of frozen particles due to the ice particle refractive index. Passive radiometric channels respond to both the integrated particle mass throughout the volume and field of view, and to the amount, location, and size distribution of the frozen (and liquid) particles with the sensitivity varying for different frequencies and hydrometeor types. This investigation probes the sensitivity of scattering and absorption coefficients, and hence computed brightness temperatures, resulting from variations in solid precipitation cloud profiles. The first study compares the single scattering, absorption, and asymmetry parameters associated with snow particles in clouds. Several methodologies are used to convert the physical characteristics (e.g., shape, size distributions, ice-air-water ratios) of ice particles to electromagnetic properties (e.g., absorption, scattering, and asymmetry factors). These methodologies include: conversion to solid ice particles, homogeneous dielectric mixing, or discrete dipole approximation. Changes in the conversion methodology can produce computed brightness temperature differences greater than 50 Kelvin.

Published
2005

48. Passive Remote Sensing of Cloud Ice Particles

Author

Skofronick-Jackson, Gail and Wang, James R

Subjects
Meteorology And Climatology
Abstract

Hurricanes, blizzards and other weather events are important to understand not only for disaster preparation, but also to track the global energy balance and to improve weather and climate forecasts. For several decades, passive radiometers and active radars on aircraft and satellites have been employed to remotely sense rain rates and the properties of liquid particles. In the past few years the relationships between frozen particles and millimeter-wave observations have become understood well enough to estimate the properties of ice in clouds. A brief background of passive remote sensing of precipitation will be presented followed by a focused discussion of recent research at NASA Goddard Space Flight Center estimating the properties of frozen particles in clouds. The retrievals are for (1) ice that will eventually melt into rain, (2) for solid precipitation falling in northern climates, and (3) cirrus ice clouds. The electromagnetic absorption and scattering properties and differences of liquid rain versus frozen particles will be summarized for frequencies from 6 to 340+ GHz. Challenges of this work including surface emissivity variability, non-linear and under-constrained relationships, and frozen particle unknowns will be discussed. Retrieved cloud particle contents and size distributions for ice above the melting layer in hurricanes, retrieved snowfall rates for a blizzard, and cirrus ice estimates will be presented. Future directions of this work will also be described.

Published
2004

49. The Influence of Microphysical Cloud Parameterization on Microwave Brightness Temperatures

Author

Skofronick-Jackson, Gail M, Gasiewski, Albin J, Wang, James R, and Zukor, Dorothy J

Subjects
Meteorology And Climatology
Abstract

The microphysical parameterization of clouds and rain-cells plays a central role in atmospheric forward radiative transfer models used in calculating passive microwave brightness temperatures. The absorption and scattering properties of a hydrometeor-laden atmosphere are governed by particle phase, size distribution, aggregate density., shape, and dielectric constant. This study identifies the sensitivity of brightness temperatures with respect to the microphysical cloud parameterization. Cloud parameterizations for wideband (6-410 GHz observations of baseline brightness temperatures were studied for four evolutionary stages of an oceanic convective storm using a five-phase hydrometeor model in a planar-stratified scattering-based radiative transfer model. Five other microphysical cloud parameterizations were compared to the baseline calculations to evaluate brightness temperature sensitivity to gross changes in the hydrometeor size distributions and the ice-air-water ratios in the frozen or partly frozen phase. The comparison shows that, enlarging the rain drop size or adding water to the partly Frozen hydrometeor mix warms brightness temperatures by up to .55 K at 6 GHz. The cooling signature caused by ice scattering intensifies with increasing ice concentrations and at higher frequencies. An additional comparison to measured Convection and Moisture LA Experiment (CAMEX 3) brightness temperatures shows that in general all but, two parameterizations produce calculated T(sub B)'s that fall within the observed clear-air minima and maxima. The exceptions are for parameterizations that, enhance the scattering characteristics of frozen hydrometeors.

Published
2000

Catalog

Books, media, physical & digital resources
See catalog results