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Joshimath: new InSAR analysis sheds light on active deformation
In Joshimath the landslide crisis continues, imposing a big impact on the people of the town. Apparently the investigation of the landslide is ongoing, although the exact nature of this is unclear. There is a very bold statement from unnamed “scientists” that the situation is getting better. The New Indian Express reports that:-
“The land of the land submergence area in Joshimath is trying to stabilise,” the scientists believe. However, it will take some more time.
As soon as the summer starts, there will be a positive change in the situation. “The flow of water in JP Colony of Joshimath, which was happening at a speed of 10 litres per second, is now happening at 1.9 litres per second, which is comforting,” said scientists, who didn’t want to be named.
This is slightly odd. First, the summer is a long way hence, and second the summer will bring monsoon rainfall, which is unlikely to help (although it will not necessarily have an adverse effect). Finally, of course, the land is not trying to do anything except obey the laws of physics.
More importantly, we now have additional insight into the landslide from a new InSAR analysis undertaken using the Sentinel-1 instrument. This has been undertaken by renowned scientists from AUTh (Aristotle University of Thessaloniki) and CNRS-EOST (Centre National de la Recherche Scientifique / Ecole et Observatoire des Sciences de la Terre / Strasbourg) using the SNAPPING PSI Full Resolution service. The work has been released online and is freely available, with further analyses under way.
The team has produced two sets of analyses, including a times series for the movement of the slopes. The first examines movement over the period from January 2018 to 31 December 2022:-
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This diagram clearly shows the various landslide units upon which the town is built, and the movement patterns that they display in the long term. It confirms that the deformation is sliding, not subsidence, as expected.
A really important element of this work is that the team has produced a time series plot for points shown on the diagram above:-
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There are a few things to note here. First, in the long term the different parts of the landslide complex are moving at different rates, which is not unusual. Point 1 is showing large displacements – almost half a metre with continuous creep, although the rate clearly fluctuates with time (this is similar to the results we got for the Utiku landslide in New Zealand for example). Other parts of the complex are moving more slowly, and indeed the point highest up the slope is not moving.
Point 3 shows a significant change in movement rate in late 2021.
The second analysis undertaken by the team examines movement over the last few weeks:
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The analysis shows that three portions of the landslide complex are currently moving, with the highest rates towards the lower part of the slope. The boundaries of the movement coincide with the margins of the landslide blocks identifiable from Google Earth. We would expect to see some of the greatest amounts of building damage occurring around these margins. Thus, it is really interesting to compare the above diagram with the map posted to Twitter by Thiyagarajan J (@jThiyagu) that shows the location of the wards damaged by the landslide:-
#JoshimathIsSinking ! These custom maps show #Joshimath city with markers of approx areas where buildings are affected (as reported in press).
From the Tunnel, the closest area is Parsari ward (500m) and the farthest is Marwadi ward (2600m), approx. @rajbhagatt @rajatpTOI pic.twitter.com/fvW2fnTjKI— Thiyagu 🇮🇳 (@jThiyagu) January 8, 2023
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There is a strong coincidence, which suggests that these analyses are starting to pin down in more detail the nature of the landslide problem at Joshimath.
Movement of landslide complexes such as this is very complex, and we would expect to changes in the rate occurring through time. Thus, great care is going to be needed in interpreting short duration time series data. But, the bottom line is that this slope is unlikely to achieve permanent stability in its current physical state without significant engineering intervention. The current crisis will abate at some point, but the underlying chronic problem, whatever the cause, is likely to remain. That is not to say that all is lost by any means, the immediate crisis will pass, but action is likely to be needed.
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Acknowledgement
Many thanks to colleagues from AUTh (Aristotle University of Thessaloniki) and CNRS-EOST (Centre National de la Recherche Scientifique / Ecole et Observatoire des Sciences de la Terre / Strasbourg) for making this analysis available online.
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