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Animation Identification Numbers 700 through 799
Movie ID Title
Viewing the Pacific Ocean (data begins at Sept. 97 to June 99)   700   SeaWiFS Biosphere: Pacific Ocean
Viewing South America (data begins at Sept. 97 to June 99)   701   SeaWiFS Biosphere: South America
Viewing North America (data begins at Sept. 97 to June 99)   702   SeaWiFS Biosphere: North America
Viewing the whole Earth on a flat map.   703   SeaWiFS Biosphere: Whole Earth
Rotating Globe (SeaWiFS data begins at Sept. 97 to June 99)   704   SeaWiFS Biosphere: Rotating Globe
Rotating Globe then pause and then zoom onto Africa (dates Jan. 98 to Dec.98)   705   SeaWiFS Biosphere: Rotating Globe with Zoom to Africa
Rotating Globe then pause and then zoom onto North America (dates Jan. 98 to Dec.98)   706   SeaWiFS Biosphere: Rotating Globe with Zoom to North America
Rotating Globe then pause and then zoom onto the Pacific Ocean (dates Jan. 98 to Dec.98)   707   SeaWiFS Biosphere: Rotating Globe With Zoom to Pacific Ocean
Total ozone over Antarctica from June 1999 through September 1999, as measured by Earth Probe TOMS   708   TOMS Ozone Over Antarctica: June 1999 to September 1999
Aerosol index measurements indicating dust blowing westwards from Africa across the Atlantic Ocean during the period July 1, 1988 to September 29, 1988. as measured by Earth Probe TOMS   709   Aerosol Index over the Atlantic Ocean: July 1, 1988 to September 29, 1988
The evolution of the ozone hole over Antarctica as shown through measurements of average ozone for September for the years 1979 through 1999, excluding 1995. These measurements were made by the TOMS instruments on Nimbus-7, Meteor-3 and Earth Probe. Dark blue represent regions of low ozone and red represents regions of high ozone.   710   Average September Ozone Levels over Antarctica for 1979 to 1999
The evolution of ozone over the Arctic as shown through measurements of average ozone for March for the years 1979 through 1999, excluding 1995 and 1996. These measurements were made by the TOMS instruments on Nimbus-7, Meteor-3 and Earth Probe. Dark blue represent regions of low ozone and red represents regions of high ozone.   711   Average March Ozone Levels over the Arctic for 1979 to 1999
Ozone measurements from Earth Probe TOMS for February 1, 1997 through May 31, 1997 showing the formation of an Arctic ozone hole   712   Arctic Ozone Hole from Earth Probe TOMS: February 1, 1997 through May 31, 1997
Total ozone measurements from Earth Probe TOMS over Antarctica for the period June 1998 through December 1998   713   Antarctic Ozone from Earth Probe TOMS: June 1998 through December 1998
Total ozone measurements from Earth Probe TOMS over Antarctica for the period July 25, 1999 through September 25, 1999   714   Antarctic Ozone from Earth Probe TOMS: July 25, 1999 through September 25, 1999
A rotation of the Earth from a view of North America to a view of the Arctic, used as an element in a fade to ozone data over the Arctic.   715   True Color Rotate to the Arctic: Match Frame
A rotation of the Earth from a view of North America to a view of Antarctica, used as an element in a fade to ozone data over Antarctica.   716   True Color Rotate to Antarctic: Match Frame
Total ozone over Antarctica for July 25, 1999 through October 3, 1999, as measured by Earth Probe TOMS   717   Ozone update on 3 October 1999
The peak of the Antarctic Ozone Hole in 1999, as measured by Earth Probe TOMS on September 15, 1999.   718   Peak of the Antarctic Ozone Hole: September 15, 1999 (Still)
Total ozone over the arctic for September 1, 1999 through November 30, 1999, as measured by Earth Probe TOMS   719   Arctic Ozone from TOMS: September 1, 1999 through November 30, 1999
A fly-in to Tropical Storms Emily and Cindy on August 25, 1999, showing the three-dimensional structure of the precipitation as measured by the Precipitation Radar instrument on TRMM. In this animation, a surface of constant precipitation is colored by the value of the precipitation on the ground under the surface. The global cloud cover data was measured by GOES.   720   Tropical Storms Emily and Cindy from TRMM: August 25, 1999
A fly-in to Hurricane Dennis on August 27, 1999, showing the three-dimensional structure of the precipitation as measured by the Precipitation Radar instrument on TRMM. In this animation, a surface of constant precipitation is colored by the value of the precipitation on the ground under the surface. The global cloud cover data was measured by GOES.   721   Hurricane Dennis from TRMM: August 27, 1999
A fly-in to Hurricane Dennis on August 27, 1999, showing the three-dimensional structure of the precipitation as measured by the Precipitation Radar instrument on TRMM. In this animation, a surface of constant precipitation is colored by the value of the precipitation on the ground under the surface. The global cloud cover data was measured by GOES.   722   Hurricane Dennis from TRMM: August 27, 1999 (Slower)
Hurricane Dennis Aug. 30, 1999 - SeaWiFS Data   723   Hurricane Dennis - August 30, 1999
Hurricane Dennis on August 26, 1999   724   Hurricane Dennis Aug. 26, 1999 - SeaWiFS Data
Hurricane Dennis and tropical storm Cindy on Aug. 27, 1999.   725   Hurricane Dennis and Tropical Storm Cindy Aug. 27, 1999 - SeaWiFS Data
A fly-in to Hurricane Floyd on September 13, 1999, showing the three-dimensional structure of the precipitation as measured by the Precipitation Radar instrument on TRMM. In this animation, a surface of constant precipitation is colored by the value of the precipitation on the ground under the surface. The global cloud cover data was measured by GOES.   726   Hurricane Floyd from TRMM: September 13, 1999
Zoom in to Hurricane Floyd as seen by SeaWiFS on September 14, 1999   727   Hurricane Floyd from SeaWiFS: September 14, 1999
A fly-in to Hurricane Floyd on September 16, 1999, showing the three-dimensional structure of the precipitation as measured by the Precipitation Radar instrument on TRMM. In this animation, a surface of constant precipitation is colored by the value of the precipitation on the ground under the surface. The global cloud cover data was measured by GOES.   728   Hurricane Floyd from TRMM: September 16, 1999
A fly-in to Hurricane Gert on September 16, 1999, showing the three-dimensional structure of the precipitation as measured by the Precipitation Radar instrument on TRMM. In this animation, a surface of constant precipitation is colored by the value of the precipitation on the ground under the surface. The global cloud cover data was measured by GOES.   729   Hurricane Gert from TRMM: September 16, 1999
SeaWiFS image of the east coast of the United States taken in April 1998   730   A Year Before Hurricane Floyd: East Coast Zoom April 1998 from SeaWiFS
SeaWiFS image of the east coast of the United States taken September 16, 1999   731   After Hurricane Floyd: East Coast Zoom September 16, 1999 from SeaWiFS
Flying up the east coast of the United States from Florida to North Carolina using a SeaWiFS image taken April 1998   732   A Year Before Hurricane Floyd: East Coast Flyover April 1998 from SeaWiFS
Flying up the east coast of the United States from Florida to North Carolina using a SeaWiFS image taken September 16, 1999   733   After Hurricane Floyd: East Coast Flyover September 16, 1999 from SeaWiFS
A fly-in to Hurricane Irene on October 14, 1999, showing the three-dimensional structure of the precipitation as measured by the Precipitation Radar instrument on TRMM. In this animation, a surface of constant precipitation is colored by the value of the precipitation on the ground under the surface. The global cloud cover data was measured by GOES.   734   Hurricane Irene from TRMM: October 14, 1999
Zoom in to a SeaWiFS image of Hurricane Irene, taken October 14, 1999   735   Push In to Hurricane Irene from SeaWiFS: October 14, 1999
Panning across a SeaWiFS image of Hurricane Irene, taken October 14, 1999   736   Pan across Hurricane Irene from SeaWiFS: October 14, 1999
The entire narrated Images video. (NOTE: 79 MB DOWNLOAD)   737   Images of Earth and Space: SC99 Edition
A view of the east coast of the United States from SeaWiFS on September 16, 1999, showing Hurricane Floyd   738   Hurricane Floyd from SeaWiFS: September 16, 1999
The Carolina coast on September 17, 1999 from SeaWiFS   739   Carolina Coast from SeaWiFS: September 17, 1999
The Carolina coast on September 23, 1999 from SeaWiFS   740   Carolina Coast from SeaWiFS: September 23, 1999
The Carolina coast on October 16, 1999 from SeaWiFS   741   Carolina Coast from SeaWiFS: October 26, 1999
Landsat 7 Cape Hatteras Pamlico Sound, over powered by rain, the rivers become chocked with silt.   742   Landsat 7 Cape Hatteras Pamlico Sound
This animation starts with a false-color map of tree heights north of San Jose, Costa Rica, and changes to a close-up 3D cut-away of a section of the forest with simulated green canopy. Data from LVIS observations taken in March, 1998.   743   LVIS Tree Height Cross Section (Tree Texture)
This animation starts with a false-color map of tree heights north of San Jose, Costa Rica, and changes to a close-up 3D cut-away of a section of the forest, also in false color. Data from LVIS observations taken in March, 1998.   744   LVIS Tree Height Cross Section (false color)
Aerosol concentrations over Borneo from February 1, 1998 to March 1, 1998 as measured by Earth Probe TOMS   746   Aerosols over Borneo from Earth Probe TOMS: February 1, 1998 to March 1, 1998
Cloud cover over Borneo for March 1, 1998 superimposed over a topographic image   747   Cloud Cover over Borneo: March 1, 1998
Cloud cover and fires from biomass burning for March 1, 1998 indicated on a topographic map of northern Borneo   748   TRMM Biomass Burning: Smoke Inhibits Rainfall Cloud Cover With Fires March 1, 1998
Hot spots from biomass burning indicated on a topographic map of Borneo   749   TRMM Biomass Burning: Hot Spots on March 1, 1998
Water droplet size for precipitation over Borneo on March 1, 1998   750   TRMM Biomass Burning: Water Droplet Size March 1, 1998
Water droplet size correlated with precipitation over northern Borneo on March 1, 1998   751   TRMM Biomass Burning: Water Droplet Size and Precipitation March 1, 1998
Precipitation over northern Borneo on March 1, 1998   752   TRMM Biomass Burning: Precipitation March 1, 1998
Correlated water droplet size, precipitation, and fires over northern Borneo on March 1, 1998   753   TRMM Biomass Burning - Smoke Inhibits Rainfall: Water Droplet Size, Precipitation and Fires March 1, 1998
Correlated water droplet size, precipitation, fires, and cloud cover over northern Borneo on March 1, 1998   754   TRMM Biomass Burning: Water Droplet Size, Precipitation and Fires With Cloud Cover March 1, 1998
Correlated water droplet size and fires over northern Borneo on March 1, 1998   755   TRMM Biomass Burning - Smoke Inhibits Rainfall: Water Droplet Size and Fire March 1, 1998
Zoom down to the Pamlico River in North Carolina, from Landsat imagery taken on July 6, 1999.   756   Landsat-7 Pamlico River Zoom: July 6, 1999
Zoom down to the Pamlico River in North Carolina, from Landsat imagery taken on September 23, 1999.   757   Landsat-7 Pamlico River Zoom: September 23, 1999
Side-by-side comparison of Loch Raven, Maryland in May and August, 1999, from Landsat imagery   758   Maryland Drought: Side by Side Comparison of Loch Raven in May and August, 1999
Dissolve between Landsat imagery of Loch Raven, Maryland in May and August of 1999, showing the effects of the drought   759   Maryland Drought: Loch Raven Dissolve Between May and August 1999
Compare Marylands Liberty Reservoir between July 1997 and July 1999: 2 Years of Drought   760   Maryland Drought: Zoom down to Liberty Reservoir Comparing July 1997 with July 1999 (with dates)
Compare Marylands Liberty Reservoir between July 1997 and July 1999 - No Dates   761   Maryland Drought: Zoom down to Liberty Reservoir comparing July 1997 and July 1999 (without dates)
A side-by-side image of Marylands Liberty Reservoir comparing July, 1997 and July, 1999, from Landsat imagery   762   Maryland Drought: Side-by-side Comparison of Liberty Reservoir in 1997 and 1999 (Without Dates)
A side-by-side image of Marylands Liberty Reservoir comparing July, 1997 and July, 1999, from Landsat imagery   763   Maryland Drought: Side-by-side Comparison of Liberty Reservoir in 1997 and 1999 (With Dates)
Zoom from a global view of Mars from Viking imagery to the Mars Polar Lander landing site near the south pole of Mars, using a false color inset of MOLA topography data. White colors indicate elevations in excess of 3012 meters, red shows elevations between 2500 and 3012 meters, yellow shows elevations from 2450 to 2500 meters, dark cyan shows elevations from 2150 to 2450 meters, dark violet shows elevations from 320 to 2150 meters. The topography in these images is vertically exaggerated by a factor of 5.   764   Mars Polar Lander Landing Site: Global View to False Color MOLA Inset
Overhead view of the Mars Polar Lander landing site   765   Close Up Fly Over of Mars Polar Lander Landing Area in True Color
High altitude view of the Mars Polar Lander landing site in false color, with color representing topography as measured by MOLA.   766   Close Up Fly Over of Mars Polar Lander Landing Area in False Color
Rotating a Martian globe, using Viking imagery, to the south pole and fading to topography data from MOLA, showing that large portions of the ice cap may be covered by dust. Note that the permanent frozen cap of carbon dioxide ice is not located directly at the south pole. White colors indicate elevations in excess of 3012 meters, and dark violet shows elevations from 320 to 2150 meters.   767   A Comparison of Visible and Topographic Data for the Martian South Pole: Version 1
A visible image of the Martian south pole, from Viking data, overlaid over a false color image of the topography of the region as measured by MOLA   768   A Comparison of Visible and Topographic Data for the Martian South Pole: Version 2
A close-up view of the Martian south pole with grid lines, from Viking imagery   769   A Rotating True Color View of the Martian South Pole
A rotating view of the Martian south pole using MOLA topography data   770   A Rotating False Color View of the Martian South Pole from MOLA
A rotating view of the Martian south pole using MOLA topography data. This animation uses a color table designed to highlight the topography at the south pole. White colors indicate elevations in excess of 3012 meters, red shows elevations between 2500 and 3012 meters, yellow shows elevations from 2450 to 2500 meters, dark cyan shows elevations from 2150 to 2450 meters, dark violet shows elevations from 320 to 2150 meters.   771   A Rotating False Color View of the Martian South Pole from MOLA: New Color Map
The southern hemisphere of Mars from Viking imagery   772   Push in South of the Hellas Basin using Viking Imagery
A view of the southern hemisphere of Mars showing topography data from MOLA. Blue tones represent elevations of less than 2 kilometers, while reddish tones are greater than about 2.8 kilometers, relative to the mean equatorial height of Mars.   773   Push in South of the Hellas Basin Showing Topography from MOLA
A view of the topography of the southern hemisphere of Mars, using a color table designed to highlight the topography at the south pole. White colors indicate elevations in excess of 3012 meters, red shows elevations between 2500 and 3012 meters, yellow shows elevations from 2450 to 2500 meters, dark cyan shows elevations from 2150 to 2450 meters, dark violet shows elevations from 320 to 2150 meters.   774   Push in South of the Hellas Basin Showing Topography from MOLA: New Color Map
Watching Viking imagery data of the southern hemisphere of Mars on a rotating globe   775   Mars Southern Hemisphere Rotation in True Color from Viking
Topography of Argyre Planitia as measured by MOLA   776   Mars Southern Hemisphere Rotation in False Color from MOLA
An animation of x-ray images of the North Pole on May 11, 1999 taken by the PIXIE instrument on Polar, indicating enegetic electron fluxes striking the upper atmosphere   777   Polar: PIXIE at Apogee on May 11, 1999 (North)
An animation of x-ray images of the North Pole on May 11, 1999 taken by the PIXIE instrument on Polar, indicating enegetic electron fluxes striking the upper atmosphere   778   Polar: PIXIE at Perigee on May 11, 1999 (North)
An animation of x-ray images of the South Pole on May 11, 1999 taken by the PIXIE instrument on Polar, indicating enegetic electron fluxes striking the upper atmosphere   779   Polar: PIXIE at Perigee 1 on May 11, 1999 (South)
An animation of x-ray images of the South Pole on May 11, 1999 taken by the PIXIE instrument on Polar, indicating enegetic electron fluxes striking the upper atmosphere   780   Polar: PIXIE at Perigee 2 on May 11, 1999 (South)
An x-ray image of the South Pole on May 11, 1999 taken by the PIXIE instrument on Polar, indicating enegetic electron fluxes striking the upper atmosphere   781   Polar: PIXIE at T055798 on May 11, 1999 at 05:05
An x-ray image of the South Pole on May 11, 1999 taken by the PIXIE instrument on Polar, indicating enegetic electron fluxes striking the upper atmosphere   782   Polar: PIXIE at T055798 on May 11, 1999 at 22:55
A comparison of images of the aurora over the North Pole on May 11, 1999, when there was no solar wind, and November 13, 1999, during normal solar wind conditions.   783   Polar Visible Aurora: North Pole Comparison between May 11, 1999 and November 13, 1999 (Continents)
A comparison of images of the aurora over the North Pole on May 11, 1999, when there was no solar wind, and November 13, 1999, during normal solar wind conditions.   784   Polar Visible Aurora: North Pole Comparison Between May 11, 1999 and November 13, 1999 (Grid)
Visible aurora over the North Pole on April 17, 1999 as measured by Polar   785   Polar Visible Aurora: High Solar Wind Conditions on April 17, 1999 over the North Pole
Visible aurora over the North Pole on May 11, 1999 as measured by Polar   786   Polar Visible Aurora: Low Solar Wind Conditions on May 11, 1999 over the North Pole
Visible aurora over the South Pole on May 11, 1999 as measured by Polar   787   Polar Visible Aurora: Low Solar Wind Conditions on May 11, 1999 over the South Pole
Visible aurora over the North Pole on November 13, 1999 as measured by Polar   788   Polar Visible Aurora: Normal Solar Wind Conditions on November 13, 1999 over the North Pole
An animation of sea surface height anomaly in the Pacific Ocean from January 1997 to December 1999 as measured by TOPEX-Poseidon   789   El Niño-La Niña Sea Surface Height Anomaly: January 1997 through December 1999
An animation of sea surface temperature anomaly in the Pacific Ocean from January 1997 through December 1999 as measured by NOAA AVHRR   790   El Niño-La Niña Sea Surface Temperature Anomaly: January 1997 through December 1999
An animation of sea surface temperature and height anomalies in the Pacific for January 1997 through December 1999 from NOAA AVHRR and TOPEX Poseidon   791   El Niño-La Niña Sea Surface Temperature and Height Anomaly 3D Isometric View: Jan. 1997 through Dec. 1999
An animation of sea surface temperature anomaly, sea surface height anomaly, and sea temperature anomaly at depth in the Pacific Ocean from January 1997 through December 1999 as measured by NOAA AVHRR, TOPEX Poseidon, and the TAO TRITON Array   792   El Niño-La Niña Cross-section of Temperature and Height Anomalies: Jan. 1997 through Dec. 1999
El Niño-La Niña sea surface temperature, height, and wind anomalies in the Pacific for January 1997 through December 1999. Wind anomalies stop at September 1999.   793   El Niño-La Niña Sea Surface Temperature, Height, and Wind Anomalies: Jan. 1997 through Dec. 1999
Zooming from a view of the entire Earth down to Washington DC, as first Landsat data at 15 meter resolution, then aerial photography data at 1 meter resolution appears.   794   Digital Earth Workbench: Zoom Down to Washington D.C.
Panning around a 3D model of the Washington monument, followed by a zoom out to see the east coast of North America   795   Digital Earth Workbench: The Washington Monument in 3D
Zooming from the east coast of North America to the Florida Keys, adding first a Landsat image, then an aerial photograph, and then a benthic habitat map, before zooming back out to a continental view.   796   Digital Earth Workbench: Multiple Views of the Florida Keys
Zooimg from a continental view of North America to a Landsat image of Yellowstone, then adding a time-dependent dataset of fire extents from 1991, then returning to a continental view   797   Digital Earth Workbench: Yellowstone Fires
Global sea surface temperature is added to the globe, then the transparency of that data set is interactively modified   798   Digital Earth Workbench: Global Sea Surface Temperature
Transparent clouds are added on a layer above an Earth with a sea surface temperature dataset   799   Digital Earth Workbench: Sea Surface Temperature with Cloud Cover
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