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Browse All : Images of Indonesia and Goddard Space Flight Center (GSFC)

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Aerosols from Earth Probe TO …
Title Aerosols from Earth Probe TOMS: Indonesia from 8/7/97 to 11/15/97 (3 times @ 1.5 days/sec)
Completed 1998-12-07
Aerosols from Earth Probe TO …
Title Aerosols from Earth Probe TOMS: Indonesia from 6/29/97 to 1/13/98 (3 times @ 6 days/sec)
Completed 1998-12-07
Atmospheric Water Vapor duri …
Title Atmospheric Water Vapor during the 1998 La Niña (WMS)
Abstract 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.
Completed 2004-07-06
SeaWiFS Indonesian Smoke
Title SeaWiFS Indonesian Smoke
Completed 1998-01-01
Aerosols from Earth Probe TO …
Title Aerosols from Earth Probe TOMS: Venezuela from 3/11/98 to 4/4/98 (3 times @ 1.5 days/sec)
Completed 1998-12-07
AURA/OMI Tropospheric Ozone …
Title AURA/OMI Tropospheric Ozone over Indonesia
Abstract Aura's instruments study tropospheric, or low-level atmospheric chemistry and will monitor air pollution around the world on a daily basis. Aura measures five of the six 'Criteria Pollutants' identified by the U.S. Environmental Protection Agency.
Completed 2004-12-07
AURA/OMI Tropospheric Ozone …
Title AURA/OMI Tropospheric Ozone over Indonesia
Abstract Aura's instruments study tropospheric, or low-level atmospheric chemistry and will monitor air pollution around the world on a daily basis. Aura measures five of the six 'Criteria Pollutants' identified by the U.S. Environmental Protection Agency.
Completed 2004-12-07
AURA/OMI Tropospheric Ozone …
Title AURA/OMI Tropospheric Ozone over Indonesia
Abstract Aura's instruments study tropospheric, or low-level atmospheric chemistry and will monitor air pollution around the world on a daily basis. Aura measures five of the six 'Criteria Pollutants' identified by the U.S. Environmental Protection Agency.
Completed 2004-12-07
TRMM Rainmap for September 1 …
Title TRMM Rainmap for September 1998: Indonesia
Completed 1998-12-07
Aerosols from Nimbus TOMS: I …
Title Aerosols from Nimbus TOMS: Indonesia 1979 - 1992 Oct 1-15 Averages
Completed 1998-12-07
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
Indonesian Tropospheric Ozon …
Title Indonesian Tropospheric Ozone and Aerosol Index
Abstract Researchers have discovered that smoke and smog move in different ways through the atmosphere. A series of unusual events several years ago created a blanket of pollution over the Indian Ocean. In this animation, significant smog or tropospheric ozone is represented by red and green and regions of significant smoke index are in shades of white and gray.
Completed 2000-10-19
Indonesian Tropospheric Ozon …
Title Indonesian Tropospheric Ozone and Aerosol Index
Abstract Researchers have discovered that smoke and smog move in different ways through the atmosphere. A series of unusual events several years ago created a blanket of pollution over the Indian Ocean. In this animation, significant smog or tropospheric ozone is represented by red and green and regions of significant smoke index are in shades of white and gray.
Completed 2000-10-19
Indonesian Tropospheric Ozon …
Title Indonesian Tropospheric Ozone and Aerosol Index
Abstract Researchers have discovered that smoke and smog move in different ways through the atmosphere. A series of unusual events several years ago created a blanket of pollution over the Indian Ocean. In this animation, significant smog or tropospheric ozone is represented by red and green and regions of significant smoke index are in shades of white and gray.
Completed 2000-10-19
Indonesian Tropospheric Ozon …
Title Indonesian Tropospheric Ozone and Aerosol Index
Abstract Researchers have discovered that smoke and smog move in different ways through the atmosphere. A series of unusual events several years ago created a blanket of pollution over the Indian Ocean. In this animation, significant smog or tropospheric ozone is represented by red and green and regions of significant smoke index are in shades of white and gray.
Completed 2000-10-19
Tropospheric Ozone from Eart …
Title Tropospheric Ozone from Earth Probe TOMS: Indonesia - 9 Day Averages (May 1997 - May 1998)
Completed 1998-12-07
Sea Surface Temperature arou …
Title Sea Surface Temperature around Indonesia from TRMM: January 1998 through July 1998
Completed 1998-07-01
Tropospheric Ozone and Smoke …
Title Tropospheric Ozone and Smoke from Earth Probe TOMS: Indian Ocean to Indonesia Zoom
Abstract Researchers have discovered that smoke and smog move in different ways through the atmosphere. A series of unusual events several years ago created a blanket of pollution over the Indian Ocean. In this animation, significant smog or tropospheric ozone is represented by red and green and regions of significant smoke index are in shades of white and gray.
Completed 2001-03-06
Tropospheric Ozone and Smoke …
Title Tropospheric Ozone and Smoke from Earth Probe TOMS: Indian Ocean to Indonesia Zoom
Abstract Researchers have discovered that smoke and smog move in different ways through the atmosphere. A series of unusual events several years ago created a blanket of pollution over the Indian Ocean. In this animation, significant smog or tropospheric ozone is represented by red and green and regions of significant smoke index are in shades of white and gray.
Completed 2001-03-06
Tropospheric Ozone and Smoke …
Title Tropospheric Ozone and Smoke from Earth Probe TOMS: Indonesia
Abstract Researchers have discovered that smoke and smog move in different ways through the atmosphere. A series of unusual events several years ago created a blanket of pollution over the Indian Ocean. In this animation, significant smog or tropospheric ozone is represented by red and green and regions of significant smoke index are in shades of white and gray.
Completed 2001-03-06
Tropospheric Ozone and Smoke …
Title Tropospheric Ozone and Smoke from Earth Probe TOMS: Indonesia
Abstract Researchers have discovered that smoke and smog move in different ways through the atmosphere. A series of unusual events several years ago created a blanket of pollution over the Indian Ocean. In this animation, significant smog or tropospheric ozone is represented by red and green and regions of significant smoke index are in shades of white and gray.
Completed 2001-03-06
Tropospheric Ozone and Smoke …
Title Tropospheric Ozone and Smoke from Earth Probe TOMS: Indonesia
Abstract Researchers have discovered that smoke and smog move in different ways through the atmosphere. A series of unusual events several years ago created a blanket of pollution over the Indian Ocean. In this animation, significant smog or tropospheric ozone is represented by red and green and regions of significant smoke index are in shades of white and gray.
Completed 2001-03-06
Tropospheric Ozone and Smoke …
Title Tropospheric Ozone and Smoke from Earth Probe TOMS: Indonesia
Abstract Researchers have discovered that smoke and smog move in different ways through the atmosphere. A series of unusual events several years ago created a blanket of pollution over the Indian Ocean. In this animation, significant smog or tropospheric ozone is represented by red and green and regions of significant smoke index are in shades of white and gray.
Completed 2001-03-06
Tropospheric Ozone and Smoke …
Title Tropospheric Ozone and Smoke from Earth Probe TOMS: Indonesia
Abstract Researchers have discovered that smoke and smog move in different ways through the atmosphere. A series of unusual events several years ago created a blanket of pollution over the Indian Ocean. In this animation, significant smog or tropospheric ozone is represented by red and green and regions of significant smoke index are in shades of white and gray.
Completed 2001-03-06
Tropospheric Ozone and Smoke …
Title Tropospheric Ozone and Smoke from Earth Probe TOMS: Indonesia
Abstract Researchers have discovered that smoke and smog move in different ways through the atmosphere. A series of unusual events several years ago created a blanket of pollution over the Indian Ocean. In this animation, significant smog or tropospheric ozone is represented by red and green and regions of significant smoke index are in shades of white and gray.
Completed 2001-03-06
Floods in Indonesia
Title Floods in Indonesia
Description Days of heavy rains led to devastating landslides on the central Indonesian island of Sulawesi (formerly Celebes) in mid-June 2006. As of June 22, the death toll stood at 200 with 135 still missing, reported the United Nations Office for the Coordination of Humanitarian Affairs. [ http://www.reliefweb.int/rw/RWB.NSF/db900SID/KKEE-6QZME5?OpenDocument ] The hardest hit area was Sinjai in South Sulawesi. This image reflects the rainfall totals over the island from June 14 to June 21, 2006. Highest rainfall totals, on the order of 10 to 12 inches (300 millimeters) are red. The southernmost area of heavy rain is near the southern tip of Sulawesi and covers the higher terrain adjacent to Sinjai. Deforestation in the region is believed to be a contributing factor in the disastrous mudslides. The image was created using data from the Multi-satellite Precipitation Analysis (MPA), which monitors rainfall over the global Tropics. The MPA uses rainfall measurements from the Tropical Rainfall Measuring Mission satellite (TRMM) to calibrate rainfall estimates from other satellites. TRMM's primary mission is to measure rainfall over the global tropics. It was placed into service in November of 1997. From its low-earth orbit, TRMM has been measuring rainfall over the global Tropics using a combination of passive microwave and active radar sensors. TRMM is a joint mission between NASA and the Japanese space agency, JAXA. Image produced by Hal Pierce (SSAI/NASA GSFC) and caption by Steve Lang (SSAI/NASA GSFC).
Floods in Indonesia
Title Floods in Indonesia
Description Days of heavy rains led to devastating landslides on the central Indonesian island of Sulawesi (formerly Celebes) in mid-June 2006. As of June 22, the death toll stood at 200 with 135 still missing, reported the United Nations Office for the Coordination of Humanitarian Affairs. [ http://www.reliefweb.int/rw/RWB.NSF/db900SID/KKEE-6QZME5?OpenDocument ] The hardest hit area was Sinjai in South Sulawesi. This image reflects the rainfall totals over the island from June 14 to June 21, 2006. Highest rainfall totals, on the order of 10 to 12 inches (300 millimeters) are red. The southernmost area of heavy rain is near the southern tip of Sulawesi and covers the higher terrain adjacent to Sinjai. Deforestation in the region is believed to be a contributing factor in the disastrous mudslides. The image was created using data from the Multi-satellite Precipitation Analysis (MPA), which monitors rainfall over the global Tropics. The MPA uses rainfall measurements from the Tropical Rainfall Measuring Mission satellite (TRMM) to calibrate rainfall estimates from other satellites. TRMM's primary mission is to measure rainfall over the global tropics. It was placed into service in November of 1997. From its low-earth orbit, TRMM has been measuring rainfall over the global Tropics using a combination of passive microwave and active radar sensors. TRMM is a joint mission between NASA and the Japanese space agency, JAXA. Image produced by Hal Pierce (SSAI/NASA GSFC) and caption by Steve Lang (SSAI/NASA GSFC).
Air Quality Emergency in Mal …
Title Air Quality Emergency in Malaysia
Description In mid-August, several locations in mainland Malaysia declared air quality emergencies, as smoke from burning in Indonesia wafted across the Strait of Malacca and blanketed the country with haze. Many regions closed their schools and businesses, and news reports have indicated this may be the worst air quality event the country has experienced since the terrible fire season on Sumatra during the 1997-98 El Niño. This pair of images shows the region in Sumatra where many of the fires are burning (left), and the resulting smoke blanketing Malaysia (right). Although it is sometimes difficult to distinguish smoke from clouds, the infrared-enhanced view can penetrate the smoke in places. In this type of image, vegetation is bright green, clouds are white or light blue, and smoke becomes almost transparent in many places. Water is dark blue (nearly black). Actively burning fires are marked with red dots. These images were captured by the Moderate Resolution Imaging Spectroradiometer (MODIS) [ http://modis.gsfc.nasa.gov ] on NASA's Terra [ http://terra.nasa.gov ] satellite on August 12, 2005. NASA image by Jeff Schmaltz, MODIS Rapid Response Team, [ http://rapidfire.sci.gsfc.nasa.gov ] Goddard Space Flight Center.
Dili, East Timor
Title Dili, East Timor
Description Violence has marked East Timor's emergence as an independent nation. This false-color Enhanced Thematic Mapper Plus (ETM+) image from Landsat shows parts of the city of Dili, which became the capital of the independent nation of East Timor. The image was captured on September 8, 1999, only a few days after the announcement of the results of the referendum in which the residents of the island voted on whether to remain part of Indonesia or to become an independent nation. The overwhelming support for independence sparked violent protests among dissenters, who set scores of fires (red dots). Dark gray smoke streams southwest from burning buildings in the center of the image. Rivers appear pinkish-purple in this false-color combination. To the west of Dili is the Comoro River. To the east are the Bemorl and Benmauc Rivers, which join before emptying into the mingling waters of the Sawu and Banda Seas. To the west of the Comoro River near the coast is a thin, straight, purplish line that marks the location of the Comoro air strip. At bottom right are the mountains of central East Timor, whose highest peak reaches more than 2,900 meters (9,570 ft). This is a false-color composite image made using shortwave infrared, near infrared, and blue wavelengths(ETM+ plus bands 7,4, and 1). Image provided by the Australian Landsat receiving station and the Landsat 7 Science Team.
Dust Storm out of Northern A …
Title Dust Storm out of Northern Africa
Description On March 29, 2007, the Shiveluch Volcano (sometimes spelled Sheveluch) on the Russian Federation's Kamchatka Peninsula erupted. According to the Alaska Volcano Observatory [ http://www.avo.alaska.edu/activity/avoreport.php?view=kaminfo ] the volcano underwent an explosive eruption between 01:50 and 2:30 UTC, sending an ash cloud skyward roughly 9,750 meters (32,000 feet), based on visual estimates. The Moderate Resolution Imaging Spectroradiometer (MODIS) [ http://modis.gsfc.nasa.gov/ ] flying onboard NASA's Aqua [ http://aqua.nasa.gov/ ] satellite took this picture at 02:00 UTC on March 29. The top image shows the volcano and its surroundings. The bottom image shows a close-up view of the volcano at 250 meters per pixel. Satellites often capture images of volcanic ash plumes, but usually as the plumes are blowing away. Plumes have been observed blowing away from Shiveluch [ http://earthobservatory.nasa.gov/NaturalHazards/natural_hazards_v2.php3?img_id=14078 ] before. This image, however, is different. At the time the Aqua satellite passed overhead, the eruption was recent enough (and the air was apparently still enough) that the ash cloud still hovered above the summit. In this image, the bulbous cloud casts its shadow northward over the icy landscape. Volcanic ash eruptions inject particles into Earth's atmosphere. Substantial eruptions of light-reflecting particles can reduce temperatures and even affect atmospheric circulation. Large eruptions impact climate patterns [ http://earthobservatory.nasa.gov/Study/Volcano/ ] for years. A massive eruption of the Tambora Volcano [ http://science.nasa.gov/headlines/y2006/03oct_novarupta.htm ] in Indonesia in 1815, for instance, earned 1816 the nickname "the year without a summer."Shiveluch [ http://www.volcano.si.edu/world/volcano.cfm?vnum=1000-27= ] is a stratovolcano—a steep-sloped volcano composed of alternating layers of solidified ash, hardened lava, and volcanic rocks. One of Kamchatka's largest volcanoes, it sports a summit reaching 3,283 meters (10,771 feet). Shiveluch is also one of the peninsula's most active volcanoes, with an estimated 60 substantial eruptions in the past 10,000 years. You can download a 250-meter-resolution KMZ file of the North African dust storm [ http://earthobservatory.nasa.gov/NaturalHazards/Archive/Mar2007/nafrica_tmo_2007087.kmz ] for use with Google Earth. [ http://earth.google.com/download-earth.html ] NASA image created by Jesse Allen, using data provided courtesy of the MODIS Rapid Response [ http://rapidfire.sci.gsfc.nasa.gov/ ] team.
Earthquake Spawns Tsunamis
Title Earthquake Spawns Tsunamis
Description The island of Sumatra suffered from both the rumblings of the submarine earthquake and the tsunamis that were generated on December 26, 2004. Within minutes of the quake, the sea surged ashore, bringing destruction to the coasts of the northern Sumatra. This pair of images from the Moderate Resolution Imaging Spectroradiometer (MODIS) on NASA?s Terra satellite shows the Aceh province of northern Sumatra, Indonesia, on December 17, 2004, before the quake (bottom), and on December 29, 2004 (top), three days after the catastrophe. Though MODIS was not specifically designed to make the very detailed observations that are usually necessary for mapping coastline changes, the sensor nevertheless observed obvious differences in the Sumatran coastline. On December 17, the green vegetation along the west coast appears to reach all the way to the sea, with only an occasional thin stretch of white that is likely sand. After the earthquake and tsunamis, the entire western coast is lined with a noticeable purplish-brown border. The brownish border could be deposited sand, or perhaps exposed soil that was stripped bare of vegetation when the large waves rushed ashore and then raced away. On a moderate-resolution image such as this, the affected area may seem small, but each pixel in the full resolution image is 250 by 250 meters. In places the brown strip reaches inland roughly 13 pixels, equal to a distance of 3.25 kilometers, or about 2 miles. On the northern tip of the island (shown in the large image), the incursion is even larger. NASA images created by Jesse Allen, Earth Observatory, using data obtained from the MODIS Rapid Response team and the Goddard Earth Sciences DAAC.
Earthquake Spawns Tsunamis
Title Earthquake Spawns Tsunamis
Description The island of Sumatra suffered from both the rumblings of the submarine earthquake and the tsunamis that were generated on December 26, 2004. Within minutes of the quake, the sea surged ashore, bringing destruction to the coasts of the northern Sumatra. This pair of images from the Moderate Resolution Imaging Spectroradiometer (MODIS) on NASA?s Terra satellite shows the Aceh province of northern Sumatra, Indonesia, on December 17, 2004, before the quake (bottom), and on December 29, 2004 (top), three days after the catastrophe. Though MODIS was not specifically designed to make the very detailed observations that are usually necessary for mapping coastline changes, the sensor nevertheless observed obvious differences in the Sumatran coastline. On December 17, the green vegetation along the west coast appears to reach all the way to the sea, with only an occasional thin stretch of white that is likely sand. After the earthquake and tsunamis, the entire western coast is lined with a noticeable purplish-brown border. The brownish border could be deposited sand, or perhaps exposed soil that was stripped bare of vegetation when the large waves rushed ashore and then raced away. On a moderate-resolution image such as this, the affected area may seem small, but each pixel in the full resolution image is 250 by 250 meters. In places the brown strip reaches inland roughly 13 pixels, equal to a distance of 3.25 kilometers, or about 2 miles. On the northern tip of the island (shown in the large image), the incursion is even larger. NASA images created by Jesse Allen, Earth Observatory, using data obtained from the MODIS Rapid Response team and the Goddard Earth Sciences DAAC.
Indonesia?s Ruang Volcano Er …
Title Indonesia?s Ruang Volcano Erupts
Description *Full-resolution Images:* ÿÿÿTerra MODIS at 1:55 UTC (1.1 MB) ÿÿÿAqua MODIS at 4:50 UTC (748 KB) Mount Ruang, a stratovolcano in the Indonesian Sulawesi Islands, erupted on September 25, 2002, sending a large plume of ash (gray pixels) streaming westward toward Borneo and Sumatra. The eruption was preceded by earthquakes on the day before, followed by a thick, black column of volcanic ash ejected as high as 5,000 m into the sky on the 25th. While no fatalities were reported, more than 1,000 residents on Ruang Island were forced to evacuate to a nearby island. This comparison pair of true-color images was acquired by the Moderate Resolution Imaging Spectroradiometer, flying aboard NASA's Terra and Aqua satellites, on September 25. The top image was acquired by Terra MODIS at 1:55 UTC, while the bottom image was acquired by Aqua MODIS at 4:50 UTC. Notice how much the plume grew in that 3-hour span of time. (Note: the Aqua image appears noticeably different because the relative sun angle makes both the plume and the ocean surface appear much brighter.) Images courtesy Jacques Descloitres, MODIS Land Rapid Response Team [ http://rapidfire.sci.gsfc.nasa.gov/ ] at NASA GSFC
Indonesia?s Ruang Volcano Er …
Title Indonesia?s Ruang Volcano Erupts
Description *Full-resolution Images:* ÿÿÿTerra MODIS at 1:55 UTC (1.1 MB) ÿÿÿAqua MODIS at 4:50 UTC (748 KB) Mount Ruang, a stratovolcano in the Indonesian Sulawesi Islands, erupted on September 25, 2002, sending a large plume of ash (gray pixels) streaming westward toward Borneo and Sumatra. The eruption was preceded by earthquakes on the day before, followed by a thick, black column of volcanic ash ejected as high as 5,000 m into the sky on the 25th. While no fatalities were reported, more than 1,000 residents on Ruang Island were forced to evacuate to a nearby island. This comparison pair of true-color images was acquired by the Moderate Resolution Imaging Spectroradiometer, flying aboard NASA's Terra and Aqua satellites, on September 25. The top image was acquired by Terra MODIS at 1:55 UTC, while the bottom image was acquired by Aqua MODIS at 4:50 UTC. Notice how much the plume grew in that 3-hour span of time. (Note: the Aqua image appears noticeably different because the relative sun angle makes both the plume and the ocean surface appear much brighter.) Images courtesy Jacques Descloitres, MODIS Land Rapid Response Team [ http://rapidfire.sci.gsfc.nasa.gov/ ] at NASA GSFC
Indonesia?s Ruang Volcano Er …
Title Indonesia?s Ruang Volcano Erupts
Description *Full-resolution Images:* ÿÿÿTerra MODIS at 1:55 UTC (1.1 MB) ÿÿÿAqua MODIS at 4:50 UTC (748 KB) Mount Ruang, a stratovolcano in the Indonesian Sulawesi Islands, erupted on September 25, 2002, sending a large plume of ash (gray pixels) streaming westward toward Borneo and Sumatra. The eruption was preceded by earthquakes on the day before, followed by a thick, black column of volcanic ash ejected as high as 5,000 m into the sky on the 25th. While no fatalities were reported, more than 1,000 residents on Ruang Island were forced to evacuate to a nearby island. This comparison pair of true-color images was acquired by the Moderate Resolution Imaging Spectroradiometer, flying aboard NASA's Terra and Aqua satellites, on September 25. The top image was acquired by Terra MODIS at 1:55 UTC, while the bottom image was acquired by Aqua MODIS at 4:50 UTC. Notice how much the plume grew in that 3-hour span of time. (Note: the Aqua image appears noticeably different because the relative sun angle makes both the plume and the ocean surface appear much brighter.) Images courtesy Jacques Descloitres, MODIS Land Rapid Response Team [ http://rapidfire.sci.gsfc.nasa.gov/ ] at NASA GSFC
Mount Egon Erupts
Title Mount Egon Erupts
Description Shortly after 12:30 p.m. local time, on September 4, 2004, a large cloud of ash and smoke erupted from Mount Egon on the Indonesian island of Flores. When the Moderate Resolution Imaging Spectroradiometer (MODIS [ http://modis.gsfc.nasa.gov ]) flew over on NASA's Aqua [ http://aqua.nasa.gov/ ] satellite a little over an hour later, the light gray cloud straddled the island. The ash plume rose up to 3,000 meters above the volcano's crater. As of Monday, September 6, up to 2,100 people had been evacuated from villages around the volcano, as the mountain continued to show signs of activity. For more information about the eruption, please visit Relief Web [ http://www.reliefweb.int/w/rwb.nsf/vLCE/A68F7E67F598C70E49256F080006DC60?OpenDocument&StartKey=Indonesia:+Volcanic+Eruption+Mt.+Egon+-+Sep+2004&ExpandView ], sponsored by the United Nations Office for the Coordination of Humanitarian Affairs. NASA image courtesy Jesse Allen, based on data from the MODIS Rapid Response Team [ http://rapidfire.sci.gsfc.nasa.gov ] at NASA GSFC
Fires and Heavy Smoke in Sum …
Title Fires and Heavy Smoke in Sumatra
Description The smoke was so thick over some parts of Sumatra, Indonesia, in late February 2002 that officials were forced to close schools due to the health hazard. As can be seen in this true-color scene acquired on March 8, 2002, many fires continue to burn along the eastern side of Sumatra while strong winds are blowing the smoke back onto the island. This image was acquired by the Moderate-resolution Imaging Spectroradiometer [ http://modarch.gsfc.nasa.gov/ ] (MODIS), flying aboard NASA?s Terra [ http://terra.nasa.gov/ ] satellite. The red boxes (see the high-resolution image) indicate the areas recently burned or still burning. Image courtesy Jacques Descloitres, MODIS Land Rapid Response Team [ http://rapidfire.sci.gsfc.nasa.gov/ ] at NASA GSFC
Fires and Heavy Smoke in Sum …
Title Fires and Heavy Smoke in Sumatra
Description The smoke was so thick over some parts of Sumatra, Indonesia, in late February 2002 that officials were forced to close schools due to the health hazard. As can be seen in this true-color scene acquired on March 13, 2002, many fires continue to burn along the eastern side of Sumatra while strong winds are blowing the smoke back over the island. This image was acquired by the Moderate-resolution Imaging Spectroradiometer [ http://modarch.gsfc.nasa.gov/ ] (MODIS), flying aboard NASA?s Terra [ http://terra.nasa.gov/ ] satellite. The red boxes (see the high-resolution image) indicate the areas recently burned or still burning. Image courtesy Jacques Descloitres, MODIS Land Rapid Response Team [ http://rapidfire.sci.gsfc.nasa.gov/ ] at NASA GSFC
Fires and Heavy Smoke in Sum …
Title Fires and Heavy Smoke in Sumatra
Description *Fires and Heavy Smoke in Sumatra* At least once a year for a period lasting from a week to several months, northern Sumatra is obscured by smoke and haze produced by agricultural burning and forest fires. These data products from the Multi-angle Imaging SpectroRadiometer (MISR) document the presence of airborne particulates on March 13, 2002. On the left is an image acquired by MISR?s 70-degree backward-viewing camera. On the right is a map of aerosol optical depth, a measure of the abundance of atmospheric particulates. This product utilized a test version of the MISR retrieval that incorporates an experimental set of aerosol mixtures. The haze has completely obscured northeastern Sumatra and part of the Strait of Malacca, which separates Sumatra and the Malaysian Peninsula. A northward gradient is apparent as the haze dissipates in the direction of the Malaysian landmass. Each panel covers an area of about 760 kilometers x 400 kilometers. Haze conditions had posed a health concern during late February (when schools in some parts of North Sumatra were closed), and worsened considerably in the first two weeks of March. By mid-March, local meteorology officials asked residents of North Sumatra?s provincial capital, Medan, to minimize their outdoor activities and wear protective masks. Poor visibility at Medan airport forced a passenger plane to divert to Malaysia on March 14, and visibility reportedly ranged between 100 and 600 meters in some coastal towns southeast of Medan. The number and severity of this year?s fires was exacerbated by dry weather conditions associated with the onset of a weak to moderate El Niño. The governments of Indonesia, Malaysia, and Brunei have agreed to ban open burning in plantation and forest areas. The enforcement of such fire bans, however, has proven to be an extremely challenging task. Image courtesy NASA/GSFC/LaRC/JPL, MISR Team [ http://earthobservatory.nasa.gov/cgi-bin/redirect?http://www-misr.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/ ]
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.
Fires in Indonesia
Title Fires in Indonesia
Description Scores of fires were smoking across Sumatra (center) on June 8, 2003, trailing smoke across the Strait of Malacca, which separates Sumatra from Malaysia to the north, and also over the the Indian Ocean (bottom left). This image of active fire locations (red dots) was captured by the Moderate Resolution Imaging Spectroradiometer (MODIS) on the Terra satellite. Image courtesy Jesse Allen, based on data from the MODIS Rapid Response Team.
Fires in Indonesia
Title Fires in Indonesia
Description This Moderate Resolution Imaging Spectroradiometer (MODIS) image from September 30, 2003, shows numerous fires (red dots) burning across Indonesia. Smoke from the fires hangs over the scene, obscuring the landscape beneath. Fire is a serious threat to Indonesia?s remaining tropical forests. Image by Jesse Allen, based on data from the MODIS Rapid Response Team at NASA GSFC
Fires in New Guinea
Title Fires in New Guinea
Description On October 22, 2003, the Moderate Resolution Imaging Spectroradiometer (MODIS) on the Terra satellite captured this image of the island of New Guinea. This image is focused on the western part of the island, which is the Irian Jaya region of Indonesia. (The eastern part of the island is the country of Papua New Guinea.) Numerous fires burned across the southern part of the island, they were detected by MODIS and are marked with red dots in this image. Image courtesy Jesse Allen, based on data from the MODIS Rapid Response Team at NASA GSFC
Shiveluch Volcano, Kamchatka …
Title Shiveluch Volcano, Kamchatka Peninsula
Description On March 29, 2007, the Sheveluch (Shiveluch) Volcano on the Russian Federation's Kamchatka Peninsula erupted. According to the Alaska Volcano Observatory [ http://www.avo.alaska.edu/activity/avoreport.php?view=kaminfo ] the volcano underwent an explosive eruption between 01:50 and 2:30 UTC, sending an ash cloud skyward roughly 9,750 meters (32,000 feet), based on visual estimates. The Moderate Resolution Imaging Spectroradiometer (MODIS) [ http://modis.gsfc.nasa.gov/ ] flying onboard NASA's Aqua [ http://aqua.nasa.gov/ ] satellite took this picture at 02:00 UTC on March 29. The top image shows the volcano and its surroundings. The bottom image shows a close-up view of the volcano at 250 meters per pixel. Images of volcanic ash plumes often show the plumes blowing away, and Sheveluch is no exception. [ http://earthobservatory.nasa.gov/NaturalHazards/natural_hazards_v2.php3?img_id=14078 ] This image, however, is different. It shows the gray-brown ash cloud suspended directly over the summit. At the time the Aqua satellite passed overhead, the local air was apparently still enough to let the ash cloud hover. In this image, the bulbous cloud casts its shadow northward over the icy landscape. Volcanic ash eruptions inject particles into Earth's atmosphere. Substantial eruptions of light-reflecting particles can reduce temperatures and even affect atmospheric circulation. Large eruptions impact climate patterns [ http://earthobservatory.nasa.gov/Study/Volcano/ ] for years. A massive eruption of the Tambora Volcano [ http://science.nasa.gov/headlines/y2006/03oct_novarupta.htm ] in Indonesia in 1815, for instance, earned 1816 the nickname "the year without a summer."Sheveluch [ http://www.volcano.si.edu/world/volcano.cfm?vnum=1000-27= ] is a stratovolcano—a steep-sloped volcano composed of alternating layers of solidified ash, hardened lava, and volcanic rocks. One of Kamchatka's largest volcanoes, it sports a summit reaching 3,283 meters (10,771 feet). Sheveluch is also one of the peninsula's most active volcanoes, with an estimated 60 substantial eruptions in the past 10,000 years. You can download a 250-meter-resolution KMZ file of Kamchatka's most active volcanic region, which includes Sheveluch, [ http://earthobservatory.nasa.gov/Newsroom/NewImages/Images/Kliuchevskoi.2007088.aqua.250m.kmz ] for use with Google Earth. [ http://earth.google.com/download-earth.html ] There is also a 250-meter-resolution close-up KMZ file of Sheveluch. [ http://earthobservatory.nasa.gov/NaturalHazards/Archive/Mar2007/Shiveluch.A2007088.0200.250m.kmz ] NASA image courtesy the MODIS Rapid Response Team [ http://rapidfire.sci.gsfc.nasa.gov ] at NASA GSFC. The Rapid Response Team provides daily images [ http://rapidfire.sci.gsfc.nasa.gov/subsets/?Kliuchevskoi ] of this region.
Fires in Sumatra
Title Fires in Sumatra
Description Fire activity has flared up once again on the island of Sumatra in Indonesia, after being relatively quiet over the past month. This image of active fires (marked in yellow) was captured by the Moderate Resolution Imaging Spectroradiometer (MODIS) on the Aqua satellite on June 15, 2004, several weeks after the first image in the series was captured. Fires are concentrated in the north-central part of the island, their smoke mingling with clouds to the north and east. Image by Jesse Allen, based on data from the MODIS Rapid Response Team at NASA Goddard Space Flight Center.
Fires in Sumatra
Title Fires in Sumatra
Description Sores of fires (marked in red) were detected by the Moderate Resolution Imaging Spectroradiometer (MODIS) on the Aqua satellite on August 4, 2004, across Sumatra in Indonesia. Image by Jesse Allen, based on data from the MODIS Rapid Response Team, NASA-GSFC
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.
Torrential Rains in Indonesi …
Title Torrential Rains in Indonesia
Description Heavy rains dumped a foot or more of water over several Indonesian island regions during March 29-April 1. The image graphically portrays heavy rain accumulations particularly over and offshore of Papua New Guinea and over the easternmost islands of Flores and Timor in Jakarta. The accumulation map was created using a technique that combines rainfall information from a number of NASA and DoD satellites. NASA's Tropical Rainfall Measurement Mission (TRMM) satellite plays a key role in mapping the rain. The heavy rains occurred sporadically in the form of intense clusters of thunderstorms, embedded within the larger Winter Asian Monsoon circulation, and modulated by the passage of an atmospheric wave called the tropical intraseasonal oscillation. The very localized but extreme rain amounts over the island of Flores resulted in violent landslides that killed 23 people. *animations* ÿÿsmall [ http://earthobservatory.nasa.gov/NaturalHazards/Archive/Apr2003/new_guinea_small.qt ] (656 KB) ÿÿlarge [ http://earthobservatory.nasa.gov/NaturalHazards/Archive/Apr2003/new_guinea.qt ] (3.3 MB) This image was created by Hal Pierce of the NASA Goddard Space Flight Center. More information on TRMM can be found at trmm.gsfc.nasa.gov
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