Subject: Geography Paper: Physical Geography-I Paper Code: C 102 Unit - II Topic: THE THEORY OF PLATE TECTONICS PHYSICAL GEOGRAPHY-I THE THEORY OF PLATE TECTONICS 4.1 INTRODUCTION TO THEORY OF PLATE TECTONICS 4.2 CONCEPT OF PLATE TECTONICS AND PLATE BOUNDARIES 4.3 CAUSES AND THE RATES OF MOVEMENT OF PLATES 4.4 CONSEQUENCES OF PLATE TECTONICS 4.5 PLATE TECTONICS IN AND AROUND INDIAN SUB-CONTINENT 4.1 INTRODUCTION TO THEORY OF PLATE TECTONICS In this section we are dealing with the most recent discoveries of the Earthâs crust. These have provided highly valuable findings related to geology, geo-chemistry and geophysics in understanding not only the earthâs crustal dynamics but also the contents of earthâs crust. To be specific, since 1960âs these discoveries have given substantial scientific understanding of upper crustal plates i.e. the continents and ocean basins with little more down ward crust all together movement along the cracks which are found on earthâs crust. As we know by this time the findings and substantial scientific literature related to earthâs structure particularly this movement of plates has supported the theory of continental drift by Wegener. As we will be coming latter in this topic that theory of plate tectonics has shed light on the spread of ocean floor, magnetism of newly formed earthâs crust materials, about associated endogenetic phenomena like volcanoes and earthquakes. It is very interesting to note that, this theory of plate tectonics has substantiated the others an aspect of earth crust like mountain building and even mineralization. In this section let us try to understand the elements and principles of theory of plate tectonics while touching briefly other associated factors. It must be remembered that, the whole concept of crustal movements i.e. plate tectonics was hypothesis in sixties but due to substantial empirical findings of American and European Geologists and other Earth scientists now it is a well known and applied theory in the field fo Earth Sciences including physical Geography. 4.2 CONCEPT OF PLATE TECTONICS AND PLATE BOUNDARIES The concept of plate tectonics suggests that the Earthâs surface layers are divided into large segments on plates. The plates are approximately 100 km thick and therefore include the Earthâs crust together with part of the upper mantle, but measure several thousand kilometers across. Fig.1 According to findings, that there are six major plates and there are about 20 minor plates (See Fig.1) Plates move over the face of the Earth either they move away from one adjacent plate, towards the another and between further pair. These plate movements result in three types of plate boundary (See Fig.2). (a) A boundary where two plates move apart: It so happens that, a fissure develops, allowing hot, molten rock to well up from the mantle (i.e. the zone in the earth between the crust and the core extending from 50 km to 2900 km depth) and to form new plate material as it solidifies. The fissure is called a âspreadingâ on âpull apartâ zone and this type of plate boundary is known as a âConstructive plate boundaryâ or âdivergent plate marginâ. Quite away from the shores of continental landmasses, on the deep ocean floor we see such constructive plate boundaries Ex. Mid Atlantic ridge between American and Europe and Africa, Indian mind oceanic ridge between Africa and S.W. Indian Plates and Pacific ridge between S.W.N America west of S. America and S.E. of Australia in the deeps of Pacific. b) A boundary where two plates collide: In the process of plate tectonics, the more denser plate will normally be deflected beneath, the less dense, and will be destroyed and absorbed at depth into mantle. Such plate destruction takes place at the zone of seduction, and the boundary is known as destructive plate boundary on convergent margin. In fact, this type of plate boundaries happens to be closer to continental landmasses i.e. the coastal zones of continent. Ex. The Western Pacific subduction plate boundary which forms one of the dangerous sections âPacific Griddle of Fireâ is closer to Japan, Philippines and New Zealand. All along, west coast of North and South American other segment of Pacific ring of fire form subduction plate boundary between denser pacific plate and lighter American continental plate. (c) Boundaries where two plates slide Past one another : In the process of plate movements there are situations where two plates slide past one another. There are known as shear margins, where little, if any interaction takes place between the rocks/plates on either side. These are also known as âtransform fault marginsâ. It appears that this kind of shear zone plate boundaries occur near junction of mid oceanic ridges. A careful study of Fig. No.1 shows such shear zones of plates ex. In South Pacific where Antarctic northern plate boundary meets Nazaca plate and American Southern plate boundaries. One such shear zone happens in South Atlantic and South Indian Oceanic mid ocean ridges meeting Antarctic plate boundary respectively. 4.3 CAUSES AND THE RATES OF MOVEMENT OF PLATES 4.3.1 Causes â Sea floor spreading : Geographical findings of Hary Hess and others have established that the mid- oceanic ridges were situated on the rising thermal convection currents coming up from the mantle (See Fig.3). The oceanic crust moves in opposite directions from mid oceanic ridges and thus there is continuous upwelling of new mouton materials (Lava) along the mid oceanic ridges. This according to these those molten lavas cool down and solidify to form a new crust along the traiting ends of divergent plates of mid oceanic ridges (oceanic crust). Thus there is a continuous creation of new crust along the mid oceanic ridges. This proves that sea floor spreads along the mid-oceanic ridges and the expanding crusts (plates) are destroyed along the oceanic trenches. These facts prove that the continents and oceanic basins are in constant motion. 4.3.2 Magnetic Profiles along ridges : W.G. Vine and Eard Mathews have conducted the magnetic survey of the central part of Carlsberg ridge in Indian Ocean and computed the magnetic profiles on the basis of general magnetism, when they compared the computed magnetic anomalies plotted on the basis actual data obtained during the survey and they found that there is sizeable difference between the two profiles. When he plotted the magnetic profiles on the basis of alternate bonds of normal and reverse magnetism in separate stripes of 20 km width on either side of the ridge, they found complete parallelism between the computed profiles and observed profiles (See. Fig. 4). This figure shows the position of magnetic stripes on either side of the mid oceanic ridge along with their time scale of their formation. Fig.3 This also proves that there is a continuous spreading of sea floor. New basaltic crust is continuously formed along the mid oceanic ridges. The newly formed basaltic layer is divided into two equal halves and is thus displaced away from the mid oceanic ridge. Alternate stripes of positive and negative magnetic anomalies are found on either side of mid oceanic ridges. Such magnetic (positive and negative) anomalies are formed because of temporal reversal in the magnetic field. The rocks formed during normal magnetic field contain positive magnetic anomalies while their rocks formed during revere polarity (reverse magnetic field) denote negative magnetic anomalies. 4.3.3 The rates of Seafloor Spreading: Recent ocean floor geophysical empirical findings have shown that, the Pacific Ocean floor is spreading faster than the Atlantic and Indian Ocean floors. Pacific Ocean floor spreading is 6 to 9 cms per year on one side of the ridge. (i.e. 12 to 18 cms on either side put together) In some of it sections like along the Eastern Pacific ridges between equator and 30° South latitude is still more. Whereas the Southern Atlantic Ocean is spreading along southern Atlantic ridge at the rate of 2 cm per year (total expansion 4 cm/year). The Indian floor spreading at the rate of 1.5 to 3 cms per year indicating a total expansion of 3 to 6 cm per year. From this it becomes clear that, Indian and Atlantic oceans are expanding sluggishly and also have relatively they have less number of Earthquakes and even in their frequency too. But the Pacific Ocean is expanding rather fast with its âRing of fireâ around and also with its more frequent even violent earthquakes. Fig.4 4.4 CONSEQUENCES OF PLATE TECTONICS 4.4.1 Plate Tectonics and Continental Displacement : Findings related to paleomagnetism of earthâs crust and seafloor spreading have revealed that, the continents and ocean basins have never been stationary or permanents. Rather, they have always been mobile throughout the geological history of the earth. They are still moving in relation to other. Earth scientists have discovered sufficient evidences to demonstrate the opening and closing of ocean basins. For example, the Mediterranean Sea is the residual of once very vast ocean (Tethys sea) and the Pacific Ocean is continuously contracting because of its gradual seduction near American plate. On the other hand the Atlantic ocean is continuously expanding for the past four million year. Red sea has started to open i.e. expanding. It may be mentioned that, continental masses come closer to each other when oceans begin to close, while continents are displaced away when the oceans begin to open i.e. expand. Geophysical investigations about earthâs Paleomagnetism in particular have shown that, about 700 million years ago all the land masses were united together in the form of one giant land mass known as Pangea-I Little latter (600-500 m.y BP) this first Pangea was broken because of thermal convective currents coming from within the Earth continents were drifted apart. These land masses were again united due to plate motions and again formed into one big landmass known a Pangea-II about 300-200 million years B.P. (See Fig.5). This second Pangea broke around 200 m.y. BP in the early Jurassic period and Africa detached from N. America and drifted away. The zone of sea floor spreading continued to extend towards north and south. The separation of South America and Africa was accomplished during middle Cretaceous period. North America and Europe began to move away from each other (See Fig. No.6). Opening of North America was accomplished in many phases. After the separation of N. America from Africa, Europe and Greenland broke away from Labrador during late Cretaceous period (80 m.y. BP) and thus Labrador was formed. This newly formed sea continued to remain for sometime as northern extension of the Atlantic Ocean. Labrador Sea and N. Atlantic continued to expand between Europe and Greenland upto middle Miocene period because the European and American plates continued to move eastward and westward respectively. Fig.5 Indian Ocean did not exist before Cretaceous period. Indian plate began to move towards Eurasian Asiatic plate through âTethys seaâ and Australian Antarctic plates after breaking away from African plate began to move south ward during Cretaceous period. Mackenzic and John Slater have presented the chronolocal sequence of the evolution of the Indian Ocean on the basis of magnetic anomalies. According to them Indian plate began to move north wards at the rate of 18 cm per year. At the same time Antarctica Plate broke way from Australia. Thus the Pacific Ocean began to shrink in size because of the expansion of Atlantic and India Oceans. Fig.6 There are two specific case studies which prove further the plate tectonics (1) Red sea is spreading at the rate of total 2 cm per year since 3-4 million years. In fact Red Sea and Gulf of Aden are located at the Junction of three plateâs namely Nubian plate, Somali plate and Arabian Plate. In the course of geological history in post Tertiary times Nubian and Somali plates are separated Ethiopian fault. West Asian frequent Earthquake phenomena are linked to movement of these plates. 4.5 PLATE TECTONICS IN AND AROUND INDIAN SUB-CONTINENT: From the previous discussion it is amply clear that, Indian and its southern neighbourhoods including Indian ocean and Australia are one of the major plates i.e. âIndian Plateâ. This plate is moving in northerly direction, and this plate movement since 200 million years has pushed Indian plate against Eurasian plate. Consequently West Ocean existed in between Eurasia and Gondwana (India particularly) shrunk, its sea folded beds raised and formed the mighty Himalayas. According to Geologists still Himalayas are rising by a few cms per year which is due to plate tectonics. However, according to recent geophysical investigations Indian plate has shear zones in its eastern sides and strikes against Pacific plate (S.E. Asian side). This leads to violent earthquakes often worst Tsunamis for ex. 2007 Banda Ach This destroyed a portion of Andaman Nicobar Islands which is also the last point of India. Indira point (former Pigmelian point) is drowned and it is in deep waters of S.E. Bay of Bengal. In this zone we have our lonely dormant volcanoeâBarren Island which is located towards NE of Port Blair in Andamans. In its Western neighbourhood Indian plate had shear zones of Arabian and Somali plate of African plate (See Fig.7). Though the later forms divergent plate boundary under Red Sea zone, Arabian plate has impacts on minor collision with Indian plate. It appears that a very high magnitude earth quake which took place in 2001 in Gujarat has link with this side plate tectonics. On to its southern most plate boundary as it is a divergent boundary, Indian plate has relatively peaceful crustal conditions. However, seismologists, are of the opinion that the Indian continental plate i.e. peninsular Indian is getting older which may tringer geological lineaments as active earthquake zones in years to come. Fig.7