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SeaWiFS Biosphere: Indonesia …
Title SeaWiFS Biosphere: Indonesia and Australia
Abstract Viewing Indonesia and Australia (data begins at Sept. 97 to June 99)
Completed 1999-08-20
Drought in Southeast Asia
Title Drought in Southeast Asia
Description Little rain has fallen in Southeast Asia after an early end to the rainy season [ http://earthobservatory.nasa.gov/NaturalHazards/natural_hazards_v2.php3?img_id=12569 ] in October 2004, leaving the region in severe drought. From southern China, through the Indochina and Malay Peninsulas, and into some of the islands of Indonesia, crops are shriveling, and in some places, drinking water is scarce. According to news reports, the drought will cost farmers in Thailand up to US $193.2 million after 809,000 hectares of crops were lost. Vietnam has lost US $60 million in crops, and up to 1.3 million people do not have access to clean water. Other countries in the region have been similarly affected, with food shortages in Cambodia and a lack of drinkable water in Hainan, China. Rains eased the drought [ http://www.fas.usda.gov/pecad/highlights/2005/03/China%20Drought/Chinadrought.htm ] in parts of China in late February, but much of the region remains parched. It is the worst drought in 50 years. The above image illustrates the extent of the drought in February 2005. The image shows outgoing longwave radiation, which is a measure of the amount of heat radiated from the surface of the Earth. Since clouds tend to be colder than the Earth?s surface, the measurement shows the distribution of clouds. It is one way to monitor drought because where there are no clouds, there is no rain. In this case, scientists have compared the amount of heat radiated from the surface this year to the average collected between 1979 and 1995. The result shows that significantly fewer cool clouds gathered over Southeast Asia in 2005 than normal, as reflected by the red that stretches from Australia to southern China. This image was derived from measurements made by the TIROS Operational Vertical Sounder (TOVS) onboard the NOAA-POES satellite series. OLR anomaly image created by Jesse Allen, Earth Observatory, using data analyzed by Assaf Anyamba and provided by NOAA National Center for Environmental Prediction [ http://www.ncep.noaa.gov/ ].
Drought in Southeast Asia
Title Drought in Southeast Asia
Description Little rain has fallen in Southeast Asia after an early end to the rainy season [ http://earthobservatory.nasa.gov/NaturalHazards/natural_hazards_v2.php3?img_id=12569 ] in October 2004, leaving the region in severe drought. From southern China, through the Indochina and Malay Peninsulas, and into some of the islands of Indonesia, crops are shriveling, and in some places, drinking water is scarce. According to news reports, the drought will cost farmers in Thailand up to US $193.2 million after 809,000 hectares of crops were lost. Vietnam has lost US $60 million in crops, and up to 1.3 million people do not have access to clean water. Other countries in the region have been similarly affected, with food shortages in Cambodia and a lack of drinkable water in Hainan, China. Rains eased the drought [ http://www.fas.usda.gov/pecad/highlights/2005/03/China%20Drought/Chinadrought.htm ] in parts of China in late February, but much of the region remains parched. It is the worst drought in 50 years. The above image illustrates the extent of the drought in February 2005. The image shows outgoing longwave radiation, which is a measure of the amount of heat radiated from the surface of the Earth. Since clouds tend to be colder than the Earth?s surface, the measurement shows the distribution of clouds. It is one way to monitor drought because where there are no clouds, there is no rain. In this case, scientists have compared the amount of heat radiated from the surface this year to the average collected between 1979 and 1995. The result shows that significantly fewer cool clouds gathered over Southeast Asia in 2005 than normal, as reflected by the red that stretches from Australia to southern China. This image was derived from measurements made by the TIROS Operational Vertical Sounder (TOVS) onboard the NOAA-POES satellite series. OLR anomaly image created by Jesse Allen, Earth Observatory, using data analyzed by Assaf Anyamba and provided by NOAA National Center for Environmental Prediction [ http://www.ncep.noaa.gov/ ].
Early Dry Season in Southeas …
Title Early Dry Season in Southeast Asia
Description In a typical monsoon season in South East Asia, the rains fall until October, but this year, the heavens went dry three to four weeks early. For farmers, who rely on monsoon rains to nourish crops, the early onset of the dry season could mean a reduced harvest. According to the Production Estimates and Crop Assessment Division of the U.S. Department of Agriculture?s Foreign Agricultural Service, the lack of rain affected the tail end of the growing season, and while most crops should be fine, yields could be reduced because of a lack of rain. The government of Thailand has already announced that the rice harvest will be less than expected, and the AFP reports that the Cambodian government is concerned about potential food shortages. In Cambodia, 80-85 percent of all rice is grown during the monsoon season. The early end to the rainy season could spell trouble for the next growing season, which depends on irrigation instead of rainfall. Not only did the rains end early, but less rain fell during the monsoon, and that could mean a shortage of irrigation water stored in reservoirs, particularly if the dry season lasts longer than normal. The above image confirms the absence of clouds associated with precipitation over Southeastern Asia during the month of October. The image is based on measurements of outgoing longwave radiation (OLR), the amount of heat being reflected from the Earth back into space, in Watts per square meter. Clouds tend to be cold, while land masses are warmer. Outgoing longwave radiation can help scientists monitor rainfall by showing where rainfall clouds are, or in this case, where they aren?t. The above image is a comparison of the amount of outgoing longwave radiation observed in October 2004, to the October average observed from 1979 to 1995. Areas that radiated more heat than average are red and those that radiated less are blue. Southeast Asia was radiating more heat than normal in October?a sign that fewer cool clouds covered the region. Indonesia, northern Australia, and parts of China also appear to be warmer, and possibly drier, than normal. This image was derived from measurements made by the TIROS Operational Vertical Sounder (TOVS) onboard the NOAA-POES satellite series. OLR anomaly image created by Jesse Allan, Earth Observatory, using data analyzed by Assaf Anyamba and provided by NOAA National Center for Environmental Prediction [ http://www.ncep.noaa.gov/ ].
Early Dry Season in Southeas …
Title Early Dry Season in Southeast Asia
Description In a typical monsoon season in South East Asia, the rains fall until October, but this year, the heavens went dry three to four weeks early. For farmers, who rely on monsoon rains to nourish crops, the early onset of the dry season could mean a reduced harvest. According to the Production Estimates and Crop Assessment Division of the U.S. Department of Agriculture?s Foreign Agricultural Service, the lack of rain affected the tail end of the growing season, and while most crops should be fine, yields could be reduced because of a lack of rain. The government of Thailand has already announced that the rice harvest will be less than expected, and the AFP reports that the Cambodian government is concerned about potential food shortages. In Cambodia, 80-85 percent of all rice is grown during the monsoon season. The early end to the rainy season could spell trouble for the next growing season, which depends on irrigation instead of rainfall. Not only did the rains end early, but less rain fell during the monsoon, and that could mean a shortage of irrigation water stored in reservoirs, particularly if the dry season lasts longer than normal. The above image confirms the absence of clouds associated with precipitation over Southeastern Asia during the month of October. The image is based on measurements of outgoing longwave radiation (OLR), the amount of heat being reflected from the Earth back into space, in Watts per square meter. Clouds tend to be cold, while land masses are warmer. Outgoing longwave radiation can help scientists monitor rainfall by showing where rainfall clouds are, or in this case, where they aren?t. The above image is a comparison of the amount of outgoing longwave radiation observed in October 2004, to the October average observed from 1979 to 1995. Areas that radiated more heat than average are red and those that radiated less are blue. Southeast Asia was radiating more heat than normal in October?a sign that fewer cool clouds covered the region. Indonesia, northern Australia, and parts of China also appear to be warmer, and possibly drier, than normal. This image was derived from measurements made by the TIROS Operational Vertical Sounder (TOVS) onboard the NOAA-POES satellite series. OLR anomaly image created by Jesse Allan, Earth Observatory, using data analyzed by Assaf Anyamba and provided by NOAA National Center for Environmental Prediction [ http://www.ncep.noaa.gov/ ].
Magnitude 6.3 quake in centr …
Title Magnitude 6.3 quake in central Java
Description A powerful earthquake rattled Yogyakarta, Java, Indonesia, in the early morning hours of May 27, 2006. The quake destroyed more than 60,000 houses in the city, and killed an estimated 6,234 people, reported the World Health Organization on June 6. Though Indonesia experiences frequent earthquakes, the May 27 quake was unusual in that it was centered about 10 kilometers under the Earth's surface, according to the United States Geological Survey (USGS). Most earthquakes in Indonesia occur deep under the Earth's surface where the slab of the Earth's crust that carries Australia (the Australia Plate) sinks beneath the Sunda Plate on which the islands of Indonesia ride. Earthquakes occur in the sometimes-messy grind of colliding plates, but these are centered deep below the Earth's surface. The May 27 earthquake happened near the surface along a fault in the Sunda Plate, about 20 kilometers south-southeast of Yogyakarta. This image shows the topography of the landscape near the earthquake epicenter. Yogyakarta sits in a broad valley between two groups of roughly north-running mountains. The towering Merapi Volcano caps the northeast end of the valley. Behind it is the single peak of the Sundoro Volcano and a cluster of small peaks in the Dieng Volcano Complex. The Slamet and Cereme Volcanoes are west of Merapi in the upper-left corner of the image. The earthquake occurred along a fault east of the mountains that frame Yogyakarta to the east. The image was created from data collected by the Shuttle Radar Topography Mission. The earthquake is not the only geologic activity to threaten the region: the Merapi volcano was also rumbling at the end of May. The volcano sent clouds of hot gas and lava down its slopes on June 6, prompting the evacuation of 11,000 people, said news reports. The ASTER sensor on NASA's Terra [ http://terra.nasa.gov/ ] satellite captured an image [ http://earthobservatory.nasa.gov/NaturalHazards/natural_hazards_v2.php3?img_id=13628 ] of the volcano in action on June 6. The volcano had been showing signs of increased activity since April, but activity picked up after the May 27 earthquake. While volcanic activity and earthquakes are often connected, it is not clear if the May 27 earthquake is directly linked to Merapi's activity, said the USGS. The same underlying geologic processes may have triggered both events. NASA image created by Jesse Allen, Earth Observatory, using Shuttle Radar Topography Mission (SRTM) data provided courtesy of the Unviersity of Maryland's Global Land Cover Facility. [ http://www.landcover.org/ ]
Massive Earthquake Along the …
Title Massive Earthquake Along the Sunda Trench
Description A magnitude 8.7 earthquake rattled northern Sumatra, Indonesia, on March 28, 2005, at 11:09 p.m., local time. At least 330 people are dead, but Indonesian officials expect the toll to soar over 2,000. The earthquake was centered 160 kilometers southeast of the 9.0 quake that triggered the devastating December 26,2004, tsunami, between the islands of Simeulue and Nias. The most severe damage appears to be on Nias, where large parts of the city Gunungsitoli were destroyed. The United States Geological Survey reports that the March 28 quake occurred on the same fault that triggered the December 26 earthquake, probably as a result of stress placed on the fault by the first quake. The above map shows the locations of both earthquakes off the northwest coast of Sumatra. The March 28 earthquake occurred in a section of the fault just south of the part of the fault that slipped on December 26. The last time this section of fault moved was in 1861, when a large earthquake triggered a fatal tsunami. As the image illustrates, the earthquakes occurred just east of the Sunda Trench, the deep underwater canyon where the Australia Plate is being pulled under the Sunda Plate. The plates, giant sections of the Earth's crust, float on a layer of soft rock, propelled by convection currents beneath them. The Australia plate moves about five centimeters northeast in relation to the Sunda plate every year. As the Australia plate has crumbled under the Sunda plate, a number of faults have developed in the Sunda plate, including the thrust fault that produced both the December 26 and March 28 quakes. According to the Pacific Tsumani Warning Center, sea level readings taken after the March 28 earthquake show that a small tsunami was generated, but there have been no reports of damage. Why did the 9.0 earthquake generate a massive tsunami compared to the small wave that came out of the most recent earthquake? By USGS estimates, both earthquakes occurred about 30 kilometers (18.6 miles) beneath the Earth's surface, but the March 28 quake was much smaller and probably didn't displace the same amount of earth as the December 26 quake. For more information about this earthquake, please visit the USGS Earthquake Hazards Program [ http://earthquake.usgs.gov/eqinthenews/2005/usweax/ ]. Map courtesy USGS Earthquake Hazards Program [ http://earthquake.usgs.gov/ ]
North Reef Island, Andaman S …
Title North Reef Island, Andaman Sea
Description On December 26, 2004, one of the largest earthquakes in recorded history struck offshore of the island of Sumatra, Indonesia. The ocean floor heaved in some places and sank in others, creating catastrophic tsunamis that raced across the Indian Ocean. Hundreds of thousands of people died as the waves struck coastlines from Thailand to Sri Lanka to Somalia. In addition to tsunami damage, satellite images of reefs, islands, and coastlines identified signs of permanent elevation change—sinking or uplift—along the fault between the Indo-Australia and Burma plates. [ http://earthobservatory.nasa.gov/NaturalHazards/natural_hazards_v2.php3?img_id=12640 ] In places such as North Reef Island, shown in this pair of images from the Advanced Spaceborne Thermal Emission and Reflection Radiometer (ASTER) [ http://asterweb.jpl.nasa.gov ] on NASA's Terra [ http://terra.nasa.gov ] satellite, the quake lifted the reefs permanently out of the water. The images use visible and infrared light detected by ASTER to make different land surfaces stand out clearly from one another: water is blue, vegetation is red, coral or bare sand appears white. In the "before" image, from December 2, 2004, the submerged reef creates a bright blue glow around the island. In the "after" image, from February 4, 2005, the white coral stands completely up out of the water. It is even tinged with red, which suggests the exposed coral had died, and algae had colonized it. In the weeks and months after the earthquake, satellite images provided broad coverage of an area where ground-based observations were initially very limited. A team of scientists led by Caltech Ph.D. geology student Aron Meltzner discovered changes in elevation along nearly 1,600 kilometers (994 miles) of the tectonic plate boundary. The images revealed that the earthquake rupture extended 100 kilometers (62 miles) farther north than estimates based on seismic and Global Positioning System (GPS) data suggested. The feature article Rise and Fall: Satellites Reveal Full Length of Tsunami-Generating Earthquake [ http://earthobservatory.nasa.gov/Study/Aceh/aceh.html ] describes how scientists used satellite images to map the length of the earthquake rupture zone. The article includes additional satellite and ground-based images of elevation changes resulting from the 2004 Aceh-Andaman earthquake. NASA images created by Jesse Allen, Earth Observatory, using data provided courtesy of the NASA/GSFC/MITI/ERSDAC/JAROS, and U.S./Japan ASTER Science Team. [ http://asterweb.jpl.nasa.gov/ ]
North Reef Island, Andaman S …
Title North Reef Island, Andaman Sea
Description On December 26, 2004, one of the largest earthquakes in recorded history struck offshore of the island of Sumatra, Indonesia. The ocean floor heaved in some places and sank in others, creating catastrophic tsunamis that raced across the Indian Ocean. Hundreds of thousands of people died as the waves struck coastlines from Thailand to Sri Lanka to Somalia. In addition to tsunami damage, satellite images of reefs, islands, and coastlines identified signs of permanent elevation change—sinking or uplift—along the fault between the Indo-Australia and Burma plates. [ http://earthobservatory.nasa.gov/NaturalHazards/natural_hazards_v2.php3?img_id=12640 ] In places such as North Reef Island, shown in this pair of images from the Advanced Spaceborne Thermal Emission and Reflection Radiometer (ASTER) [ http://asterweb.jpl.nasa.gov ] on NASA's Terra [ http://terra.nasa.gov ] satellite, the quake lifted the reefs permanently out of the water. The images use visible and infrared light detected by ASTER to make different land surfaces stand out clearly from one another: water is blue, vegetation is red, coral or bare sand appears white. In the "before" image, from December 2, 2004, the submerged reef creates a bright blue glow around the island. In the "after" image, from February 4, 2005, the white coral stands completely up out of the water. It is even tinged with red, which suggests the exposed coral had died, and algae had colonized it. In the weeks and months after the earthquake, satellite images provided broad coverage of an area where ground-based observations were initially very limited. A team of scientists led by Caltech Ph.D. geology student Aron Meltzner discovered changes in elevation along nearly 1,600 kilometers (994 miles) of the tectonic plate boundary. The images revealed that the earthquake rupture extended 100 kilometers (62 miles) farther north than estimates based on seismic and Global Positioning System (GPS) data suggested. The feature article Rise and Fall: Satellites Reveal Full Length of Tsunami-Generating Earthquake [ http://earthobservatory.nasa.gov/Study/Aceh/aceh.html ] describes how scientists used satellite images to map the length of the earthquake rupture zone. The article includes additional satellite and ground-based images of elevation changes resulting from the 2004 Aceh-Andaman earthquake. NASA images created by Jesse Allen, Earth Observatory, using data provided courtesy of the NASA/GSFC/MITI/ERSDAC/JAROS, and U.S./Japan ASTER Science Team. [ http://asterweb.jpl.nasa.gov/ ]
Plume from Gamkonora
Title Plume from Gamkonora
Description On July 7, 2007, the Gamkonora Volcano on Halmahera, Indonesia, began releasing plumes of ash, according to a report from ABC News, Australia. Over the next few days, the volcano continued its activity, including ejecting flaming rocks. The activity forced the evacuation of some 8,600 residents. At 14:50 East Indonesian Time on July 9, the volcano erupted, according to ReliefWeb. The Moderate Resolution Imaging Spectroradiometer (MODIS) [ http://modis.gsfc.nasa.gov/ ] flying on NASA's Aqua [ http://aqua.nasa.gov/ ] satellite captured this image of Gamkonora releasing a volcanic plume on July 10, 2007. Clouds obscure much of the view, but the plume's beige color distinguishes it from the surrounding clouds.Gamkonora [ http://www.volcano.si.edu/world/volcano.cfm?vnum=0608-04= ] is a stratovolcano composed of alternating layers of hardened lava, solidified ash, and volcanic rocks left by previous eruptions. Rising to a height of 1,635 meters (5,364 feet), it is the highest peak on the island of Halmahera. Its largest recorded eruption occurred in 1673, accompanied by tsunamis that overwhelmed nearby villages. You can download a 250-meter-resolution KMZ file of Gamkonora [ http://earthobservatory.nasa.gov/NaturalHazards/Archive/Jul2007/gamkonora_amo_2007191.kmz ] suitable for use with Google Earth. [ http://earth.google.com/ ] NASA image created by Jesse Allen, using data provided courtesy of the MODIS Rapid Response [ http://rapidfire.sci.gsfc.nasa.gov/ ] team.
Storms in the Java Sea
Title Storms in the Java Sea
Description A ferry carrying more than 600 passengers sank in the Java Sea between the islands of Borneo (image center) and Java (to the south-southwest) just before midnight on December 29, 2006, during high winds and rough seas. On January 1, 2007, a plane carrying more than 100 people crashed on its flight over the Java Sea, high winds and turbulent weather are being investigated as possible causes. The origin of surges of deadly wind in this usually relatively calm region are poorly understood, and the area is not well-monitored with traditional weather equipment. Ocean winds data from NASA's QuikScat satellite may help improve monitoring and understanding of unusual weather in the area. Data obtained from QuikScat on December 30 and January 1 shed new insights into the atmospheric conditions at the time of the tragic incidents described above. In this image from January 1, the different colors reveal different wind speeds. White arrows are wind vectors showing both direction and speed. The data from December 30 and January 1 showed that the strong winds in the Java Sea originated from the surge of a strong winter monsoon from the Asian continent. The monsoon winds blew south across the South China Sea and deflected eastward after they crossed the equator due to the rotation of Earth. The winds in the Java Sea remained strong through January 1, 2007. Associated with the eastward winds, twin cyclones were also observed by QuikScat. (A cyclone is any large-scale atmosphere circulation around a region of low air pressure. The systems spin counter-clockwise in the Northern Hemisphere and clockwise in the Southern Hemisphere.) The stronger cyclone was south of the equator (summer hemisphere) between Java and Australia, and a weaker one was north of the equator (winter hemisphere) west of Borneo. QuikScat measures ocean surface wind speed by sending radar pulses to the surface and measuring the strength of the signals that return to the sensor. The sensor's wide-scale observations make it possible for scientists to interpret local weather events, such as the recent high wind outbreak in the Java Sea region, in the context of the large-scale atmospheric circulation and to confirm connections between the two. QuikScat data are available in near-real time to operational weather forecasting agencies around the world. NASA image courtesy of David Long, Brigham Young University, on the QuikSCAT Science Team, [ http://winds.jpl.nasa.gov/ ] and the Jet Propulsion Laboratory.
Thunderstorm over the Indian …
Title Thunderstorm over the Indian Ocean
Description On January 24, 2007, a minor cloud system blossomed in the Indian Ocean between Indonesia and northwestern Australia. The storm lacked the circulation of a tropical storm, so it never received a name. It did not strike any major populated centers, so it never was a news item. But newsworthy and fascinating are not always the same thing, and the symmetrical shape of the storm and the apparently expanding ring of cloud ripples shown in this image suggest some intriguing atmospheric physics in action. This photo-like image was acquired by the Moderate Resolution Imaging Spectroradiometer (MODIS) [ http://modis.gsfc.nasa.gov/ ] on the Terra [ http://terra.nasa.gov/ ] satellite on January 24, 2007, at 10:10 a.m. local time (2:10 UTC). The circular cloud system in the image was driven by powerful thunderstorms that previously raged beneath the now-ragged cirrus clouds at the system's center. The clouds formed from an afternoon convection system, a vigorous overturning of the air that is common this time of year near Australia's tropical northern coast. The system traveled westward over Austalia's Northern Territory, eventually reaching the coast of Western Australia. Over the Indian Ocean, the cloud system grew rapidly, drawing warm, moist ocean air up into the top of the storm. At the top of this convection system, the air ceased to flow upward and spilled out into an expanding ring. This same process almost always occurs in thunderstorms, but in this case there appears to have been relatively constant wind through a deep layer of the atmosphere, allowing the uplifted air to spread out equally in all directions. The clouds at the top of the storm dispersed as an expanding disk of cirrus cloud. The outflowing air may also have disturbed and amplified existing clouds, making them more reflective. Increased reflection of sunlight makes the clouds seem more brightly white to the MODIS sensor. NASA image by Jesse Allen, Earth Observatory, using data provided courtesy of the MODIS Rapid Response Team, [ http://rapidfire.sci.gsfc.nasa.gov ] Goddard Space Flight Center. Image interpretation provided by George Huffman, NASA Goddard Space Flight Center.
Tropical Cyclone Fay
Title Tropical Cyclone Fay
Description The MODIS instrument onboard NASA's Aqua satellite captured this true-color image of Tropical Cyclone Fay churning in the Pacific waters between Australia and Indonesia. At the time this image was captured, Fay was located approximately 175 miles northwest of Kuri Bay and had winds gusting to 150 mph. Image courtesy Jeff Schmaltz, MODIS Land Rapid Response Team at NASA GSFC.
Flooding in Indonesia
Title Flooding in Indonesia
Description *Animations:* ÿÿlarge (1.5 MB MPEG) ÿÿsmall [ http://earthobservatory.nasa.gov/Newsroom/NewImages/Images/java_rain.qt ] (882 KB QuickTime) This rainfall accumulation map, generated by NASA?s Tropical Rainfall Measurement Mission (TRMM) satellite, shows locally heavy rains which fell over the mountainous terrain of Java, Indonesia, during the last week of December. These rains produced severe flash flooding, mudslides, and numerous deaths across the island. More than 365,000 inhabitants were displaced from their homes due to the severe weather. A larger and persistent area of heavy rain has recently occurred throughout Indonesia, and may be the result of a slow-moving, wavelike tropical disturbance called the Madden Julian Oscillation (MJO). The MJO is generated over the Indian Ocean and moves eastward, crossing over Indonesia, northern Australia, and southern Asia. The disturbance often occurs on a six- to nine-week cycle and can bring several days of torrential rains as it passes over a region. More images of extreme rain over southeast Asia and surrounding areas may found on the TRMM [ http://earthobservatory.nasa.gov/cgi-bin/redirect?http://trmm.gsfc.nasa.gov/ ] Web site. Image and animations courtesy of Jeff Halverson, TRMM Outreach Scientist, and Hal Pierce, TRMM Visualizer, NASA Goddard Space Flight Center
Flooding in Indonesia
Title Flooding in Indonesia
Description *Animations:* ÿÿlarge (1.5 MB MPEG) ÿÿsmall [ http://earthobservatory.nasa.gov/Newsroom/NewImages/Images/java_rain.qt ] (882 KB QuickTime) This rainfall accumulation map, generated by NASA?s Tropical Rainfall Measurement Mission (TRMM) satellite, shows locally heavy rains which fell over the mountainous terrain of Java, Indonesia, during the last week of December. These rains produced severe flash flooding, mudslides, and numerous deaths across the island. More than 365,000 inhabitants were displaced from their homes due to the severe weather. A larger and persistent area of heavy rain has recently occurred throughout Indonesia, and may be the result of a slow-moving, wavelike tropical disturbance called the Madden Julian Oscillation (MJO). The MJO is generated over the Indian Ocean and moves eastward, crossing over Indonesia, northern Australia, and southern Asia. The disturbance often occurs on a six- to nine-week cycle and can bring several days of torrential rains as it passes over a region. More images of extreme rain over southeast Asia and surrounding areas may found on the TRMM [ http://earthobservatory.nasa.gov/cgi-bin/redirect?http://trmm.gsfc.nasa.gov/ ] Web site. Image and animations courtesy of Jeff Halverson, TRMM Outreach Scientist, and Hal Pierce, TRMM Visualizer, NASA Goddard Space Flight Center
Floods in East Africa
Title Floods in East Africa
Description Kenya gets most of its rainfall in two doses: a long rainy season that runs from March or April through July or August, and a short rainy season that starts in September or October and usually tapers off in December. As if trying to make up for lack of rain during the 2005 short rainy season, [ http://earthobservatory.nasa.gov/Newsroom/NewImages/images.php3?img_id=17250 ]which failed entirely, the rainy season that started in October 2006 proved to be unusually heavy. Some locations in Kenya received as much as 200 millimeters more rain than average in October. The heavy rain fell on drought-baked ground, triggering extensive flooding in northern Kenya. The East Africa Standard, [ http://allafrica.com/stories/200610280016.html ] a Nairobi newspaper, reported on October 28 that 10 people had died in the flooding and more than 75,000 were made homeless. The Moderate Resolution Imaging Spectroradiometer (MODIS [ http://modis.gsfc.nasa.gov ]) on NASA's Aqua [ http://aqua.nasa.gov/ ] satellite captured the top image of flooding in northern Kenya on October 30, 2006. Aquamarine, sediment-laden flood water runs through the Laga Bogal and Laga Bor river channels and spreads across the surrounding landscape in places. The Lorian Swamp, in the lower-right corner of the image, appeared dry on October 14, when the lower image was captured. By October 30, water flowed through the swamp. The rain has also spurred plant growth. The arid landscape assumed a green tint in the two weeks that passed between October 14 and October 30. In these false-color images, made with both infrared and visible light, vegetation is bright green, bare or sparsely vegetated ground is tan-pink, and clouds are pale blue and white. In this type of image, water is typically black or dark blue, but sediment has given the water a blue-green color in the top image. Eastern Africa regularly goes through cycles of drought and floods, possibly driven by El Niño. El Niño is a cyclical warming of ocean waters in the central and eastern Pacific that can alter weather patterns around the world. In general, El Niño causes drought in some regions like Indonesia, Australia, and the Philippines, while bringing excess rain to others, including East Africa and the southwestern United States. In September 2006, NASA's JASON satellite recorded a mild El Niño [ http://earthobservatory.nasa.gov/Newsroom/NewImages/images.php3?img_id=17419 ] in the tropical Pacific Ocean. At the same time, drought [ http://earthobservatory.nasa.gov/NaturalHazards/natural_hazards_v2.php3?img_id=13943 ] was settling in over Australia and heavy rain pounded East Africa.Daily images [ http://rapidfire.sci.gsfc.nasa.gov/subsets/?NAfrica_3_07 ] of East Africa are provided by the MODIS Rapid Response Team at NASA Goddard Space Flight Center. NASA images courtesy the MODIS Rapid Response Team [ http://rapidfire.sci.gsfc.nasa.gov ] at NASA GSFC.
Floods in East Africa
Title Floods in East Africa
Description Kenya gets most of its rainfall in two doses: a long rainy season that runs from March or April through July or August, and a short rainy season that starts in September or October and usually tapers off in December. As if trying to make up for lack of rain during the 2005 short rainy season, [ http://earthobservatory.nasa.gov/Newsroom/NewImages/images.php3?img_id=17250 ]which failed entirely, the rainy season that started in October 2006 proved to be unusually heavy. Some locations in Kenya received as much as 200 millimeters more rain than average in October. The heavy rain fell on drought-baked ground, triggering extensive flooding in northern Kenya. The East Africa Standard, [ http://allafrica.com/stories/200610280016.html ] a Nairobi newspaper, reported on October 28 that 10 people had died in the flooding and more than 75,000 were made homeless. The Moderate Resolution Imaging Spectroradiometer (MODIS [ http://modis.gsfc.nasa.gov ]) on NASA's Aqua [ http://aqua.nasa.gov/ ] satellite captured the top image of flooding in northern Kenya on October 30, 2006. Aquamarine, sediment-laden flood water runs through the Laga Bogal and Laga Bor river channels and spreads across the surrounding landscape in places. The Lorian Swamp, in the lower-right corner of the image, appeared dry on October 14, when the lower image was captured. By October 30, water flowed through the swamp. The rain has also spurred plant growth. The arid landscape assumed a green tint in the two weeks that passed between October 14 and October 30. In these false-color images, made with both infrared and visible light, vegetation is bright green, bare or sparsely vegetated ground is tan-pink, and clouds are pale blue and white. In this type of image, water is typically black or dark blue, but sediment has given the water a blue-green color in the top image. Eastern Africa regularly goes through cycles of drought and floods, possibly driven by El Niño. El Niño is a cyclical warming of ocean waters in the central and eastern Pacific that can alter weather patterns around the world. In general, El Niño causes drought in some regions like Indonesia, Australia, and the Philippines, while bringing excess rain to others, including East Africa and the southwestern United States. In September 2006, NASA's JASON satellite recorded a mild El Niño [ http://earthobservatory.nasa.gov/Newsroom/NewImages/images.php3?img_id=17419 ] in the tropical Pacific Ocean. At the same time, drought [ http://earthobservatory.nasa.gov/NaturalHazards/natural_hazards_v2.php3?img_id=13943 ] was settling in over Australia and heavy rain pounded East Africa.Daily images [ http://rapidfire.sci.gsfc.nasa.gov/subsets/?NAfrica_3_07 ] of East Africa are provided by the MODIS Rapid Response Team at NASA Goddard Space Flight Center. NASA images courtesy the MODIS Rapid Response Team [ http://rapidfire.sci.gsfc.nasa.gov ] at NASA GSFC.
Floods in East Africa
Title Floods in East Africa
Description Severe drought early in 2006 followed by widespread flooding [ http://earthobservatory.nasa.gov/NaturalHazards/natural_hazards_v2.php3?img_id=13795 ] during August crippled Ethiopia. In late October and early November, the disaster continued to develop as heavy rain once again sent the Wabe Shebele River over its banks. The swollen river grew to twice its normal size, inundating towns that line its fertile banks, reported the World Food Program [ http://www.alertnet.org/thenews/newsdesk/WFP/4d4580f3cc2d9d49654e66a8daf84c16.htm ]. More than 60 people died in the floods, and many more were impacted. On November 1, 2006, skies cleared, providing the Moderate Resolution Imaging Spectroradiometer (MODIS [ http://modis.gsfc.nasa.gov ]) on NASA's Terra [ http://terra.nasa.gov/ ] satellite a clear view of the floods in southeastern Ethiopia. The Wabe Shabele spreads several kilometers across its flood plain, its water ranging from inky black to light blue. The scene is shown in infrared-enhanced false color to highlight the presence of water on the ground. In this color combination, made with both visible and infrared light, water is typically black, as it is in the lower reaches of the river in this image. Elsewhere in the scene, however, water is light blue because sediment in the water scatters light. The pale blue color blends with the light green of newly growing plants, making it difficult to tell just how extensive the floods are on the west bank of the river. Other waterways on either side of the Wabe Shabele are also filled with mud-laden, light blue water. The lower image, taken on October 7, shows the Wabe Shabele under normal conditions. Though the river is prone to flooding, the attractiveness of living along its banks is clear from this image. Little vegetation is growing in the arid region except along the river's banks, which are lined in green. Conditions changed by November 1. The same rainfall that caused the floods also spurred plant growth, and the landscape went from a barren tan-pink to verdant green. Lines of high clouds, pale blue and white in this false-color image, are scattered across both images. Like much of East Africa, southeastern Ethiopia goes through a regular cycle of floods and droughts. The cycle is in part driven by El Niño, a cyclical warming of ocean waters in the central and eastern Pacific that can alter weather patterns around the world. In general, El Niño causes drought in some regions, such as Indonesia, Australia, and the Philippines, while bringing excess rain to others, including East Africa and the southwestern United States. In September 2006, NASA's JASON satellite recorded a weak El Niño [ http://earthobservatory.nasa.gov/Newsroom/NewImages/images.php3?img_id=17419 ] in the tropical Pacific Ocean. At the same time, drought [ http://earthobservatory.nasa.gov/NaturalHazards/natural_hazards_v2.php3?img_id=13943 ], was settling in over Australia, and heavy rain pounded East Africa. NASA images created by Jesse Allen, Earth Observatory, using data provided courtesy of the MODIS Rapid Response [ http://rapidfire.sci.gsfc.nasa.gov/ ] team.
Floods in East Africa
Title Floods in East Africa
Description Severe drought early in 2006 followed by widespread flooding [ http://earthobservatory.nasa.gov/NaturalHazards/natural_hazards_v2.php3?img_id=13795 ] during August crippled Ethiopia. In late October and early November, the disaster continued to develop as heavy rain once again sent the Wabe Shebele River over its banks. The swollen river grew to twice its normal size, inundating towns that line its fertile banks, reported the World Food Program [ http://www.alertnet.org/thenews/newsdesk/WFP/4d4580f3cc2d9d49654e66a8daf84c16.htm ]. More than 60 people died in the floods, and many more were impacted. On November 1, 2006, skies cleared, providing the Moderate Resolution Imaging Spectroradiometer (MODIS [ http://modis.gsfc.nasa.gov ]) on NASA's Terra [ http://terra.nasa.gov/ ] satellite a clear view of the floods in southeastern Ethiopia. The Wabe Shabele spreads several kilometers across its flood plain, its water ranging from inky black to light blue. The scene is shown in infrared-enhanced false color to highlight the presence of water on the ground. In this color combination, made with both visible and infrared light, water is typically black, as it is in the lower reaches of the river in this image. Elsewhere in the scene, however, water is light blue because sediment in the water scatters light. The pale blue color blends with the light green of newly growing plants, making it difficult to tell just how extensive the floods are on the west bank of the river. Other waterways on either side of the Wabe Shabele are also filled with mud-laden, light blue water. The lower image, taken on October 7, shows the Wabe Shabele under normal conditions. Though the river is prone to flooding, the attractiveness of living along its banks is clear from this image. Little vegetation is growing in the arid region except along the river's banks, which are lined in green. Conditions changed by November 1. The same rainfall that caused the floods also spurred plant growth, and the landscape went from a barren tan-pink to verdant green. Lines of high clouds, pale blue and white in this false-color image, are scattered across both images. Like much of East Africa, southeastern Ethiopia goes through a regular cycle of floods and droughts. The cycle is in part driven by El Niño, a cyclical warming of ocean waters in the central and eastern Pacific that can alter weather patterns around the world. In general, El Niño causes drought in some regions, such as Indonesia, Australia, and the Philippines, while bringing excess rain to others, including East Africa and the southwestern United States. In September 2006, NASA's JASON satellite recorded a weak El Niño [ http://earthobservatory.nasa.gov/Newsroom/NewImages/images.php3?img_id=17419 ] in the tropical Pacific Ocean. At the same time, drought [ http://earthobservatory.nasa.gov/NaturalHazards/natural_hazards_v2.php3?img_id=13943 ], was settling in over Australia, and heavy rain pounded East Africa. NASA images created by Jesse Allen, Earth Observatory, using data provided courtesy of the MODIS Rapid Response [ http://rapidfire.sci.gsfc.nasa.gov/ ] team.
2002 December 3 See Explanat …
Title 2002 December 3 See Explanation. Clicking on the picture will download the highest resolution version available.
Explanation On December 4th [ http://sunearth.gsfc.nasa.gov/eclipse/TSE2002/ TSE2002.html ], for the second time in as many years, the Moon's shadow will track [ http://sunearth.gsfc.nasa.gov/eclipse/TSE2002/TSE2002txt/ T02animate.html ] across southern Africa bringing a total solar eclipse [ http://www.mreclipse.com/Special/SEprimer.html ] to African skies. Reaching Africa just before 6:00 Universal Time [ http://aa.usno.navy.mil/faq/ docs/UT.html ], the narrow path of totality - corresponding to the path of the Moon's umbra or dark central shadow - will run eastward through Angola, Namibia (Caprivi Strip), Botswana, Zimbabwe, South Africa's Kruger National Park [ http://profjohn.com/el/el2002/index.html ], and Mozambique. Moving out across the Indian Ocean it will ultimately cross onto the Australian continent at sunset (around 9:10 UT [ http://www.csiro.au/helix/eclipse/ ]). Observers directly in this path could catch at most a minute or so of the eclipse at its total phase, but at least a partial eclipse will be visible over much of Africa, Australia [ http://astronomy.swin.edu.au/solar_eclipse_2002/ ], some parts of Indonesia, and eastern Antarctica. While watching [ http://www.mreclipse.com/TSE01reports/ TSE01galleryA.html ] last year's June 21 eclipse, astronomer Fred Espenak recorded a series of exposures used to construct this dramatic composite image. The sequence follows the 2001 geocentric celestial event from start to finish above a thorny acacia tree [ http://www.blueplanetbiomes.org/ acacia_tortillis.htm ] near Chisamba, Zambia.
NASA Radar Gives Fresh Look …
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Flooding Starts to Break Que …
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creator NASA -- NASA image created by Jesse Allen, Earth Observatory Team, using AMSR-E data obtained from www.ssmi.com/ Remote Sensing Systems .
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Forest Change on New Ireland …
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Forest Change on New Ireland …
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Thunderstorm over the Indian …
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On January 24, 2007, a minor …
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Jason Satellite Observes Mil …
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In September 2006, NASA sate …
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creator NASA -- NASA image by Akiko Hayashi, Jet Propulsion Laboratory.
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Jason Satellite Observes Mil …
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In September 2006, NASA sate …
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creator NASA -- NASA image by Akiko Hayashi, Jet Propulsion Laboratory.
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Plume from Gamkonora: Natura …
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On July 7, 2007, the Gamkono …
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Western Flores Home to New H …
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The Indonesian islands are s …
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creator NASA -- NASA image created by Jesse Allen, Earth Observatory, using Landsat data obtained from the University of Maryland's glcf.umiacs.umd.edu/index.shtml Global Land Cover Facility .
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Western Flores Home to New H …
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The Indonesian islands are s …
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creator NASA -- NASA image created by Jesse Allen, Earth Observatory, using Landsat data obtained from the University of Maryland's glcf.umiacs.umd.edu/index.shtml Global Land Cover Facility .
identifier l7_flores_29sep99
Tectonic Uplift near Sumatra …
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creator NASA -- NASA image by Robert Simmon, based on data provided by the NASA/GSFC/METI/ERSDAC/JAROS, and U.S./Japan asterweb.jpl.nasa.gov/ ASTER Science Team
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Another Kelvin Wave Strenght …
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In the Pacific Ocean around …
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creator NASA -- NASA/JPL Ocean Surface Topography Team.
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El Nino and Rainfall: Image …
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At the end of 2006, East Afr …
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creator NASA -- NASA image created by Jesse Allen, Earth Observatory, using rainfall data provided courtesy of the precip.gsfc.nasa.gov/ Global Precipitation Climatology Product team at NASA Goddard Space Flight Center.
identifier precipanom_trmm_200611
Earth observations taken dur …
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Tropical Cyclone Fay: Natura …
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The MODIS instrument onboard …
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Early Dry Season in Southeas …
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In a typical monsoon season …
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creator NASA -- NASA image by Jesse Allen, Earth Observatory, using data analyzed by Assaf Anyamba and provided by NOAA's www.ncep.noaa.gov/ National Center for Environmental Prediction .
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Early Dry Season in Southeas …
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In a typical monsoon season …
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creator NASA -- NASA image by Jesse Allen, Earth Observatory, using data analyzed by Assaf Anyamba and provided by NOAA's www.ncep.noaa.gov/ National Center for Environmental Prediction .
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Closeup of Anak Krakatau: Im …
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On an atlas of the world, An …
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creator NASA -- NASA image by Robert Simmon, based on data copyright www.spaceimaging.com/ Space Imaging
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Floods in East Africa: Natur …
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Floods in East Africa: Natur …
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North Reef Island, Andaman S …
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On December 26, 2004, one of …
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creator NASA -- NASA images created by Jesse Allen, Earth Observatory, using data provided courtesy of the NASA/GSFC/MITI/ERSDAC/JAROS, and U.S./Japan asterweb.jpl.nasa.gov/ ASTER Science Team.
identifier nreefis_ast_2005035
La Nina In Progress : Image …
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Researchers at the National …
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creator NASA -- NASA image created by Jesse Allen, Earth Observatory, using data provided courtesy of Chelle Gentemann and Frank Wentz, Remote Sensing Systems.
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La Nina In Progress : Image …
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creator NASA -- NASA image created by Jesse Allen, Earth Observatory, using data provided courtesy of Chelle Gentemann and Frank Wentz, Remote Sensing Systems.
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Magnitude 6.3 quake in centr …
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A powerful earthquake rattle …
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Tsunami Damage in Java: Imag …
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Off the island of Java, Indo …
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CALIPSO and CloudSat Images: …
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Remote-sensing devices that …
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creator NASA -- Images courtesy NASA/JPL/NOAA/The Cooperative Institute for Research in the Atmosphere (CIRA), Colorado State University (top), and Kathy Powell, SAIC and NASA Langley Research Center (lower).
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La Nina Greenup Patterns: Im …
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La Nina's fingerprint is all …
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