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Tropical Cyclone Daryl
| Title |
Tropical Cyclone Daryl |
| Description |
This pair of images shows the birth of Cyclone Daryl off the northwest coast of Western Australia on January 19, 2006. In the fifteen hours that elapsed between the time the Tropical Rainfall Measuring Mission (TRMM [ http://trmm.gsfc.nasa.gov/ ]) satellite captured the top image at 10:08 a.m. Australian Western Standard Time and when it captured the bottom image at 1:00 a.m., Daryl went from a weak, newly named storm to a mature storm roughly equivalent to a Category 1 hurricane on the Saffir-Simpson scale. The storm's center remained just offshore as it moved southwest along the coast, sparing coastal communities a direct hit. Both images show rain rates in the storm. In the top image, TRMM reveals that despite having a sizeable band of intense rain (dark red segment) centered in a broad area of light (blue areas) to occasionally moderate (green areas) rain, Daryl showed very little evidence of circulation. This lack of circulation indicated that Daryl was in the early stages of development. At the time of this image, Daryl was rated as a Category 1 cyclone by the Australian Bureau of Meteorology's Tropical Cyclone Warning Center, indicating peak wind gusts of less than 125 kilometers per hour (78 miles per hour)equivalent to a tropical storm. The lower image was taken just 15 hours later at 17:00 UTC (1:00 a.m. Australian WST on January 20) and shows a very different-looking storm. Although Daryl did not have a well-defined closed eye, the heavy rain had separated into arcing bands (green and darker red arcs), indicating that Daryl had a more mature circulation than it did earlier. Daryl became a Category 3 cyclone the following day. Catching Tropical Cyclone Daryl in the act of building may provide new and critical data for understanding the complexities of storm intensification. Becuase storms tend to form and intensify well away from land, scientists are still trying to understand how cyclones intensify. Armed with both passive and active sensors, including the first and only precipitation radar in space, TRMM has proven itself to be a valuable tool for examining tropical cyclones. These images show rain rates as measured by a number of different sensors on the TRMM satellite. Rain rates in the center swath are from the TRMM Precipitation Radar, while rain rates in the outer swath are from the TRMM Microwave Imager. The rain rates are overlaid on infrared data from the TRMM Visible Infrared Scanner. Launched in November 1997 to measure rainfall over the global tropics, TRMM is a joint mission between NASA and the Japanese space agency, JAXA. Images produced by Hal Pierce (SSAI, NASA/GSFC) and captioned by Steve Lang (SSAI, NASA/GSFC). |
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Tropical Cyclone Daryl
| Title |
Tropical Cyclone Daryl |
| Description |
This pair of images shows the birth of Cyclone Daryl off the northwest coast of Western Australia on January 19, 2006. In the fifteen hours that elapsed between the time the Tropical Rainfall Measuring Mission (TRMM [ http://trmm.gsfc.nasa.gov/ ]) satellite captured the top image at 10:08 a.m. Australian Western Standard Time and when it captured the bottom image at 1:00 a.m., Daryl went from a weak, newly named storm to a mature storm roughly equivalent to a Category 1 hurricane on the Saffir-Simpson scale. The storm's center remained just offshore as it moved southwest along the coast, sparing coastal communities a direct hit. Both images show rain rates in the storm. In the top image, TRMM reveals that despite having a sizeable band of intense rain (dark red segment) centered in a broad area of light (blue areas) to occasionally moderate (green areas) rain, Daryl showed very little evidence of circulation. This lack of circulation indicated that Daryl was in the early stages of development. At the time of this image, Daryl was rated as a Category 1 cyclone by the Australian Bureau of Meteorology's Tropical Cyclone Warning Center, indicating peak wind gusts of less than 125 kilometers per hour (78 miles per hour)equivalent to a tropical storm. The lower image was taken just 15 hours later at 17:00 UTC (1:00 a.m. Australian WST on January 20) and shows a very different-looking storm. Although Daryl did not have a well-defined closed eye, the heavy rain had separated into arcing bands (green and darker red arcs), indicating that Daryl had a more mature circulation than it did earlier. Daryl became a Category 3 cyclone the following day. Catching Tropical Cyclone Daryl in the act of building may provide new and critical data for understanding the complexities of storm intensification. Becuase storms tend to form and intensify well away from land, scientists are still trying to understand how cyclones intensify. Armed with both passive and active sensors, including the first and only precipitation radar in space, TRMM has proven itself to be a valuable tool for examining tropical cyclones. These images show rain rates as measured by a number of different sensors on the TRMM satellite. Rain rates in the center swath are from the TRMM Precipitation Radar, while rain rates in the outer swath are from the TRMM Microwave Imager. The rain rates are overlaid on infrared data from the TRMM Visible Infrared Scanner. Launched in November 1997 to measure rainfall over the global tropics, TRMM is a joint mission between NASA and the Japanese space agency, JAXA. Images produced by Hal Pierce (SSAI, NASA/GSFC) and captioned by Steve Lang (SSAI, NASA/GSFC). |
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Tropical Cyclone Daryl
| Title |
Tropical Cyclone Daryl |
| Description |
This pair of images shows the birth of Cyclone Daryl off the northwest coast of Western Australia on January 19, 2006. In the fifteen hours that elapsed between the time the Tropical Rainfall Measuring Mission (TRMM [ http://trmm.gsfc.nasa.gov/ ]) satellite captured the top image at 10:08 a.m. Australian Western Standard Time and when it captured the bottom image at 1:00 a.m., Daryl went from a weak, newly named storm to a mature storm roughly equivalent to a Category 1 hurricane on the Saffir-Simpson scale. The storm's center remained just offshore as it moved southwest along the coast, sparing coastal communities a direct hit. Both images show rain rates in the storm. In the top image, TRMM reveals that despite having a sizeable band of intense rain (dark red segment) centered in a broad area of light (blue areas) to occasionally moderate (green areas) rain, Daryl showed very little evidence of circulation. This lack of circulation indicated that Daryl was in the early stages of development. At the time of this image, Daryl was rated as a Category 1 cyclone by the Australian Bureau of Meteorology's Tropical Cyclone Warning Center, indicating peak wind gusts of less than 125 kilometers per hour (78 miles per hour)equivalent to a tropical storm. The lower image was taken just 15 hours later at 17:00 UTC (1:00 a.m. Australian WST on January 20) and shows a very different-looking storm. Although Daryl did not have a well-defined closed eye, the heavy rain had separated into arcing bands (green and darker red arcs), indicating that Daryl had a more mature circulation than it did earlier. Daryl became a Category 3 cyclone the following day. Catching Tropical Cyclone Daryl in the act of building may provide new and critical data for understanding the complexities of storm intensification. Becuase storms tend to form and intensify well away from land, scientists are still trying to understand how cyclones intensify. Armed with both passive and active sensors, including the first and only precipitation radar in space, TRMM has proven itself to be a valuable tool for examining tropical cyclones. These images show rain rates as measured by a number of different sensors on the TRMM satellite. Rain rates in the center swath are from the TRMM Precipitation Radar, while rain rates in the outer swath are from the TRMM Microwave Imager. The rain rates are overlaid on infrared data from the TRMM Visible Infrared Scanner. Launched in November 1997 to measure rainfall over the global tropics, TRMM is a joint mission between NASA and the Japanese space agency, JAXA. Images produced by Hal Pierce (SSAI, NASA/GSFC) and captioned by Steve Lang (SSAI, NASA/GSFC). |
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Tropical Cyclone Gonu
| Title |
Tropical Cyclone Gonu |
| Description |
At one time, Cyclone Gonu was a powerful Category 5 storm packing sustained winds of 255 kilometers per hour (160 miles per hour), according to the Joint Typhoon Warning Center, [ https://metocph.nmci.navy.mil/jtwc.php ] and on a course towards Oman. This made it the most powerful cyclone ever to threaten the Arabian Peninsula since record keeping began back in 1945. Tropical cyclones do on occasion form in the Arabian Sea, but they rarely exceed tropical storm intensity. In 2006, Tropical Storm Mukda was the only system to form in the region, and it remained well out to sea before dissipating. Gonu became a tropical storm in the morning (local time) of June 2, 2007, in the east-central Arabian Sea. After some initial fluctuations in direction, the storm settled on a northwesterly track and began to intensify. Gonu went from tropical storm intensity to a Category 2 Tropical Cyclone [ http://www.nhc.noaa.gov/aboutsshs.shtml ] on the night of June 3. Overnight, it developed into a Category 4 storm with winds estimated at 210 km/hr (132 mph). The Tropical Rainfall Measuring Mission (TRMM) [ http://trmm.gsfc.nasa.gov/ ], captured this image of Gonu as the storm was moving northwest over the central Arabian Sea. The image was taken at 6:23 a.m. local time (03:23 UTC) on June 4, 2007, when Gonu was a Category 4 storm. It shows the horizontal distribution of rain intensity looking down on the storm. The distribution of rain within the storm reveals the storm's structure, and in this case, Gonu displays all of the tell-tale signs of a potent storm. Not only did Gonu have a complete, well-formed, symmetrical eye surrounded by an intense eyewall (innermost red ring), this inner eyewall was surrounded by a concentric outer eyewall (outermost red and green ring). This double eyewall structure only occurs in very intense storms. Eventually the outer eyewall will contract and replace the inner eyewall, a process known as eyewall replacement. The image was made with data from several sensors on the TRMM satellite. Rain rates in the center of the swath are from the TRMM Precipitation Radar, while those in the outer portion are from the TRMM Microwave Imager. The rain rates are overlaid on infrared data from the TRMM Visible Infrared Scanner. Several hours after this image was taken, Gonu reached Category 5 intensity, the very peak of possible storm strengths. The system remained in this high state through the day, then began weakening during the night of June 4 as it continued to approach the coast of Oman. The center remained just offshore of the northeast coast of Oman as a Category 1 storm before turning northward towards Iran, where it was expected to make landfall as a tropical storm, according to forecasts made on June 6, 2007. The TRMM satellite was placed into service in November 1997. From its low-earth orbit, TRMM provides valuable images and information on storm systems around the tropics using a combination of passive microwave and active radar sensors, including the first precipitation radar in space. TRMM is a joint mission between NASA and the Japanese space agency, JAXA. NASA image produced by Hal Pierce (SSAI/NASA GSFC) and caption by Steve Lang (SSAI/NASA GSFC). |
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