July 03, 2019 – NASA Peers Into Hurricane Barbara’s Heavy Rainfall
The Global Precipitation Measurement mission or GPM core satellite passed over the storm and measured the rate in which rain was falling throughout it.
The GPM core satellite passed over Hurricane Barbara at 3:21 a.m. EDT (0721 UTC) on July 3, 2019. GPM found the heaviest rainfall rate (pink) was northeast of the center of circulation. There, rain was falling at a rate of more than 50 mm (2 inches) per hour. The GPM image was overlaid on a GOES-West infrared image of Barbara’s clouds. Credit: NASA/JAXA/NRL/NOAA
The GPM core satellite passed over Hurricane Barbara at 3:21 a.m. EDT (0721 UTC) on July 3, 2019. GPM found the heaviest rainfall rates were occurring around the eye. There, rain was falling at a rate of more than 50 mm (2 inches) per hour. GPM is a joint mission between NASA and the Japan Aerospace Exploration Agency, JAXA.
NOAA’s National Hurricane Center noted at 4 a.m. EDT (0900 UTC), the eye of Hurricane Barbara was located near latitude 13.5 degrees North and longitude 125.6 degrees West. Barbara is moving toward the west-northwest near 14 mph (22 kph).
Barbara is about 1,995 miles (3,210 km) east of Hilo, Hawaii. A motion toward the west-northwest or northwest, but at a slightly slower forward speed, is expected Wednesday through Friday.
Maximum sustained winds remain near 155 mph (250 kph) with higher gusts. Barbara is a category 4 hurricane on the Saffir-Simpson Hurricane Wind Scale. Gradual weakening is expected on Wednesday, followed by faster weakening on Thursday and Friday. Barbara is forecast to weaken to a tropical storm some time on Friday.
Hurricane-force winds extend outward up to 45 miles (75 km) from the center, and tropical-storm-force winds extend outward up to 185 miles (295 km). The estimated minimum central pressure is 933 mb (27.55 inches).
July 02, 2019 – Barbara Now a Major Hurricane on NASA Satellite Imagery
NASA’s Terra and Aqua satellites passed over the Eastern Pacific Ocean after Tropical Storm Barbara strengthened into the first hurricane of the season. Barbara intensified rapidly into a major hurricane.
On July 2, 2019, the MODIS instrument aboard NASA’s Terra satellite provided a visible image of Hurricane Barbara in the Eastern Pacific Ocean, now far from western Mexico. Credit: NASA Worldview, Earth Observing System Data and Information System (EOSDIS)
NOAA’s National Hurricane Center (NHC) noted that Barbara intensified early during the morning of July 2 and could strengthen a little more. Fortunately, Barbara is over 1,000 miles west of the southern tip of Baja California, and there are no coastal watches or warnings in effect.
On July 2, the Moderate Resolution Imaging Spectroradiometer or MODIS instrument aboard NASA’s Terra satellite provided a visible image of Barbara that showed powerful thunderstorms circling an eye. Bands of thunderstorms wrapped into the center from the southern and eastern quadrants.
An infrared look by NASA’s Aqua satellite on July 2, at 5:17 a.m. EDT (0917 UTC revealed where the strongest storms were located within Hurricane Barbara. The Atmospheric Infrared Sounder or AIRS instrument aboard NASA’s Aqua satellite analyzed cloud top temperatures and found cloud top temperatures of strongest thunderstorms as cold as or colder than minus 81.6 degrees Fahrenheit (minus 63.1 degrees Celsius) circling the eye, which was seen in a lighter color in a false-colored NASA image. Cloud top temperatures that cold indicate strong storms that have the capability to create heavy rain.
On July 2, at 5:17 a.m. EDT (0917 UTC) the AIRS instrument aboard NASA’s Aqua satellite analyzed cloud top temperatures of Hurricane Barbara in infrared light. AIRS found coldest cloud top temperatures (purple) of strongest thunderstorms were as cold as or colder than minus 81.6 degrees Fahrenheit (minus 63.1 degrees Celsius). Credit: NASA JPL/Heidar Thrastarson
At 11 a.m. EDT (1500 UTC), the NHC noted the eye of Hurricane Barbara was located near latitude 12.5 degrees north and longitude 122.2 degrees west. Barbara is about 1,080 miles or 1,740 km southwest of the southern tip of Baja California, Mexico. Barbara is moving toward the west-northwest near 14 mph (22 kph). Barbara is forecast to slow in forward speed later today and then turn toward the northwest in a day or two. The estimated minimum central pressure is 948 millibars (28.00 inches).
Satellite data indicate that the maximum sustained winds have increased to near 130 mph (215 kph) with higher gusts. Barbara is a category 4 hurricane on the Saffir-Simpson Hurricane Wind Scale. Hurricane-force winds extend outward up to 25 miles (35 km) from the center and tropical-storm-force winds extend outward up to 185 miles (295 km).
Some additional strengthening is possible today, but weakening is likely to begin on Wednesday and continue into Thursday.
July 01, 2019 – NASA Finds Winds Tore Tropical Storm 04W Apart
Visible imagery from NASA’s Aqua satellite showed Tropical Cyclone 04W had been torn apart from wind shear in the Northwestern Pacific Ocean.
On July 1 at 12:40 a.m. EDT (4:40 p.m. EDT), the MODIS instrument aboard NASA’s Aqua satellite provided a visible image of 04W’s remnants. Clouds associated with the former tropical storm appeared fragmented between Luzon, the northern Philippines, and Taiwan. Credit: NASA/NRL
On Saturday, June 29, Tropical Storm 04W developed east of the Philippines and was moving toward the northwest. 04W formed near 15.3 north latitude and 130.7 east longitude, about 564 miles east of Manila, Philippines. At that time, 04W had maximum sustained winds near 35 knots (40 mph)
The next day, the Joint Typhoon Warning Center issued their final bulletin on 04W. This short-lived storm weakened to a depression just over 24 hours from its development. Although it moved close enough to the Philippines to get the local name of Egay, and to trigger a tropical cyclone warning signal #1 for the Batanes province in Luzon, 04W weakened to a depression by 11 a.m. EDT (1500 UTC) on June 30.
At the time of the final warning, 04W was located near 18.4 north latitude and 126.6 east longitude, about 395 nautical miles northeast of Manila, Philippines.
Northeasterly vertical wind shear was tearing the storm apart. In general, wind shear is a measure of how the speed and direction of winds change with altitude. Tropical cyclones are like rotating cylinders of winds. Each level needs to be stacked on top each other vertically in order for the storm to maintain strength or intensify. Wind shear occurs when winds at different levels of the atmosphere push against the rotating cylinder of winds, weakening the rotation by pushing it apart at different levels.
On July 1 at 12:40 a.m. EDT (4:40 p.m. EDT), the Moderate Resolution Imaging Spectroradiometer or MODIS instrument aboard NASA’s Aqua satellite provided a visible image of 04W’s remnants. Clouds associated with the former tropical storm appeared fragmented between Luzon, the northern Philippines, and Taiwan. Satellite imagery showed the low level circulation had unraveled into a broad, weak circulation.
The remnants are expected to continue moving northwest and dissipate.
July 01, 2019 – NASA Looks at Tropical Storm Barbara’s Heavy Rainfall
Tropical Storm Barbara formed on Sunday, June 30 in the Eastern Pacific Ocean over 800 miles from the coast of western Mexico. The Global Precipitation Measurement mission or GPM core satellite passed over the storm and measured the rate in which rain was falling throughout it.
The GPM core satellite passed over Tropical Storm Barbara at 3:31 a.m. EDT (0731 UTC) on July 1, 2019. GPM found the heaviest rainfall rate (pink) was northeast of the center of circulation. There, rain was falling at a rate of 41 mm (about 1.6 inches) per hour. Credit: NASA/JAXA/NRL
Barbara formed as a tropical storm around 11 a.m. EDT (1500) on June 30, and slowly intensified.
The GPM core satellite passed over Tropical Storm Barbara at 3:31 a.m. EDT (0731 UTC) on July 1, 2019. GPM found the heaviest rainfall rates were occurring northeast of the center of circulation. There, rain was falling at a rate of 41 mm (about 1.6 inches) per hour. The rainfall in that area are part of a band of thunderstorms wrapping into the low-level center, and there were a couple of other areas in that same band with the same rainfall rate. GPM is a joint mission between NASA and the Japan Aerospace Exploration Agency, JAXA.
NOAA’s National Hurricane Center noted at 5 a.m. EDT (0900 UTC) on July 1, the center of Tropical Storm Barbara was located near latitude 11.2 degrees north, longitude 115.8 degrees west. That’s about 895 miles (1,445 km) south-southwest of the southern tip of Baja California, Mexico. Barbara is moving toward the west near 21 mph (33 kph). A westward to west-northwestward motion at a slower forward speed is expected over the next few days. The estimated minimum central pressure is 998 millibars (29.47 inches). Maximum sustained winds have increased to near 65 mph (100 kph) with higher gusts.
Additional strengthening is forecast during the next couple of days, and Barbara is expected to become a hurricane later today.
June 28, 2019 – NASA Satellite Takes Tropical Storm Alvin’s Temperature
Cloud top temperatures are an indication of strength of tropical cyclones. The colder the cloud tops, the higher they extend in the troposphere, and colder temperatures typically indicate stronger storms. NASA’s Aqua satellite peered into Tropical Storm Alvin with infrared light to determine if the storm was intensifying.
NASA’s Aqua satellite provided an infrared picture of Tropical Storm Alvin’s cloud top temperatures on June 27 at 4:59 a.m. EDT (0859 UTC). Strongest storms with coldest cloud tops appear in purple and have temperatures as cold as or colder than minus 63 Fahrenheit (minus 53 Celsius). Credit: NASA JPL, Heidar Thrastarson
The Atmospheric Infrared Sounder or AIRS instrument aboard NASA’s Aqua satellite passed over Tropical Storm Alvin and analyzed the storm in infrared light. Infrared light provides scientists with temperature data and that is important when trying to understand the strength of the thunderstorms that make up a tropical cyclone. The higher the cloud tops, the colder and the stronger they are. So infrared light as that gathered by the AIRS instrument can identify the strongest sides of a tropical cyclone.
NASA’s Aqua satellite flew over Alvin on June 27 at 4:59 a.m. EDT (0859 UTC). AIRS detected strongest storms around the center with cloud top temperatures as cold as minus 63 degrees Fahrenheit (minus 53 degrees Celsius). Infrared data showed cloud top temperatures were getting colder, indicating stronger uplift of air, pushing those storms higher in the troposphere. Storms with cloud top temperatures that cold have the capability to produce heavy rainfall. The storm intensified over June 27 to early June 28 as winds increased from 60 to 70 mph (97 to 110 kph).
On June 28, NOAA’s National Hurricane Center forecaster Daniel Brown said, “Alvin’s satellite presentation has begun to degrade overnight with the overall cloud pattern becoming elongated from southwest to northeast. Southwesterly shear has caused the system to become less symmetric.”
Current Status of Alvin
At 5 a.m. EDT (0900 UTC) on Friday, June 28, 2019 the center of Tropical Storm Alvin was located near latitude 18.0 degrees north and longitude 116.3 degrees west. That puts the center of Alvin about 535 miles (860 km) southwest of the southern tip of Baja California, Mexico. Maximum sustained winds are near 70 mph (110 kph) with higher gusts.
Alvin is moving toward the northwest near 15 mph (24 kph), and a gradual turn toward the west-northwest with a decrease in forward speed is expected over the next couple of days. Alvin is expected to move into an area of cooler waters and where the southwesterly wind shear is forecast to increase. Those two factors are expected to cause rapid weakening during the next 24 to 36 hours. Because Alvin is a small cyclone, it is likely to suffer from the effects of the hostile environment more quickly.
The National Hurricane Center expects Alvin to weaken over the next day or two, and Alvin is forecast to become a remnant low on Saturday and should dissipate soon thereafter.
For forecast updates on Tropical Storm Alvin, visit: www.nhc.noaa.gov
June 27, 2019 – NASA’s Terra Satellite Eyes Tropical Storm Alvin
Visible imagery from NASA’s Terra satellite showed Tropical Storm Alvin had organized and strengthened into a strong tropical storm, just over 500 miles from Mexico’s Baja California peninsula.
On June 27, the Moderate Resolution Imaging Spectroradiometer or MODIS instrument aboard NASA’s Terra satellite provided a visible image of Alvin. Satellite imagery revealed that Alvin’s clouds appeared more organized than they did the previous day.
On June 27, 2019, the MODIS instrument aboard NASA’s Terra satellite provided a visible image of Tropical Cyclone Alvin, located over 500 miles west of Baja California, Mexico. Credit: NASA Worldview, Earth Observing System Data and Information System (EOSDIS)
Recent microwave imagery also showed that Alvin’s “convective structure,” or the development and organization of thunderstorms around the low-level center) has improved during the morning of June 27. AT 6:57 a.m. EDT (1057 UTC). The Special Sensor Microwave/Imager (SSM/I) instrument aboard Defense Meteorological Satellite Program satellite showed a closed ring of convection (clouds and storms) around the mid-level center of the small tropical storm. Infrared satellite imagery revealed that Alvin has not changed significantly.
NOAA’s National Hurricane Center (NHC) reported at 11 a.m. EDT (1500 UTC), the center of Tropical Storm Alvin was located near latitude 15.8 degrees north and longitude 113.1 degrees west. That’s about 535 miles (855 km) south-southwest of the southern tip of Baja California.
Maximum sustained winds are near 60 mph (95 kph) with higher gusts. Alvin is moving toward the west-northwest near 14 mph (22 kph), and this general motion is expected to continue for the next day or so. The estimated minimum central pressure is 999 millibars (29.50 inches).
Some strengthening is possible during the next 24 hours before Alvin reaches cooler waters. Weakening is the expected to begin on Friday and the NHC said Alvin is forecast to become a remnant low on Saturday.
June 26, 2019 – NASA Analyzes Alvin, the First Eastern Pacific Tropical Storm
The Eastern Pacific Ocean has spawned its first tropical storm of the 2019 hurricane season, and NASA’s Aqua satellite measured the cloud top temperatures within to gauge its strength.
On June 26 at 4:15 a.m. EDT (0815 UTC), NASA’s Aqua satellite revealed cloud top temperatures in strongest storms were near Tropical Storm Alvin’s center of circulation. Those temperatures were as cold as or colder than minus 70 degrees (red) Fahrenheit (minus 56.6 degrees Celsius). Credit: NASA/NRL
Infrared satellite imagery provides temperature data, and when NASA’s Aqua satellite passed over the system it was still a depression, but showing powerful thunderstorm development. Cloud top temperatures determine strength of the thunderstorms that make up a tropical cyclone. The colder the cloud tops, the stronger the uplift in the storms that help thunderstorm development. Infrared data helps determine where the most powerful storms are within a tropical cyclone.
The Moderate Resolution Imaging Spectroradiometer or MODIS instrument aboard Aqua provided that infrared data on June 26 at 4:15 a.m. EDT (0815 UTC). The MODIS data showed the strongest thunderstorms were near the center of circulation. They were as cold as or colder than minus 70 degrees Fahrenheit (minus 56.6 degrees Celsius). NASA research indicates very cold cloud tops with the potential to generate very heavy rainfall.
Tropical Depression One-E strengthened into a tropical storm and named Alvin at 11 a.m. EDT (1500 UTC) on Wednesday, June 26, 2019. At that time, NOAA’s National Hurricane Center noted that the center of Tropical Storm Alvin was located near latitude 14.7 degrees north and longitude 109.4 degrees west. That puts Alvin far from land areas and about 450 miles (725 km) southwest of Manzanillo, Mexico. Alvin is also about 565 miles (915 km) south of the southern tip of Baja California. As a result, there are no coastal watches or warnings in effect.
Alvin is moving toward the west near 14 mph (22 kph) and the NHC expects a westward to west-northwestward motion with some decrease in forward speed over the next few days. Maximum sustained winds have increased to near 40 mph (65 kph) with higher gusts.
Some additional strengthening is forecast during the next day or so. Weakening is forecast to begin on Friday, and Alvin is expected to become a remnant low on Saturday.
June 17 Update – NASA-NOAA Satellite Finds Dry Air Affecting Tropical Cyclone Vayu
Tropical Cyclone Vayu was fading as it neared the coast of southwestern Pakistan and northwestern India. Dry air and wind shear were preventing development the development of thunderstorms, making the clouds on the storm’s western side appear wispy in an image from NASA-NOAA’s Suomi NPP satellite.
NASA-NOAA’s Suomi NPP satellite passed over the Arabian Sea on June 17 and saw the effects of dry air on Tropical Cyclone Vayu’s western quadrant where only wispy clouds were seen. Credit: NASA Worldview, Earth Observing System Data and Information System (EOSDIS).
The Visible Infrared Imaging Radiometer Suite (VIIRS) instrument aboard Suomi NPP provided a visible image of the storm on June 17, 2019. The VIIRS image showed that dry air that moved into the storm on the western side had prevented further development of the thunderstorms that make up a tropical cyclone. Clouds on that side of Vayu appeared wispy and were precipitation free. Thicker clouds were visible on Vayu’s eastern side where some had already spread over the coast of northwestern Indian near Naliya. Vayu is forecast to make landfall near Naliya later in the day.
On June 17 at 0300 UTC (June 16 at 11 p.m. EDT), the Joint Typhoon Warning Center issued the final warning on Vayu. At that time, Tropical Cyclone Vayu was located near 21.8 degrees north latitude and 66.8 degrees east longitude, approximately 180 nautical miles south of Karachi, Pakistan. Vayu was moving to the northeast and had maximum sustained winds near 35 knots (40 mph/65 kph) making it a minimal tropical storm.
In addition to dry air sapping the tropical cyclone’s ability to create more thunderstorms, wind shear is pushing the remaining storms to the east of the center.
In general, wind shear is a measure of how the speed and direction of winds change with altitude. Tropical cyclones are like rotating cylinders of winds. Each level needs to be stacked on top each other vertically in order for the storm to maintain strength or intensify. Wind shear occurs when winds at different levels of the atmosphere push against the rotating cylinder of winds, weakening the rotation by pushing it apart at different levels.
Vayu is forecast to dissipate later in the day on June 17.
June 14, 2019 – Update #2 – NASA Finds Tropical Cyclone Vayu Getting Stretched
When NASA’s Aqua satellite passed over the Northern Indian Ocean, it captured an infrared image that revealed Tropical Cyclone Vayu was elongating. That’s never a good sign for a tropical cyclone, because they need a circular rotation to maintain strength.
On June 14, at 0359 UTC (0859 UTC) the AIRS instrument aboard NASA’s Aqua satellite analyzed cloud top temperatures of Tropical Cyclone Vayu in infrared light. AIRS found coldest cloud top temperatures (purple) of strongest thunderstorms were as cold as or colder than minus 63 degrees Fahrenheit (minus 53 degrees Celsius). Credit: NASA JPL/Heidar Thrastarson
On June 14, warnings remained in effect for India’s Gujarat coast.
Infrared light enables NASA to take the temperatures of clouds and thunderstorms that make up tropical cyclones. The stronger the storms are indicate that they extend high into the troposphere and have cold cloud top temperatures.
An infrared look by NASA’s Aqua satellite on June 14, at 0359 UTC (0859 UTC) revealed strongest storms within Tropical Cyclone Vayu. The Atmospheric Infrared Sounder or AIRS instrument aboard NASA’s Aqua satellite analyzed cloud top temperatures and found cloud top temperatures of strongest thunderstorms as cold as or colder than minus 63 degrees Fahrenheit (minus 53 degrees Celsius) circling the center and in thunderstorms northwest of the center. Cloud top temperatures that cold indicate strong storms that have the capability to create heavy rain.
On June 14 at 11 a.m. EDT (1500 UTC), the center of Tropical Cyclone Vayu was located near latitude 20.8 degrees south and longitude 68.2 degrees east. Vayu was moving to the southwest and had weakened. Maximum sustained winds were near 75 knots (75 mph/120 kph) making the storm a category one hurricane on the Saffir-Simpson Hurricane Wind Scale. The AIRS imagery showed that the storm appeared more elongated, indicating that vertical wind shear was increasing and having an adverse effect on it, so Vayu was weakening.
The Joint Typhoon Warning Center expects Vayu to turn to the northeast in a day and a half and make landfall near the India/Pakistan border by June 17.
For updated forecasts from the India Meteorological Department, visit: http://www.imd.gov.in
June 14, 2019 – NASA Finds Tropical Cyclone Vayu off India’s Gujarat Coast
NASA’s Terra satellite showed Tropical Cyclone Vayu still lingering near the northwestern coast of India, and its cloud-filled eye remained offshore.
On June 14, 2019, the MODIS instrument aboard NASA’s Terra satellite provided a visible image of Tropical Cyclone Vayu off India’s Gujarat coast, western India. Credit: NASA Worldview, Earth Observing System Data and Information System (EOSDIS)
On June 14, 2019, t the Moderate Resolution Imaging Spectroradiometer or MODIS instrument aboard NASA’s Terra satellite provided a visible image of Tropical Cyclone Vayu located off western India’s Gujarat coast. Animated enhanced infrared satellite imagery revealed a compact area of asymmetric central deep convection (building thunderstorms) with well-organized spiral banding wrapping into a cloud-filled ragged eye.
JTWC forecasters noted that there are several things happening with the storm that is affecting the strength and shape of it. Dry air continues to feed into the storm, which prevents the development of thunderstorms (that make up the tropical cyclone). However, that is offset by low vertical wind shear (outside winds blowing at different speeds at different levels of the atmosphere that if strong enough, can blow a storm apart). Vayu is also moving through very warm waters, as warm as 30 to 31 degrees Celsius (86 to 87.8 degrees Fahrenheit) that is keeping the storm together. Tropical cyclones require sea surface temperatures of at least 80 degrees Fahrenheit (26.6 degrees Celsius) to maintain them. Warmer sea surface temperatures help keep storms together or give them fuel to strengthen further.
At 5 a.m. EDT (0900 UTC), the Joint Typhoon Warning Center or JTWC reported that Tropical Cyclone Vayu was located near 20.8 degrees north latitude and 68/0 east longitude. That is 248 nautical miles south-southeast of Karachi, Pakistan. Vayu has turned to the west-southwest. Maximum sustained winds had dropped to 85 knots (98 mph/157 kph) and the storm is forecast to continue weakening.
The JTWC has forecast Vayu to curve back to the northeast and make landfall in four days along the northwestern India/Pakistan border on June 17.
