We actually have come up with a very consistent techniques and results that can predict the upcoming earthquake (more than 7 Mw) based on offline public data within a few days namely short-term prediction instead of the not so useful early detection (after the earthquake event) and the useless forecast (will happen within this decade). The paper have been rejected for many times now by many prominent journals for example Nature and Science, heck it's even rejected by arXiv.org. Apparently it's a taboo to perform a study and claim on short-term earthquake by USGS, and they even make fun of it that I think is pretty childish to put in a professional website [1],[2]. However, based on our results for short-term prediction of offline data, they are very consistent for five recent major earthquakes across five earthquake prones countries.
[1] Can you predict earthquakes?
https://www.usgs.gov/index.php/faqs/can-you-predict-earthqua...
[2] 100% Chance of an Earthquake:
https://www.usgs.gov/programs/earthquake-hazards/100-chance-...
I though the Himalayas were formed from the Indian subcontinent slamming into the Eurasian land mass?
So the Himalayas have formed at the same time with a great number of mountain ranges, from the Atlas and the Pyrenees at the Western extremity, passing through many other mountains, e.g. the Alps, the Carpathians, the Caucasus, the Hindu Kush, the Pamir etc., until the Himalayas at the Eastern extremity.
See:
India being pulled away from Africa/Madagascar and eventually beneath the Eurasian continental crust is all related to the closing of the Tethys. ...This is a lot easier to explain with pictures...
If it helps, remember that continents are just lighter and thicker "rafts" of stuff. They're not plates themselves. They're often attached to oceanic crust as part of a plate. When one side of that oceanic crust becomes cold and thick enough to start to subduct, the entire plate gets pulled along.
"One notably (and perhaps ominously) quiet section of the fault is the 220 km long Meiktila segment, between the large city of Mandalay and the new capital of Naw Pyi Daw. This long quiet section separates a southern cluster of ruptures in 1929 and 1930 from a northern cluster between 1931 and 2012. The length of the Meiktila segment implies that it is capable of producing an earthquake as large as Mw 7.8 to 7.9, if it ruptures all at once [Wells and Coppersmith, 1994; Blaser et al., 2010] (Figure 22 and Table 4).
We speculate, on the basis of sparse historical records of shaking, that the 1839 Ava earthquake may have resulted from the failure of Meiktila segment, in conjunction with the Sagaing segment, its neighbor on the north. If the Meiktila segment has been dormant since then, and the fault is fully coupled down to a depth between 12 and 15 km, as Vigny et al. [2003] and Socquet et al. [2006] suggest, then accumulated slip potency on the Meiktila segment after 1839 is enough to generate a Mw 7.6 earthquake."