The Quran and Mountains: Difference between revisions

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The [[Qur'an|Quran]] has a particular conception of the nature of mountains, their formation, and the geological role they play that is is referenced in multiple verses and several [[Hadith|hadiths]]. In recent times, many Islamic scholars have argued that this conception is both scientifically sound and and instance of [[Scientific Miracles in the Quran|miraculous scientific foreknowledge]] on the part of the Quran which, they argue, could not have arrived at the conception it holds without divine insight. Individuals key to the popularization of this idea include the [[Apologists|apologists]] I. A. Ibrahim and [[Zakir Naik]], Professor Zaghloul Raghib El Naggar (a geologist specializing in biostratification), and the Saudi-financed surgeon [[Bucailleism|Dr. Maurice Bucaille]].
The [[Qur'an|Quran]] has a particular conception of the nature of mountains, their formation, and the geological role they play that is is referenced in multiple verses and several [[Hadith|hadiths]]. In recent times, many Islamic scholars have argued that this conception is both scientifically sound and and instance of [[Scientific Miracles in the Quran|miraculous scientific foreknowledge]] on the part of the Quran which, they argue, could not have arrived at the conception it holds without divine insight. Individuals key to the popularization of this idea include the [[Apologists|apologists]] I. A. Ibrahim and [[Zakir Naik]], Professor Zaghloul Raghib El Naggar (a geologist specializing in biostratification), and the Saudi-financed surgeon [[Bucailleism|Dr. Maurice Bucaille]].


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As above, there is no scientific evidence which demonstrates that mountains stabilize the lithospheric plates, and El Naggar provides no references. By contrast, there is scientific evidence that suggests that continental plates are stabilized by craton keels. Craton keels are deep extensions of cratons into the mantle which extend any where from 60-300km below the surface. These keels extend far deeper than mountain roots. The formation of these craton roots, or keels, is, however, unrelated to mountains or their formation.<ref>Jordan, T. H., Nature, 1978, 274, 544–548; Elasser, W. M., in The Application of Modern Physics to Earth and Planetary Interiors (ed. Runcorn, S. K.), Interscience, New York, 1969, pp. 223– 240; Morgan, W. J., J. Geophys. Res., 1968, 73, 1959–1970</ref>  
As above, there is no scientific evidence which demonstrates that mountains stabilize the lithospheric plates, and El Naggar provides no references. By contrast, there is scientific evidence that suggests that continental plates are stabilized by craton keels. Craton keels are deep extensions of cratons into the mantle which extend any where from 60-300km below the surface. These keels extend far deeper than mountain roots. The formation of these craton roots, or keels, is, however, unrelated to mountains or their formation.<ref>Jordan, T. H., Nature, 1978, 274, 544–548; Elasser, W. M., in The Application of Modern Physics to Earth and Planetary Interiors (ed. Runcorn, S. K.), Interscience, New York, 1969, pp. 223– 240; Morgan, W. J., J. Geophys. Res., 1968, 73, 1959–1970</ref>  


Critics also point out that cratons are stable regions of the earth's crust that are no longer subject to mountain building processes. These craton roots or keels form through the depletion of basaltic elements into the asthenosphere, leading to less dense material that sinks deeper into the mantle due to the lower buoyancy (i.e. the isostasy of the crust, rather than the mountains). <ref>Sankaran, A.V. - [{{Reference archive|1=http://www.ias.ac.in/currsci/nov102001/1158.pdf|2=2011-10-02}} CURRENT SCIENCE] - VOL. 81, NO. 9, 10 NOVEMBER 2001 pp. 1158-1160</ref>
Critics also point out that cratons are stable regions of the earth's crust that are no longer subject to mountain building processes. These craton roots or keels form through the depletion of basaltic elements into the asthenosphere, leading to less dense material that sinks deeper into the mantle due to the lower buoyancy (i.e. the isostasy of the crust, that is, rather than of the mountains).<ref>Sankaran, A.V. - [{{Reference archive|1=http://www.ias.ac.in/currsci/nov102001/1158.pdf|2=2011-10-02}} CURRENT SCIENCE] - VOL. 81, NO. 9, 10 NOVEMBER 2001 pp. 1158-1160</ref>


===The relationship between mountains and earthquakes===
===The relationship between mountains and earthquakes===


As early as the 1920s, scientists noted that earthquakes are concentrated in very specific narrow zones (Wadati-Benioff zones). In 1954, French seismologist J.P. Rothé published this map showing the concentration of earthquakes along the zones indicated by dots and cross-hatched areas.<ref>[{{Reference archive|1=http://pubs.usgs.gov/gip/dynamic/zones.html|2=2011-10-02}} Earthquake zones] - U.S. Geological Survey</ref><center>[[File:Map by J.P. Rothé.gif|500px]]</center>
Critics also point out that, as early as the 1920s, scientists noted that earthquakes are concentrated in very specific and narrow zones arounds the planet (known as Wadati-Benioff zones). In 1954, French seismologist J.P. Rothé published a map showing the concentration of earthquakes along the zones indicated by dots and cross-hatched areas.<ref>[{{Reference archive|1=http://pubs.usgs.gov/gip/dynamic/zones.html|2=2011-10-02}} Earthquake zones] - U.S. Geological Survey</ref><center>[[File:Map_by_J.P._Rothé.gif|alt=|center|thumb|425x425px]]</center>


Note how the earthquakes originate mainly from the edges of tectonic plates, including collisional mountain ranges and ocean trenches and ridges, thus suggesting that mountains do not stabilize the crust or the earth.  
Critics note how the earthquakes originate mainly from the edges of tectonic plates, including collisional mountain ranges and ocean trenches and ridges, which demonstrates that mountains do not stabilize the crust or the earth. The presence of mountains on any part of the Earth's surface thus often suggests the presence of precisely those underground geographical circumstances which generate earthquakes. Critics cite the Himalayan mountain range as a specific example of a mountain range which, rather than preventing earthquakes, is in fact closely associated with them. <center>[[File:Seis-states.gif|alt=|center|frame]]</center>
 
Further evidence is provided by a detailed look at the Himalayan mountain range which shows that it is closely associated with earthquakes, thus proving mountains do not prevent earthquakes.  
<center>[[File:Seis-states.gif]]</center>
{{Quote|[{{Reference archive|1=http://asc-india.org/menu/seismi.htm|2=2011-10-02}} Seismicity of South Asia]<BR>Amateur Seismic Centre|Why do earthquakes happen here?  
{{Quote|[{{Reference archive|1=http://asc-india.org/menu/seismi.htm|2=2011-10-02}} Seismicity of South Asia]<BR>Amateur Seismic Centre|Why do earthquakes happen here?  
The Indian subcontinent lies upon the Indian Plate. This plate is moving northward at about 5 centimetres per year and in doing so, collides with the Eurasian Plate. Upon the Eurasian Plate lie the Tibet plateau & central Asia. '''Due to this mammoth collision, the Himalayas are thrust higher and very many earthquakes are generated in the process. This is the cause of earthquakes from the Himalayas to the Arakan Yoma.''' The same process, though involving the Indian Plate and the Burmese Micro-plate results in earthquakes in the Andaman & Nicobar Islands. Sometimes earthquakes of different magnitudes occur within the Indian Plate, in the peninsula and in adjoining parts of the Arabian Sea or the Bay of Bengal. These arise due to localized systems of forces in the crust sometimes associated with ancient geological structures such as in the Rann of Kachchh.}}  
The Indian subcontinent lies upon the Indian Plate. This plate is moving northward at about 5 centimetres per year and in doing so, collides with the Eurasian Plate. Upon the Eurasian Plate lie the Tibet plateau & central Asia. '''Due to this mammoth collision, the Himalayas are thrust higher and very many earthquakes are generated in the process. This is the cause of earthquakes from the Himalayas to the Arakan Yoma.''' The same process, though involving the Indian Plate and the Burmese Micro-plate results in earthquakes in the Andaman & Nicobar Islands. Sometimes earthquakes of different magnitudes occur within the Indian Plate, in the peninsula and in adjoining parts of the Arabian Sea or the Bay of Bengal. These arise due to localized systems of forces in the crust sometimes associated with ancient geological structures such as in the Rann of Kachchh.}}  
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