ISRO-NASA satellite NISAR to map Himalayas’ seismic zones

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ISRO-NASA satellite NISAR to map Himalayas’ seismic zones


A big part of the Himalayan area falls in Zone V, with the very best threat of sturdy earthquakes.
| Photo Credit: Okay.R. Deepak

A forthcoming satellite, NISAR, collectively developed by the Indian Space Research Organisation (ISRO) and the National Aeronautics and Space Administration (NASA) of the U.S. will map essentially the most earthquake-prone areas within the Himalayas with unprecedented regularity. The knowledge it will generate can doubtlessly give advance warning of land subsidence, as just lately noticed in Joshimath, Uttarakhand, as effectively level to locations which can be at biggest threat from earthquakes.

The NISAR satellite, anticipated to value roughly $900 million (with ISRO contributing about one-tenth) will use two frequency bands: the L-band and S-band to picture the seismically energetic Himalayan area that can, each 12 days, create a “deformation map”, stated Prakash Chauhan, Director, ISRO-National Remote Sensing Centre at a seminar right here this week.

“The geoscience community can use this to determine how strain is building up in various parts of the Himalayas,” he stated. These two frequency bands will collectively present high-resolution, all-weather knowledge from the satellite that’s anticipated to observe a sun-synchronous orbit and can be launched in January 2024.

Strain refers to the deformation that happens in rocks when it’s underneath stress from different rocks, normally due to actions of continental plates which can be sliding, colliding, or subducting in opposition to one another. The Indian Plate, for example, collided into the Eurasian plate forming the Himalayas and continues to incrementally push it upwards.

Based on the depth of previous earthquakes, the information of the pace at which plates transfer and the places at which plates work together (known as faults) might help geologists and seismologists map out areas which can be most weak to earthquakes and estimate how far the resultant tremors can unfold. What can’t be deduced nevertheless is the timing. Ground-based observatories can choose up underground waves that end result from an earthquake and supply early warning. Satellites, relying on how they’re positioned and by advantage of their distance from the Earth can picture a large swathe and, if monitored steadily, can present how mountains and geological formations are altering over time.

Scientists from the Geological Survey of India in 2021 revealed a “strain map” of the Himalayas based mostly on knowledge from 1,252 GPS stations alongside the Himalayas. It recognized areas that had the best odds of producing earthquakes of magnitude above 8 and their extent. “ These many stations are still too few and there’s only one satellite (Sentinel) that we rely on…with NISAR, the costliest space mission ever, we can have a game-changer in earth-science observation,” stated Dr. Chauhan.

While satellite imagery to research deformation in land is already employed, the frequency at which observations are taken and the readability of the photographs are essential, V.Okay. Gahalaut, of the National Geophysical Research Institute (NGRI), advised The Hindu. “With a frequency of 12 days and the ability to be able to provide images even under cloudy conditions, NISAR would be a valuable tool to study deformation patterns, such as in Joshimath,” he added.

Land subsidence or the loosening of the sub-surface had precipitated a number of components of Uttarakhand to “sink” and this precipitated water to seep through cracks and crevices into homes. In 2021, a big landslide of rock and ice triggered a flash flood in Chamoli, Uttarakhand that claimed shut to 200 lives and destroyed two hydropower initiatives. It was satellite imagery that helped scientists decipher the reason for the flash floods.



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