{ "count": 31, "next": null, "previous": null, "results": [ { "id": 5596, "url": "https://svs.gsfc.nasa.gov/5596/", "result_type": "Visualization", "release_date": "2026-01-27T17:00:00-05:00", "title": "Tracking Weather Extremes: December 2025 Pacific Northwest Flooding", "description": "Created with NASA's GEOS data, this visualization shows the December 2025 atmospheric river that brought extreme precipitation to the Pacific Northwest. The analysis displays total precipitable water from the Pacific Ocean and resulting precipitation across Washington, Oregon, British Columbia, and Montana. This Category 5 atmospheric river delivered up to 10 inches of rain and forced over 100,000 evacuations in Washington state.", "hits": 571 }, { "id": 4939, "url": "https://svs.gsfc.nasa.gov/4939/", "result_type": "Visualization", "release_date": "2021-10-07T00:00:00-04:00", "title": "3D Water Vapor shows an Atmospheric River", "description": "This visualization shows the NOAA-20 satellite orbiting the Earth with a trail of 3D water vapor behind it collected between January 25 and 28, 2021. The calculated total precipitable water (TPW) is shown in a blue to red color scale beneath the white water vapor.Coming soon to our YouTube channel. || JPSS_ATMS_water_vapor_with_TPW.3462_print.jpg (1024x576) [179.6 KB] || JPSS_ATMS_water_vapor_with_TPW_1080p30.mp4 (1920x1080) [83.0 MB] || JPSS_ATMS_water_vapor_with_TPW_1080p60.mp4 (1920x1080) [84.5 MB] || JPSS_ATMS_water_vapor_with_TPW_1080p30.webm (1920x1080) [7.7 MB] || 1920x1080_16x9_30p (1920x1080) [0 Item(s)] || 1920x1080_16x9_60p (1920x1080) [0 Item(s)] || 3840x2160_16x9_30p (3840x2160) [0 Item(s)] || 3840x2160_16x9_60p (3840x2160) [0 Item(s)] || captions_silent.31606.en_US.srt [43 bytes] || JPSS_ATMS_water_vapor_with_TPW_30p_2160p30_2.mp4 (3840x2160) [409.8 MB] || JPSS_ATMS_water_vapor_with_TPW_60p_2160p60_2.mp4 (3840x2160) [441.6 MB] || JPSS_ATMS_water_vapor_with_TPW_1080p30.mp4.hwshow [204 bytes] || ", "hits": 119 }, { "id": 40365, "url": "https://svs.gsfc.nasa.gov/gallery/earth-science-oct2018-briefing/", "result_type": "Gallery", "release_date": "2018-10-18T00:00:00-04:00", "title": "Earth Science Overview Oct 2018 Briefing", "description": "No description available.", "hits": 115 }, { "id": 30701, "url": "https://svs.gsfc.nasa.gov/30701/", "result_type": "Hyperwall Visual", "release_date": "2016-02-08T12:00:00-05:00", "title": "Earth: A System of Systems", "description": "Slices of Earth observational and modeling data || R_beach_ball_flat_1080p.00001_print.jpg (1024x576) [105.6 KB] || R_beach_ball_flat_1080p.00001_searchweb.png (320x180) [53.8 KB] || R_beach_ball_flat_1080p.00001_thm.png (80x40) [4.3 KB] || R_beach_ball_flat_1080p.mp4 (1920x1080) [47.3 MB] || R_beach_ball_flat_720p.mp4 (1280x720) [26.4 MB] || R_beach_ball_flat_720p.webm (1280x720) [7.8 MB] || beach_ball_noLabels_1080p.mp4 (1920x1080) [41.8 MB] || beach_ball_noLabels_720p.mp4 (1280x720) [23.1 MB] || R_beach_ball_flat_360p.mp4 (640x360) [9.3 MB] || cam_held (4104x2304) [0 Item(s)] || earth_system_of_systems_30701.key [51.4 MB] || earth_system_of_systems_30701.pptx [49.0 MB] || beachball_2304p.mp4 (4096x2304) [125.7 MB] || beach_ball_noLabels_2304p.mp4 (4096x2304) [121.0 MB] || ", "hits": 265 }, { "id": 40268, "url": "https://svs.gsfc.nasa.gov/gallery/hyperwall-geos/", "result_type": "Gallery", "release_date": "2015-10-23T00:00:00-04:00", "title": "Hyperwall GEOS", "description": "all Hyperwall shows based on GEOS", "hits": 5 }, { "id": 40243, "url": "https://svs.gsfc.nasa.gov/gallery/hyperwall-earth/", "result_type": "Gallery", "release_date": "2015-07-24T00:00:00-04:00", "title": "Hyperwall Earth", "description": "Hyperwall stories in the Earth Category\nReturn to Main Hyperwall Gallery.", "hits": 66 }, { "id": 30583, "url": "https://svs.gsfc.nasa.gov/30583/", "result_type": "Hyperwall Visual", "release_date": "2015-02-13T00:00:00-05:00", "title": "AXIOM-1 Sea Surface Salinity, Sea Ice Thickness and Atmospheric Precipitable Water", "description": "This animation shows sea surface sailinity, sea ice thickness, and atmospheric precipitable water. || 0001_print.jpg (1024x576) [234.1 KB] || 0001_searchweb.png (180x320) [120.0 KB] || 0001_web.png (320x180) [120.0 KB] || 0001_thm.png (80x40) [8.0 KB] || sss-1920x1080.webm (1920x1080) [16.1 MB] || axiom_salinity_h265_720p.mp4 (1280x720) [109.1 MB] || axiom_salinity_720p.mp4 (1280x720) [166.0 MB] || sss-1920x1080.mp4 (1920x1080) [976.2 MB] || sss (5760x3240) [128.0 KB] || axiom_salinity_h265_2304p.mp4 (4096x2304) [1.0 GB] || ocean+salinity_ice_thickness_precip_water_30583.key [983.1 MB] || ocean+salinity_ice_thickness_precip_water_30583.pptx [979.9 MB] || axiom_salinity_2304p.mp4 (4096x2304) [1.5 GB] || ", "hits": 32 }, { "id": 30584, "url": "https://svs.gsfc.nasa.gov/30584/", "result_type": "Hyperwall Visual", "release_date": "2015-02-13T00:00:00-05:00", "title": "AXIOM-1 Ocean chlorophyll, Sea Ice Thickness and Atmospheric Precipitable Water", "description": "This animation shows ocean surface chlorophyll concentration, sea ice thickness, and atmospheric precipitable water. || 0001_print.jpg (1024x576) [236.0 KB] || 0001_searchweb.png (320x180) [121.0 KB] || 0001_web.png (320x180) [121.0 KB] || 0001_thm.png (80x40) [8.0 KB] || chl-1920x1080.webm (1920x1080) [15.9 MB] || axiom_chl_720p.mp4 (1280x720) [161.2 MB] || axiom_chl_h265_720p.mp4 (1280x720) [105.5 MB] || chl-1920x1080.mp4 (1920x1080) [889.5 MB] || chl (5760x3240) [128.0 KB] || axiom_chl_h265_2304p.mp4 (4096x2304) [913.8 MB] || chlorophyll_ice_thickness_precip_water_30584.key [896.4 MB] || chlorophyll_ice_thickness_precip_water_30584.pptx [893.1 MB] || axiom_chl_2304p.mp4 (4096x2304) [1.4 GB] || ", "hits": 38 }, { "id": 30644, "url": "https://svs.gsfc.nasa.gov/30644/", "result_type": "Hyperwall Visual", "release_date": "2014-12-10T10:00:00-05:00", "title": "Simulated Clouds and Precipitable Water", "description": "Clouds and precipitable water animation of Apr 1 - Jul 31, 2006. || geos_cloudspw_20060101_0000_print.jpg (1024x576) [245.1 KB] || geos_cloudspw_20060101_0000.png (4096x2304) [15.1 MB] || geos_cloudspw_20060101_0000_searchweb.png (320x180) [108.1 KB] || geos_cloudspw_20060101_0000_thm.png (80x40) [7.9 KB] || geos_cloudspw_720p.webm (1280x720) [12.5 MB] || geos_cloudspw_720p.mp4 (1280x720) [270.8 MB] || geos_cloudspw_1080p.mp4 (1920x1080) [523.0 MB] || geos_cloudspw_2160p.mp4 (3840x2160) [1.4 GB] || ", "hits": 160 }, { "id": 30524, "url": "https://svs.gsfc.nasa.gov/30524/", "result_type": "Hyperwall Visual", "release_date": "2014-11-03T00:00:00-05:00", "title": "AXIOM-1 Sea Surface Temperature", "description": "This animation shows sea surface temperature, ice thickness, and atmospheric precipitable water. || 0001_print.jpg (1024x576) [212.3 KB] || 0001_searchweb.png (320x180) [102.5 KB] || 0001_web.png (320x180) [102.5 KB] || 0001_thm.png (80x40) [7.0 KB] || sst-1920x1080.webm (1920x1080) [41.7 MB] || sst (1920x1080) [128.0 KB] || sst (5760x3240) [128.0 KB] || sst-1920x1080.mp4 (1920x1080) [1.3 GB] || sst_ice_thickness_precip_water_30524.key [1.3 GB] || sst_ice_thickness_precip_water_30524.pptx [1.3 GB] || sst-5760x3240.mp4 (5760x3240) [9.0 GB] || ", "hits": 23 }, { "id": 4163, "url": "https://svs.gsfc.nasa.gov/4163/", "result_type": "Visualization", "release_date": "2014-05-29T00:00:00-04:00", "title": "GPM Senses East Coast Snow Storm on March 17th, 2014", "description": "The Global Precipitation Measurement (GPM) Mission is a joint satellite mission between NASA and JAXA. GPM has the capability of differentiating between liquid and frozen precipitation. In this visualization we see a large east coast snow storm through the eyes of GPM. || ", "hits": 18 }, { "id": 4153, "url": "https://svs.gsfc.nasa.gov/4153/", "result_type": "Visualization", "release_date": "2014-03-25T01:00:00-04:00", "title": "GPM/GMI First Light", "description": "Eleven days after the Feb. 27 launch of the Global Precipitation Measurement (GPM) Core Observatory, the two instruments aboard took their first joint images of an interesting precipitation event. On March 10, the Core Observatory passed over an extra-tropical cyclone about 1055 miles (1700 kilometers) due east of Japan's Honshu Island. The storm formed from the collision of a cold front wrapping around a warm front, emerging over the ocean near Okinawa on March 8. It moved northeast over the ocean south of Japan, drawing cold air west-to-east over the land, a typical winter weather pattern that also brought heavy snow over Hokkaido, the northernmost of the four main islands. After the GPM images were taken, the storm continued to move eastward, slowly intensifying before weakening in the central North Pacific.This visualization shows data from the GPM Microwave Imager, which observes different types of precipitation with 13 channels. Scientists analyze that data and then use it to calculate the light to heavy rain rates and falling snow within the storm.For more information on this topic: GPM web siteOther multimedia items related to this story: GPM GMI First Light (#11508) GPM DPR First Light (#11509) || ", "hits": 41 }, { "id": 30017, "url": "https://svs.gsfc.nasa.gov/30017/", "result_type": "Hyperwall Visual", "release_date": "2013-03-07T00:00:00-05:00", "title": "GEOS-5 Nature Run Collection", "description": "Through numerical experiments that simulate the dynamical and physical processes governing weather and climate variability of Earth's atmosphere, models create a dynamic portrait of our planet. This 10-kilometer global mesoscale simulation (Nature Run) using the NASA Goddard Earth Observing System Model (GEOS-5) explores the evolution of surface temperatures as the sun heats the Earth and fuels cloud formation in the tropics and along baroclinic zones; the presence of water vapor and precipitation within these global weather patterns; the dispersion of global aerosols from dust, biomass burning, fossil fuel emissions, and volcanoes; and the winds that transport these aerosols from the surface to upper-levels.The full GEOS-5 simulation covered 2 years—from May 2005 to May 2007. It ran on 3,750 processors of the Discover supercomputer at the NASA Center for Climate Simulation, consuming 3 million processor hours and producing over 400 terabytes of data. GEOS-5 development is funded by NASA's Modeling, Analysis, and Prediction Program. || ", "hits": 170 }, { "id": 3837, "url": "https://svs.gsfc.nasa.gov/3837/", "result_type": "Visualization", "release_date": "2011-06-13T00:00:00-04:00", "title": "Components of the Water Cycle on a Flat Map for Science On a Sphere", "description": "Water regulates climate, predominately storing heat during the day and releasing it at night. Water in the ocean and atmosphere carry heat from the tropics to the poles. The process by which water moves around the earth, from the ocean, to the atmosphere, to the land and back to the ocean is called the water cycle. The animations below each portray a component of the water cycle. These animations of the components of the water cycle were created for the Science On a Sphere production \"Loop\" using data from the GEOS-5 atmospheric model on the cubed-sphere, run at 14-km global resolution for 25-days. Variables animated here include hourly clouds, precipitation, evaporation and water vapor. For more information on GEOS-5 see https://gmao.gsfc.nasa.gov/systems/geos5. Some of these visualizations are an orthographic view of the data used in Components of the Water Cycle. || ", "hits": 76 }, { "id": 3811, "url": "https://svs.gsfc.nasa.gov/3811/", "result_type": "Visualization", "release_date": "2011-01-11T00:00:00-05:00", "title": "Components of the Water Cycle on a Flat Map", "description": "Water regulates climate, predominately storing heat during the day and releasing it at night. Water in the ocean and atmosphere carry heat from the tropics to the poles. The process by which water moves around the earth, from the ocean, to the atmosphere, to the land and back to the ocean is called the water cycle. The animations below each portray a component of the water cycle. The three animations of atmospheric phenomena were created using data from the GEOS-5 atmospheric model on the cubed-sphere, run at 14-km global resolution for 25-days. Variables animated here include hourly evaporation, water vapor and precipitation. For more information on GEOS-5 see http://gmao.gsfc.nasa.gov/systems/geos5 . For more information on the cubed-sphere work see http://science.gsfc.nasa.gov/610.3/cubedsphere.html.The animation of global sea surface temperature was created using data from a model run of ECCO's Ocean General Circulation Model. See http://www.ecco-group.org/model.htm for more information on ECCO.This group of animations are an orthographic view of the data used in Components of the Water Cycle. || ", "hits": 100 }, { "id": 40034, "url": "https://svs.gsfc.nasa.gov/gallery/2004hurricane-season/", "result_type": "Gallery", "release_date": "2010-03-08T00:00:00-05:00", "title": "2004 Hurricane Season", "description": "No description available.", "hits": 29 }, { "id": 40035, "url": "https://svs.gsfc.nasa.gov/gallery/2003hurricane-season/", "result_type": "Gallery", "release_date": "2010-03-08T00:00:00-05:00", "title": "2003 Hurricane Season", "description": "No description available.", "hits": 131 }, { "id": 3645, "url": "https://svs.gsfc.nasa.gov/3645/", "result_type": "Visualization", "release_date": "2009-10-08T00:00:00-04:00", "title": "Hourly Total Precipitation from the GEOS-5 Model", "description": "This animation portrays the hourly flow of precipitation around the world. The animation was created using data from the GEOS-5 atmospheric model on the cubed-sphere, run at 14-km global resolution for 30-days. For more information on the GEOS-5, see http://gmao.gsfc.nasa.gov/systems/geos5 . For more information on the cubed-sphere work, see http://sivo.gsfc.nasa.gov/cubedsphere_overview.html. || ", "hits": 18 }, { "id": 3648, "url": "https://svs.gsfc.nasa.gov/3648/", "result_type": "Visualization", "release_date": "2009-10-08T00:00:00-04:00", "title": "Components of the Water Cycle", "description": "Water regulates climate, storing heat during the day and releasing it at night. Water in the ocean and atmosphere carry heat from the tropics to the poles. The process by which water moves around the earth, from the ocean, to the atmosphere, to the land and back to the ocean is called the water cycle. The animations below each portray a component of the water cycle. All use an identical view and camera motion to allow for easy compositing.Data for the animation of global sea surface temperature was derived from a model run of ECCO's Ocean General Circulation Model. See http://www.ecco-group.org/model.htm for more information on ECCO.Data for the animation of atmospheric phenomena was created using data from the GEOS-5 atmospheric model on the cubed-sphere, run at 14-km global resolution for 25-days. Variables animated here include evaporation, water vapor and precipitation.For more information on the GEOS-5 see http://gmao.gsfc.nasa.gov/systems/geos5.For more information on the cubed-sphere work see http://science.gsfc.nasa.gov/610.3/cubedsphere.html.All three of these animations are time synchronous throughout the animation to allow cross fades during compositing.The final animation shown here, a pulsing network of rivers over the continents, represents the flow of water from land back into the ocean, thereby completing the water cycle.A flat version of these animations can be found in item #3811. || ", "hits": 143 }, { "id": 3436, "url": "https://svs.gsfc.nasa.gov/3436/", "result_type": "Visualization", "release_date": "2007-07-05T00:00:00-04:00", "title": "CloudSat, Calipso and MODIS over Central America", "description": "Associated with tropical thunderstorms are broad fields of cirrus clouds that flow out of the tops of the vigorous storm systems that form over warm tropical oceans. These clouds play a role in how much infrared energy is trapped in Earth's atmosphere. NASA's Tropical Composition, Cloud and Climate Coupling (TC4) mission, which runs from July 16, 2007 through August 8, 2007, aims to document the full lifecycle of these clouds. Observations from four A-Train satellites flying in formation will complement the aircraft measurements with large-scale views of many different features of the atmosphere. Observations from this mission along with previous studies will improve our understanding of what effect a warming climate with rising ocean temperatures will have on these cloud systems. These images over Central America, produced in support of the TC4 mission, show a tropical storm system over Central and South America on August 2, 2006 as measured from multiple satellite sensors, including Aqua MODIS, CloudSat and CALIPSO. In this view from the Pacific Ocean, Panama is on the left and South America is shown on the right. In the following series of still images, each satellite's measurement is shown individually and in combination with the others from the same camera viewpoint. The profile showing CloudSat and CALIPSO data is truncated at a height of twenty kilometers and exaggerated ten times. The land topography is also exaggerated by a factor of ten. || ", "hits": 34 }, { "id": 3210, "url": "https://svs.gsfc.nasa.gov/3210/", "result_type": "Visualization", "release_date": "2005-07-28T11:00:00-04:00", "title": "Global Large-scale Precipitation during Hurricane Frances (WMS)", "description": "Water vapor is a small but significant constituent of the atmosphere, warming the planet due to the greenhouse effect and condensing to form clouds. As moisture-laden air rises, the relative humidity increases until it saturates the air, at which time precipitation occurs. If the uplift of air is due to large-scale atmospheric motion, then the precipitation is called large-scale, or dynamic. This animation shows the large-scale precipitation for the whole globe from September 1, 2004, through September 5, 2004, during the period of Hurricane Frances in the western Atlantic Ocean and Typhoon Songda in the western Pacific Ocean. Large-scale precipitation tends to be continuous and to come from decks of stratus clouds rather than from thunderstorms. || ", "hits": 21 }, { "id": 3182, "url": "https://svs.gsfc.nasa.gov/3182/", "result_type": "Visualization", "release_date": "2005-07-27T11:00:00-04:00", "title": "Global Atmospheric Sea Level Pressure during Hurricane Frances (WMS)", "description": "The weight of the Earth's atmosphere exerts pressure on the surface of the Earth. This pressure varies from place-to-place due the variations in the Earth's surface since higher altitudes have less atmosphere above them than lower altitudes. Atmospheric pressure also varies from time-to-time due to the uneven heating of the atmosphere by the sun and the rotation of the Earth, causing weather. In order to see the changes in pressure which affect the weather, the variation due to altitude is removed from the surface pressure, creating a quantity called sea level pressure. This animation shows the atmospheric sea level pressure for the whole globe from September 1, 2004, through September 5, 2004, during the period of Hurricane Frances in the western Atlantic Ocean and Typhoon Songda in the western Pacific Ocean. The sharp, moving low pressures areas for Frances and Songda can be clearly seen in the oceans. Even with the direct effect of altitude removed, cold high-altitude regions such as the South Pole and the Himalayan Plateau still exhibit lower-than-normal pressures, probably due to the interaction of cold air over those regions with the warmer air in the surrounding regions. || ", "hits": 49 }, { "id": 3202, "url": "https://svs.gsfc.nasa.gov/3202/", "result_type": "Visualization", "release_date": "2005-07-27T11:00:00-04:00", "title": "Global Atmospheric Water Vapor during Hurricane Frances (WMS)", "description": "Water vapor is a small but significant constituent of the atmosphere, warming the planet due to the greenhouse effect and condensing to form clouds which both warm and cool the Earth in different circumstances. Warm, moisture-laden air moving out from the tropics brings rainfall to the temperate zones. This animation shows the atmospheric water vapor for the whole globe from September 1, 2004, through September 5, 2004, during the period of Hurricane Frances in the western Atlantic Ocean and Typhoon Songda in the western Pacific Ocean. The band of water vapor over the tropics is the intertropical convergence zone, where converging trade winds and high temperatures force large amounts of water high into the atmosphere. Both Hurricane Frances and Typhoon Songda exhibit significant spiral bands of high water vapor. || ", "hits": 40 }, { "id": 3032, "url": "https://svs.gsfc.nasa.gov/3032/", "result_type": "Visualization", "release_date": "2005-01-12T12:00:00-05:00", "title": "Model of Clouds during Hurricane Isabel, 2003 (WMS)", "description": "The NASA finite-volume General Circulation Model (fvGCM) is used to produce a high-resolution weather prediction system. This model has an increased accuracy of predicting the strength and location of hurricanes over other prediction methods. Several variables are predicted, including cloud cover and precipitable water in the atmosphere. Data from Hurricane Isabel was used to validate the fvGCM model. || ", "hits": 14 }, { "id": 3033, "url": "https://svs.gsfc.nasa.gov/3033/", "result_type": "Visualization", "release_date": "2005-01-12T12:00:00-05:00", "title": "Model of Precipitable Water during Hurricane Isabel, 2003 (WMS)", "description": "The NASA finite-volume General Circulation Model (fvGCM) is used to produce a high-resolution weather prediction system. This model has an increased accuracy of predicting the strength and location of hurricanes over other prediction methods. Several variables are predicted, including cloud cover and precipitable water in the atmosphere. Data from Hurricane Isabel was used to validate the fvGCM model. || ", "hits": 20 }, { "id": 3063, "url": "https://svs.gsfc.nasa.gov/3063/", "result_type": "Visualization", "release_date": "2004-12-06T12:00:00-05:00", "title": "fvGCM Climate Model of Hurricane Ivan (hourly/closeup view)", "description": "This animation illustrates the output of NASA's finite-volume General Circulation Model (fvGCM) during the five day period just prior to the landfall of hurricane Ivan.The data used for this animation was computed for each hour. The visible structure of the hurricane is defined by areas of high wind. The color represents the amount of total precipitable water (blue is low, red is high). || ", "hits": 23 }, { "id": 3064, "url": "https://svs.gsfc.nasa.gov/3064/", "result_type": "Visualization", "release_date": "2004-12-06T12:00:00-05:00", "title": "fvGCM Climate Model of Hurricane Frances and other storms", "description": "This animation illustrates the output of NASA's finite-volume General Circulation Model (fvGCM) which is a global, 1/4 degree atmospheric model. Three dimensional volumetric representations of tropical cyclones are shown around the world including: Hurricane Francis in the Western Atlantic, Tropical Depression Ivan in the Eastern Atlantic, Tropical Cyclone Pheobe in the Indian Ocean, and Super Typhoon Songda in the Western North Pacific. The structures are defined by areas of high wind speeds. The colors represent total precipitable water (blue is low, red is high). || ", "hits": 35 }, { "id": 3001, "url": "https://svs.gsfc.nasa.gov/3001/", "result_type": "Visualization", "release_date": "2004-09-09T12:00:00-04:00", "title": "Hurricane Isabel Model: Precipitable Water", "description": "The NASA finite-volume General Circulation Model (fvGCM) was used to predict the path of hurricane Isabel, starting from a known initial state. The predicted path is compared to the actual path taken by the hurricane. || ", "hits": 12 }, { "id": 3002, "url": "https://svs.gsfc.nasa.gov/3002/", "result_type": "Visualization", "release_date": "2004-09-09T12:00:00-04:00", "title": "Hurricane Isabel Model: Clouds and Precipitable Water", "description": "The NASA finite-volume General Circulation Model (fvGCM) was used to predict the path of hurricane Isabel, starting from a known initial state. The predicted path is compared to the actual path taken by the hurricane. || ", "hits": 19 }, { "id": 2901, "url": "https://svs.gsfc.nasa.gov/2901/", "result_type": "Visualization", "release_date": "2004-02-12T12:00:00-05:00", "title": "Atmospheric Water Vapor during the 1998 La Niña (WMS)", "description": "Water vapor is a small but significant constituent of the atmosphere, warming the planet due to the greenhouse effect and condensing to form clouds which both warm and cool the Earth in different circumstances. A key feature of global atmospheric water vapor convection is the Intertropical Convergence Zone, the low pressure region within five degrees of the equator where the trade winds converge and solar heating of the atmosphere forces the water-laden air to rise in altitude, form clouds, and then precipitate as rain in the afternoon. This visualization shows the global water vapor distribution in gray and white and the global precipitation in yellow every hour from August 30, 1998 to September 20, 1998. The afternoon thunderstorms in the tropics are seen as a flashing yellow region that moves from east to west, following the sun. This is a La Niña period, when the water to the west of South America is cooler than normal, forcing the atmosphere there to cool down and hold less water. Strong east-to-west winds can be seen in this region, contributing to the high water vapor region that forms further to the west over southeast Asia, the Philippines, and Indonesia, causing increased humidity and rainfall in that region. This data is from the Goddard Earth Modeling System, a coupled land-ocean-atmosphere model which uses earth and satellite-based observations to simulate the Earth's physical system during events such as La Niña. || ", "hits": 27 }, { "id": 2902, "url": "https://svs.gsfc.nasa.gov/2902/", "result_type": "Visualization", "release_date": "2004-02-12T12:00:00-05:00", "title": "Atmospheric Water Vapor during the 1997-1998 El Niño (WMS)", "description": "Water vapor is a small but significant constituent of the atmosphere, warming the planet due to the greenhouse effect and condensing to form clouds which both warm and cool the Earth in different circumstances. A key feature of global atmospheric water vapor convection is the Intertropical Convergence Zone, the low pressure region within five degrees of the equator where the trade winds converge and solar heating of the atmosphere forces the water-laden air to rise in altitude, form clouds, and then precipitate as rain in the afternoon. This visualization shows the global water vapor distribution in gray and white and the global precipitation in yellow every hour from December 20, 1997 to January 14, 1998. The afternoon thunderstorms in the tropics are seen as a flashing yellow region that moves from east to west, following the sun. This is an El Niño period, when the water to the west of South America is warmer than normal, allowing the atmosphere there to heat up and hold more water. This region feeds a high band of water vapor reaching to the southeastern United States and causes increased humidity and rainfall in that region. This data is from the Goddard Earth Modeling System, a coupled land-ocean-atmosphere model which uses earth and satellite-based observations to simulate the Earth's physical system during events such as El Niño. || ", "hits": 12 } ] }