Microsoft Word - 6 Katupotha Katupotha /Journal of Tropical Forestry and Environment Vol. 3, No. 01 (2013) 42-54 42 Palaeoclimate change during Glacial Periods: Evidence from Sri Lanka J. Katupotha Department of Geography, University of Sri Jayewardenepura, Nugegoda, Sri Lanka Date Received: 24-11-2012 Date Accepted: 16-02-2013 Abstract In the Earth’s history, there were five major glaciations, namely, Huronian (2,300 Ma), Cryogenianor Sturtian-Varangian(850-635 Ma), Andean-Saharan (460-430 Ma, Karoo (360-260 Ma) and the Quaternary (2.58 Ma to Present) that occurred between 2,300 Ma and 0.0114 Ma. It is revealed that Gondwanaland emerged between the Huronian glaciation (2300-2100 Ma) in the Paleoproterozoic Era and the Andean-Saharan glaciation (460-420 Ma) in the Early Paleozoic Era. During this time, most continental land masses were clustered in the southern hemisphere, and Sri Lanka was part of the Gondwanaland landmass comprising present day Africa, Madagascar, India and Antarctica. Within the Ordovician (485.4-445.2Ma) to Permian Periods (299.0-254.2 Ma) there were signs of the breaking up of Gondwanaland resulting in the severing of India and Sri Lanka together and subsequently Sri Lanka from India. By end of the Permian Period (260 Ma) Karoo Glaciation had ended and the present Mannar Basin developed within a deep canyon (about 4-7 km deep) on the Precambrian basement. Although the island of Sri Lanka presently lies in the Indian Ocean between 5 º 52´N-9 º 54´N and 79 º 30´E-81 º 55´E, to the southwest of Bay of Bengal and southeast of Arabian Sea, it was positioned within 67 º S-65 º S and 34 º E-43 º E during the Lower and Middle Jurassic Era (201.3-166.1 Ma). Huge rocky blocks (erratic boulders) have been transported to different places by continental ice sheets due to climatic changes in the Permian, Triassic and Jurassic Periods, but erratic pebbles (2 to 8 cm or more in size) and streams fed deposits have been transported by glacifluvial processes. These glaciofluvial processes occurred on four occasions during the Jurassic Period and Eocene, Miocene and Pliocene Epochs on Sri Lankan landmass, which fallowed the climatic changes and sea level fluctuations that broke up the sedimentary beds, initiating establishment of the present topography and structural configuration. As a result, the earlier sedimentary deposits were obliterated from greater part of Sri Lanka. During the Quaternary Period the erosional rate increased and the resultant erratic boulders along with glaciofluvialdeposits can still be found on “Planated Surfaces”of Sri Lanka. 1. Introduction From the time of initial accretion and differentiation (ca. 4560 Ma) to the first appearance of abundant hard-bodied fossils, the Precambrian Super Eon spans 88 percent of Earth history (Felix et al., 2004).Sri Lanka is a tropical island positioned between 5 º 50´N-9 º 55´N and 79 º 30´E-81 º 55´E, southwest Bay of Bengal and southeast Arabian Sea in the Indian Ocean. Although Sri Lanka became a separate landmass during the Triassic-Jurassic Period (208.5-201.3 Ma), its history goes back to the Achaean Eon of the Precambrian Super Eon that is divided into six Eons, with boundaries defined by what can be considered first-order “watersheds” in the evolution of the Earth (Felix et al., 2004). *Correspondence: katupotha@gmail.com Tel: +94 71 8011540 Fax: +94 11 5524530 ISSN 2235-9370 Print / ISSN 2235-9362 Online ©2013 University of Sri Jayewardenepura Katupotha /Journal of Tropical Forestry and Environment Vol. 3, No. 01 (2013) 45-57 43 Sri Lankan rocks have been documented to be late Archaean to early Proterozoic (3,200 - 2,400 Ma) based on ages of detrital grains zircons obtained from Highland/Southwestern Complex (H/SWC) rocks. It is revealed that these rocks have a relationship with Precambrian events, and therefore to be the foundation rocks or basement rocks of Sri Lanka (Hölzlet al. 1991; Kröneret al. 1991). By the Paleoproterozoic Era (2,050 - 1,800 Ma), the rugged high ground occupying the Highland Complex (HC) of Sri Lanka (Cooray 1994) became characterized by a NW-SE and NE-SW trending sequence of high- grade metasediments and granuliticorthogneisses. Likewise, during the Mesoproterozoic Era (1600-1200 Ma), orthogneisses of the Vijayan Complex (VC) were intruded between 1,040-1,030 Ma and orthogneisses of the Wanni Complex (WC) were intruded between 1,100-670 Ma. Moreover, by the Neoproterozoic Era between 610 and 550 Ma, the high-grade regional metamorphism of the HC, VC and WC took place within ultra-high temperature metamorphic rocks (Braun, 2003). All these Proterozoic rocks are the basement rocks of Sri Lanka. In the Earth’s history, there were five major glaciations, namely, the Huronian, Cryogenian or Sturtian-Varangian, Andean-Saharan, Karoo (Carboniferous and Permian Period) and the Quaternary that occurred between 2,300 and 0.0114 Ma (ICS 2009). It is accepted that Gondwanaland emerged between the Huronian Glaciation (2,300-2,100 Ma) in the Paleoproterozoic Era and the Andean-Saharan Glaciation (460-430 Ma) in the Early Paleozoic Era. Wanless and Cannon (1966) reported the events of Late Paleozoic Glaciation from India and Pakistan, Africa, South America, Australia, Antarctica, Madagascar and Falkland Islands. During these glacial times, most of the continental land masses mentioned above were clustered in the southern hemisphere, and the landmass of Sri Lanka remained joined to the landmass of Africa-Madagascar-India that was joined to Antarctica. Although the present landmass of Sri Lanka lies southwest of Bay of Bengal and southeast of Arabian Sea, it was positioned within 67 º S-65 º S and 34 º E-43 º E during the Lower and Middle Jurassic Era (201.3-166.1 Ma). Climatic changes in the Permian, Triassic and Jurassic Periods huge rocky blocks (erratic boulders) have been transported to different places by continental ice sheets. Likewise erratic pebbles, smaller stones from 2 to 8 cm or more, andstreams fed deposits have been transported by glacifluvial processes (Table 1). This paper proposes that these glaciofluvial processes that occurred on four occasions namely, the Jurassic Period and Eocene, Miocene and Pliocene Epochs due to geologicand climatic changes and sea level fluctuationsbroke up the prevailing glaciofluvial sedimentary beds, giving rise to the present topography comprising, “Planated Surfaces”, relict erratic boulders and ice-rafted or streams fed deposits. Quesnelet al. (2012) have proposed a geomorphologic classification of planation surfaces and inferred scenarios of vertical deformation and morphogenetic evolution by applying the planation surface concept, previously used for stable cratonsof western Africa, Australia and Brazil- Guyana which endured glacial times. This is the first attempt to postulate that Sri Lanka had endured glacial climate as revealed by the incidences of erratic boulders, erratic pebbles and streams fed deposits. Both erratic pebbles and stream fed deposits weredeposited from melt-water of the Karoo (Carboniferous - Permian Period, 360-260 Ma) glaciers since the Middle Triassic to the Early Eocene Period (247.2-56.0 Ma). By Early Eocene time, Sri Lanka was located between 18-24 o S and 63-66 o E (Table 1). In this effort, information gathered from detailed investigations of erratic boulders located along the coastal belt in the Eastern Province (Second Planated Surface) and erratic boulders and streams fed deposits of the Kurunegala District, Northwestern Province (Second and Third Planated Surfaces) further validated glaciation and climate change. 2. Methodology In the Earth’s history, glacial and interglacial periods have played a significant role in the evolution of continentsand palaeoclimate together with fauna and flora, ice-rafted and streams fed deposits etc.Poulsenet al (1977) present evidence that Late Paleozoic tropical climate responded to Katupotha /Journal of Tropical Forestry and Environment Vol. 3, No. 01 (2013) 42-54 44 Gondwanan de-glaciation. There are also many geological, geomorphological, palaeontological and sedimentological evidences that can be found on land (from continents) and from oceanic sediment cores (Steiner and Wallick 1992). The prime motivation for writing this paper is to suggest a process for the evolution of its major planated surfaces and associated climate changes as a consequence of palaeode- glaciation revealed by the occurrence of glaciofluvial deposits.In this effort, information regarding size and dimensions of erratic boulders was gathered from detailed investigations during the period from November 2011 to March 2012 and September 2012 from in many localities within Colombo, Kurunegala,Trincomalee, Batticaloa and Ampara Districts. 3. Results and Discussion The cyclic sedimentary sequences located in low latitudes in continental areas are interpreted as results of frequent changes in global sea levels associated with palaeo glacial cycles. Glacial cycles and variations in sea level are documented in oxygen-isotope and pCO2 variations (Horton et al. 2012). Due to such changes much of the Southern Hemisphere was covered by ice as glaciers pushed northward by Upper Permian time (298.9-279.3 Ma). Coal was produced in both Equatorial rainforests and in temperate forests during the warmer "Interglacial" periods (Table 1). Likewise, the equatorial rainforest disappeared as deserts spread across Central Pangaea during the Middle and Upper Permian periods. Although the southern ice sheets were gone, an ice cap covered the North Pole. Likewise, rainforests covered South China as it crossed the Equator. Sea levels in the Permian Period remained generally low, and near-shore environments were limited by the collection of almost all major landmasses into a single continent called Pangaea (ICS 2009). Table 1: Showing the climate changes and other significant events in relation to glacial periods. The symbol • denotes events in Sri Lanka. Era Period Epoch Major events in Sri Lanka (SL) are in Italics Start (Ma BP) Quaternary Holocene The last glacial period ends; The salient feature is rise of human civilization. Quaternary Ice Age recedes, and the current interglacial begins. The period of cold climatic conditions and drought, which name as Younger Dryasoccurred between approximately 12,800 and 11,500 years BP. Sahara forms from savannah, and agriculture begins, allowing humans to build cities. • Post-glacial sea level rise, drowning of continental shelf, sea level was at least 1.5m or more above from present level. Unconsolidated sandy beaches and dune deposits, beach rock, lagoon and estuarine clays, alluvium, buried and emerged coral reefs were formed (Katupotha 1988a; 1988b; 1988c and 1995). • Streams fed deposits and other fluvial deposits flowed from Central Highland to coastal zone (to Second Planated Surface). • The First Planated Surface submerged by sea water, and now exists submerged. (This surface is designated asSubmerged Plateau by Sommerville, 1907 and submerged Peneplain by Deraniyagala, 1958. 0.0114 Pleistocene Little Ice Age (stadial) causes brief cooling in Northern Hemisphere from 1400 to 1850 ADE. Atmospheric CO2 levels start creeping from 100 parts per million volume (ppmv) at the end of the last glaciation to the current level of 385 ppmv, causing some sources, global warming and climate change, possibly from anthropogenic sources. 0.0117- 0.126 (Upper) Katupotha /Journal of Tropical Forestry and Environment Vol. 3, No. 01 (2013) 45-57 45 Flourishing and then extinction of many large mammals (Pleistocene mega-fauna). Evolution of anatomically modern humans. • Stranding evidence of sea level fluctuations, sand dunes, gravel deposits, formation of Red Beds, laterite, nodular ironstone (Katupotha 1995; Cooray 1984). • Erratic pebbles, stream fed deposits and other terrestrial deposits flowed from Central Highland to coastal zone (to Second Planated Surface). • SL assuming present position between 5º 52´N-9º 55´N and 79º 30´E-81º 55´E. 0.781 (Middle) 1.806 - 2.588 (Lower) Neogene Pliocene Intensification of present Icehouse conditions, present (Quaternary) ice age begins roughly 2.58 Ma; cool and dry climate. Australopithecines, many of the existing genera of mammals, and recent mollusks appear. Homo habilis appears. • Marine colloidal sedimentation in northwestern SL. 3.600- 5.332 Miocene Moderate Icehouse climate, punctuated by ice ages; Orogeny in northern hemisphere. Widespread forests slowly draw in massive amounts of CO2, gradually lowering the level of atmospheric CO2 from 650 ppmv down to around 100 ppmv . . • The Puttalam-Jaffna limestone in the northwest and Minihagalkanda beds in the southeast were deposited. By the Tortonian Stage(11.62-7.246 Ma) of the Miocene period, Sri Lanka had located itself at 4 º N - 8 º N and 77 º E - 79 º E. • By Mid Miocene (15.97-13.82 Ma), Sri Lanka was positioned between 0.30 º N - 4 º .30’S and 73 º E - 76 º E. Erratic boulders, erratic pebbles and stream fed deposits deposited at random on Second and Third Planated Surfaces. 23.03 - 7.246 Paleogene Oligocene Warm but cooling climate appeared on the Earth, moving towards Icehouse; rapid evolution and diversification of fauna, especially mammals. Major evolution and dispersal of modern types of flowering plants (ICS 2009). • By Oligocene Period, Central Highland was covered by an ice cap, glaciers on Second and Third planated surfaceswere melting. 33.9 - 28.1 Eocene Moderate, cooling climate. Re-glaciation of Antarctica and formation of its ice cap; and the Icehouse Earth climate that would follow it to this day. Lowering of atmospheric carbon dioxide from 3800 ppmv down to 650 ppmv (ICS 2009). • 37.2 Ma, SL resided as an island within 9 o -13 o S and 66 o – 69 o E. Himalayan Orogeny began between 52 and 48 Ma. • At that time SL was between 18 o -24 o S and 63 – 66 o E. • Possibility of the Fourth Planated Surface (Central Highlands) being covered by glaciers. 56.0-38.0 Paleocene Alpine Orogeny in Europe and Asia begins. Indian Subcontinent collides with Asia 55 Ma, Himalayan Orogeny starts between 52 and 65.5 - 58.7 Katupotha /Journal of Tropical Forestry and Environment Vol. 3, No. 01 (2013) 42-54 46 48 Ma (ICS, 2009). • SL positioned between 31 o S-34 o S and 55 o E-58 o E Mesozoic Cretaceous Break up of Gondwana. Beginning of Laramide and Sevier Orogenies of the Rocky Mountains. Atmospheric CO2 close to present-day levels. • Between 100.5 Ma and 72.1 Ma (Upper Cretaceous) SL moved further north and east (45 º S-50 º S and 53 º E-56 º E) rotating northerly. • Around 125.0-113.0 Ma SL was located within 45 º S - 50 º S and 53 º E-56 º E. Between 136 Ma and 130 Ma in Early Cretaceous, SL rotated anticlockwise from ENE-WSW to NE-SW; SL located around 64 o S=66 o S to 33 o E-38 o E.At some stage during the Cretaceous period (145.0=70.6 Ma) more than 850m thick sandstones were deposited in the Mannar Basin. • Evolution of “Post-Gondwana” highland landscapes (King 1962). 100.5 - 72.1 145.5 - 113.0 Jurassic Upper Breakup of Pangaea into Gondwana and Laurasia. Nevadan Orogeny in North America. Rantigata and Cimmerian Orogenies taper off. Atmospheric CO2 levels 4-5 times the present day levels (1200-1500 ppmv, compared to today's 385 ppmv). • SL detached from the southern supercontinentGondwanaland. The Indian Ocean began to open up. India and Sri Lanka’s landmass separated from the Australia and Antarctica/Australia plate. • During the Upper Jurassic Period SL was positioned within 65 o S- 67 o S and 32 o E-36 o E. Tabbowa Beds (generally (arkoses) and Andigama-Pallama Beds (arkoses and carbonaceous shales with thin coal slivers) were formed locally onshore within fault- bounded basins. • SL emerged as a separate landmass. 163.5 - 152.1 Middle 174.3- 161.1 Lower 201.3- 182.7 Triassic Upper Landmasses unite into supercontinent Pangaea, creating the Appalachians. End of Permo-Carboniferous glaciation. Permian-Triassic extinction event occur 251 Ma: 95% of life on Earth becomes extinct, including all trilobites, graptolites, and blastoids. Climate was generally hot and dry. Formed typical red bed sandstones and evaporites. Large size of Pangaea limited the moderating effect of the global ocean. The Permian–Triassic extinction event (Great Dying) occurred 251.4 Ma ago (ICS, 2009). 235.0 - 208.5 Middle 247.2 - 242.0 Lower 252.0 - 251.2 Paleozoic Permian Sea levels in the Permian remained generally low, and near-shore environments were limited by the collection of almost all major landmasses into a single continent - Pangaea (ICS 2009). 254.2 - 299.0 Carbonifer- ous/Pennsy- lvanian Uralian Orogeny in Europe and Asia. Variscan Orogeny occurs towards middle and late Mississippian Periods. 323.2- 303.7 Carbonife- rous/Missi- ssippian Coal-forming coastal swamps. Glaciation in East Gondwana. Tuhua Orogeny in New Zealand tapers off. 358.9 330.9 Devonian "Old Red Continent" of Euramerica. Beginning of Acadian Orogeny for Anti-Atlas Mountains of North Africa, and Appalachian Mountains of North America, also the Antler, Variscan, and Tuhua Orogeny in New Zealand. 419.2 - 372.2 Katupotha /Journal of Tropical Forestry and Environment Vol. 3, No. 01 (2013) 45-57 47 Siluian Beginning of Caledonian Orogeny for hills in England, Ireland, Wales, Scotland, and the Scandinavian Mountains. Also continued into Devonian period as the Acadian Orogeny, above. Taconic Orogeny tapers off. Lachlan Orogeny on Australian Continent tapers off. 443.4 - 423.0 Ordovician Gondwana emerges. Petermann Orogeny on the Australian Continent tapers off (550-535 Ma). Ross Orogeny in Antarctica. Atmospheric CO2 content roughly 20-35 times present-day (Holocene) levels (6000 ppmv compared to today's 385 ppmv) and Ice age at end of period (ICS, 2009). • From Ordovician (488.3-445.6Ma) to Permian (299.0 - 253.8 Ma) there were breaking up signs of Gondwanaland, including between Sri Lanka and India. • Present Mannar Basin developed as a deep canyon (about 4 km deep) on the Precambrian basement. 485.4 - 445.2 Cambrian 542 – 496 Ma, the Gondwanaland emerges. Most continental land masses were clustered in the southern hemisphere (ICS 2009). • SL remained joined with the landmass composed of Africa, Madagascar" India and Antarctica. Joining East Gondwanaland to West Gondwanaland (ICS 2009). 541.0 – 489.5 Source: See References Cooray 1984; ICS 2009 (Retrieved 2009-09-25); Katupotha 1988a, 1988b, 1988c and 1995; King 1962; Sommerville, 1907 and Deraniyagala, 1958. In Sri Lanka, nearly 90% of its rock types are composed of crystalline Precambrian metamorphic rocks. They are subdivided as Highland Complex, Wanni Complex and Vijayan Complex and other small divisions (Cooray, 1984, 1994; Hölzlet al. 1991, Kröneret al. 1991). Meta-igneous rocks (charnockites, hornblende-biotite gneiss, migmatitic and quartzofeldspathic rocks) and metasedimentary rocks (quartzites, marble/dolomite and garnet-sillimanite-graphite schist) are major rock types of the Highland Complex. The Vijayan Complex lies east of the Highland Complex. It is composed of metamorphosed granitoids, charnockitic gneisses, migmatites, microcline-bearing quartzofeldspathic rocks, amphibolite and/or biotite gneiss. The Wanni Complex located west of the Highland Complex is composed of rock types more or less similar to those of the Vijayan Complex. In addition, a small unit named “Kadugannawa Complex” composed of amphibolite or hornblende-biotite gneisses and migmatitesis located in the central part of the country. The other remaining rocks (~10%) consist of Jurassic sandstones, shales and mudstones, some exposed in faulted basins at Tabbowa and Andigama, and Miocene limestone lying unconformably on the Precambrian basement of the North, Northwestern and Southeastern coastal belts (Cooray, 1984; Katupotha and Dias, 2001). Geologically, the Jurassic Period is extremely important to Sri Lanka. Prior to Jurassic, at the end of the Paleozoic the Earth's surface was characterized by a relatively simple landmass configuration with three main continents (Gondwanaland, Laurasia and Angaraland) coalescing to form the Pangean supercontinent. The oceanic domain was defined in its major part by Panthalassa and partially by the Tethys. No major geographic rearrangement of continents and oceans has been documented for the Permian-Triassic transition and for the Lower Triassic, except for the northward motion of entire Pangaea (Galfetti, et al, 2007). During the Triassic which extends about 252.2 to 208.5Ma and Global climate was warm during the Upper Triassic. There was no ice at either North or South Poles. Warm Temperate conditions extended towards the poles. The Pangaea Mega-monsoon was in full swing during the Lower and Middle Jurassic (Jinnan and Parrish 1999). The interior of Pangaea was very arid and hot. Deserts covered what is now the Amazon and Congo rainforests. China, surrounded by moisture bearing winds was lush and verdant. During the Katupotha /Journal of Tropical Forestry and Environment Vol. 3, No. 01 (2013) 42-54 48 Upper Jurassic (163.5-152.1 Ma) the global climate began to change due to the break-up of Pangaea. The interior of Pangaea became less dry, and seasonal snow and ice frosted the Polar Regions. By Lower to Middle Jurassic (201.3-166.1Ma), Sri Lanka emerged as a separate landmass positioned within 52 o S-55 o S and 17 o E-22 o E. Sri Lanka reached its present position at 5º 52´N-9º 55´N, 79º 30´E-81º 55´E, by Lower to Middle Pleistocene (1.806-0.781 Ma). During this drifting period from Lower to Middle Jurassic, Sri Lanka was subjected to at least four major upliftments through Jurassic, Miocene, Pliocene and Pleistocene times (Wayland 1919, Deraniyagala 1958, Cooray1984). As an ‘Upliftment’ in geological terms, is a consequence of tectonic activity, this author is of the view that such major upliftments did not occur for the formation of “The face of Sri Lanka” during this geologic period, and proposes a new “Planation Surface Concept” together with minor tectonic activity to reconstruct the morphogenesis of Sri Lanka’s topography based on glacial events during drifting of Sri Lanka from the southern hemisphere to the northern hemisphere. Accordingly, it is possible to identify “Four Major Planated Surfaces” developed in response to climatic and sea level fluctuations, which followed the glaciations and de-glaciations. Such events broke up the existing glaciofluvialsedimentary beds transforming the topography and structure of Sri Lanka. At present, the “First Planated Surface” is now submerged (Figure 1), which has been identified as a ‘submerged plateau’ by Sommerville (1907) and submerged peneplain by ’Deraniyagala (1958). Sedimentary rocks of the Upper Jurassic age in north-west Sri Lanka are preserved in at least three faulted basins within the crystalline Vijayan Complex (Table 1). For example, Tabbowa Beds (generally arkoses) and Andigama-Pallama Beds arkoses and carbonaceous shales with thin coal slivers) were formed locally onshore within fault-bounded basins (Cooray 1984). One of these basins, that on the west of Tabbowa Tank, 12.8 km from Puttalam on the road to Anuradhapura, is exposed at the surface. The shales, which are at Andigama and Pallama, about 21 and 43 km respectively due south of Tabbowa, are completely covered by later deposits. Similar deposits lie almost in a straight line with similar faulted basins near Chennai on the east coast of Peninsular India, nearly 320 km to the north, and it is probable that all these Jurassic sediments were deposited at the same time (Cooray 1984). The sediments were laid down on the margins of Gondwanaland which included parts of what are now known as India, Australia, Antarctica, South America, Africa and Madagascar. By the Upper Jurassic Period Sri Lanka was detached from the southern supercontinent Gondwanaland, and the Indian Ocean began to open up. The landmasses of India and Sri Lanka separated from Australia and the Antarctica/Australia plate.As the climate warmed up the glacial meltwater deposited the coarser material near the terminal end of the glacierand the finer material further away. Such phenomena are salient features of paleoclimate of Sri Lanka. The Lower Cretaceous (145.5-113.0 Ma) was a mild "Ice House" world (ICS, 2009). There was snow and ice during the winter seasons, and cool temperate forests covered the Polar Regions. During the Upper Cretaceous the global climate was warmer than today's climate. No ice existed at the Poles. Dinosaurs migrated between the Warm Temperate and Cool Temperate Zones as the seasons changed. “Post-Gondwana” highland landscapes in Sri Lanka emerged (King 1962). At some stage during the Cretaceous period (145.0-72.1Ma) more than 850m thick sandstones were deposited in the Mannar Basin. Between 145.0 Ma and 113.0 Ma, in Lower Cretaceous, Sri Lanka rotated anticlockwise from ENE-WSW to NE-SW while translocating northwards from 58 o S-60 o S to 13 o E-16 o E. By Upper Cretaceous Sri Lanka moved further north and east to a position within 54 o S-57 o S, 30 o E-35 o E. Due to these changes,namely, anticlockwise rotation and northward movement Sri Lanka’s “Second Planated Surface” (present surface including the coastal plain) was formed by extensive retreating glaciers again (Figure 1).Similarly, the “Third PlanatedSurface” and the “Fourth Rugged Central Highland” of Sri Lanka emerged due to thawing of massive glaciers (Figure 1), which covered Central Highland and Third Planation Surface since Palaeocene to Oligocene Periods. Within these periods, Sri Lanka moved from 31 o S-34 o S and 55 o E-58 o E to 9 o S-13 o S and 66 o E-69 o E passing the Tropic of Capricorn. Katupotha /Journal of Tropical Forestry and Environment Vol. 3, No. 01 (2013) 45-57 49 Figure 1: Diagrammatic section across Sri Lanka from west to east showing the four planated surfaces. I - first (submerged), II– second (Flat terrain to Undulating terrain, Rolling and Hilly Terrains, III - third (Dissected Rolling and Hilly; Steeply Dissected Rolling and Hilly Terrains, and lV - fourth (Mountainous and Rugged Central Highland) With the emergence of Planated Surfaces and Central Highland of Sri Lanka as Third and Fourth Planated Surfaces, important depositional features of glaciofluvial origin including outwash plain, valley terrains, erratic boulders, ice-rafted deposits (eskers and tills), kames and kame terraces and streams fed deposits were formed. The climate during the Miocene was similar to today's climate, but warmer. Well- defined climatic belts stretched from Pole to Equator and continents continued to drift toward their present positions. King (1962) postulated that the extreme planation of plateau in Sri Lanka, survived only on smooth ridges or crests. This would be the “Third Planated Surface” in the country. Antarctica continued to become more isolated and finally developed a permanent ice cap (ICS 2009). By the end of the Oligocene Period Sri Lanka reached 2 o E-7 o S and 73 o E-76 o E and passed the Equator by Mid Miocene (15.97-13.82 Ma) with the position around 0.3 o N-4.30 o N and 73 o E-76 o E (Table 1). As a result of the Pliocene-Quaternary climate changes the earlier glacial sedimentary deposits in Sri Lanka disappeared from the greater part of Sri Lanka and at present such deposits can be identified as patches from several parts of the country.There are no Pleistocene glacial deposits have been reported, because by the Quaternary Period, Sri Lanka had already reached its present position. However, scattered erratic boulders and patches of old ice-rafted deposits from former glacial depositions such as, outwash plains, valley terrains, kames and kame terraces can be identified throughout on first, second and third planated surfaces, although most are worn to shadows. As a glacial deposit, an erratic is a piece of rock that differs from the size and type of rock native to the area in which it rests. Erratics can range in size from pebbles to large boulders such as big rocks (hundreds to thousands of metric tons in weight). Geologists identify erratics by studying the compositions and orientation of surrounding rocks in comparison to the composition and orientation of the erratic itself.Clast petrology(grains of sediment, silt, sand, gravel, etc), provenance and shape data for the Middle Pleistocene glaciofluvial sand and gravel of the Mníšek member have been discussed by Nývlt and Hoare (2011).The results are compared with those for in situ weathered bedrock debris and recent fluvial sediments from the same area. The results of this study would be helpful to investigate glaciofluvial sediments in Sri Lanka. Due to the Pliocene-Quaternary climate changes, the earlier glacial sedimentary deposits in Sri Lanka have disappeared from greater part of Sri Lanka. However, there are no Pleistocene glacial deposits in Sri Lanka, but scattered erratic boulders and patches of ice-rafted deposits can be identified as glacial deposits older than Pleistocene Glaciation. Likewise, outwash plain type landforms can be identified from the “Second and Third Planated Surfaces”, while valley terrains can be identified from the upper part of the “Third Planated Surface” and from the “Rugged Central Highland” area. Erratics are significant because since they are transported by glaciers, they are one of a series of indicators which mark the path of glacier movement. Their lithographic origin can be traced to the parentrock, allowing for confirmation of the ice-sheets flow route. Similarly they can be transported by Katupotha /Journal of Tropical Forestry and Environment Vol. 3, No. 01 (2013) 42-54 50 ice-rafting. Ice-rafted debris or ice-rafted deposits and stream feddeposits were deposited onto the bottom of the water body, for example, onto a river bed or an ocean floor. Erratic boulders at Tennamavadi are located at coordinates 8°58"N and 80°58'E in Sri Lanka’s Northeastern Coastal Zone very close to the present coast. The locality is about15-20m above MSL and 1.5 km southwest of Kokkilai Lagoon mouth, (Figure 1). Colour and mineral composition indicate that the rocks are derived from the Highland Complex rocks. They are mainly quartzite, marbles, garnet-sillimanite-schist and chanockitic gneisses. The erratic boulders at Valaichchenai Lagoon (coordinates 7°56'N, 81°33'E), and Uraniya (Pottuvil) Lagoon (coordinates 6°53'N, 81°50'E) are about 2.0m - 4.0m above MSL (Figure2). The lithology of these boulders being composed of a heterogeneous group of gneisses, migmatites and granites with scattered sedimentary bands confirm the source to be Highland Complex rocks (Cooray 1984). The erratics exhibit rounded, oval and elongated shapes ranging in from pebbles to large boulders hundreds to thousands of metric tons in weight. These appear to have been dropped on rock outcrops or on the ground by melting glaciers moving in a northeasterly direction. Erratic boulders at Kadigawa (coordinates 7°42'N and 80°00'E) and Kadigawa Temple area (coordinates 7°43'N and 80°00’E) in the Kurunegala DistrictNorthwestern Province are located on the Second Planated Surface. The area is 35 - 40m above the present MSL. Erratic boulders at Nakolagane Temple site (coordinates 7°48'N and 80°18'E, Photograph 4) and erratic boulders at Viharagala Temple site (coordinates 7°46'N and 80°28'E, Figure3) in the Kurunegala District, Northwestern Province are located above 120 to 200m MSL. The boulders of the Northwestern Province are derived from the rocks of Highland and Wanni Complexes. The Wanni Complex is composed mainly of quartzites, calc-silicate gneisses, cordierite gneisses, garnet-sillimanite gneisses, garnet-biotite gneisses, quartzofeldspathic gneisses, metagranites (including pink granites), granitoid gneisses, charnockites, meta-diorite, amphibolites, meta-gabbros, migmatites, monzo-diorite and pegmatites. Premarathne and Jayasena (2009) report that the hillocks named Weudakanda and Erapolakanda in the KurunegalaDistrict are covered with residual and colluvial soils. Some of these soils are reddish brown in color. Sub-aerial tropical weathering may have converted the original transported materials to iron-rich brown and reddish brown earth. An alternate statement proposed is “Descending from Weuda towards the western coast in the northwest plain, several intriguing isolated deposits were encountered immediately hinterland of the coastal area.” They are the white sand deposits of Nattandiya and its nearby Figure 1: Showing erratic boulders at Tennamavadi (coordinates 8°58'N, 80°58'E), about 1.5 km southwest of Kokkilai Lagoon mouth, 15 -20m above MSL in Northeast coast. Figure 2: Showing erratic boulders at Uraniya (Pottuvil) Lagoon (coordinates 6°54N, 81°50'E), 3m above MSL, East coast. Katupotha /Journal of Tropical Forestry and Environment Vol. 3, No. 01 (2013) 45-57 51 areas and ferruginized, indurated gravel bearing deposits exposed at Erunwela, Muttibendivila, Pallama, Metiyagane and (in the subsurface of hummocks throughout the lower plains in the northwest (Wayland 1919, Coates 1935, Deraniyagala 1958, Cooray 1963 and 1984). The original transported materials were converted to iron-rich brown and reddish brown earth embedded with well rounded quartz gravel to pebble size are found in a hummocky area at Leekolawewa in the Kurunegala District (Photograph 5). The sizes of the well rounded and oval shaped pebbles and cobbles vary from 2.0 cm to 8.0-10 cm. This author believes that these sediments represent weather-worn outwash plain deposits produced at several stages during the glacial history. Between Kaduwela and Hanwella on the Kelani Ganga (Western Province), for example, a high- level gravel known as the “Malwana formation” is present at 16m above the present river level (28m above MSL); a lower gravel, the Ranale formation, is found at 6.5m above the present river level (23m above MSL; Photograph 6). The Malwana formation contains beds of well rounded, coarse quartz pebbles embedded in a matrix of laterite separated from each other by pebble-free layers of laterite. Remnants of this formation are seen capping the ridge that runs parallel with the river in Ranale and Nawagamuwa villages on the left bank of the Kelani Ganga (river), and at Mapitigama, Weelgama, Thittapattara, and Wiyalananda villages on the right bank of the same river (Cooray 1984). The Ranale gravel forms a terrace about a 1-2 km wide and at a height between 10-25m above MSL. It is about 3-4m thick probably formed as ice-rafted palaeo deposits during the progressive lowering of the river valley at a later stage. Outcrops of these gravels can be seen at several scattered locations along the valley on either side of the Kelani River, some of them being away from its present course. Well rounded and polished quartz pebbles, about 2.0 cm to 8.0 cm in size, embedded in a matrix of laterite separated from each other by a pebble-free layer of laterite is shown. These erratic boulders and ice-rafted deposits can be correlated with the pattern of sedimentation during the Late Paleozoic, Gondwanaland Glacial sediment from the Talchir Formation, Satpura Gondwana basin, central India (Chakraborty and Ghosh, 2008). Figure 3: Erratic boulders at Viharagala Temple site (coordinates 7°46'N, 80°28'E). Figure 4: Erratic boulders at Nakolagane Temple site (coordinates 7°49’N, 80°19’E) both in Kurunegala District. Katupotha /Journal of Tropical Forestry and Environment Vol. 3, No. 01 (2013) 42-54 52 4. Conclusion Climate changes and variations in sea level, which followed the glacial cycles from Huronian glaciation to Karoo glaciation in the Southern hemisphere continued during the northward drift of the landmass. Due to such changes, much of the Southern Hemisphere remained covered by ice as glaciers pushed northward during the Lower Permian time (299.0-279.3 Ma. By Lower Triassic (252.0-251.2) Ma, the interior of Pangea was hot and dry and warm temperate climates extended to the Poles. In due course, the interior of Pangaea became less dry, and seasonal snow and ice frosted the Polar Regions. Sri Lanka emerged as a separate landmass between201.3 and 166.1 Ma (Lower and Middle Jurassic), when the landmass was positioned within 52 o S-55 o S and 17 o E-22 o E. Sri Lanka reached its present positionwithin 5º 52´N-9º 54´N and 79º 30´E-81º 55´E at sometime between Lower and Middle Pleistocene Although many workers proposed that Sri Lanka was subjected to at least four major upliftments during Jurassic, Miocene, Pliocene and Pleistocene times, this author is of the opinion that such major upliftmentsdid not occur during the said geologic periods, and instead introduces the new “Four Major Planation Surface Concept” to interpret the morphogenesis of Sri Lanka leading to its present topography based on major glacial events during drifting of Sri Lanka from the southern to the northern hemisphere. The concept of “Four Major Planation Surfaces” states that pervasive climatic changes and significant sea level fluctuations that occurred since Jurassic, Miocene, Pliocene and Pleistocene times led to the brake up of glaciofluvialsedimentary beds altering the country’s topography and structural configuration. The Pliocene-Quaternary climates changes appear to have obliterated earlier glacial sedimentary deposits from greater part of Sri Lanka. Despite no Pleistocene glacial deposits have been recorded, scattered erratic boulders without proper direction and patches of relict erratic pebbles or stream fed deposits can be identified near the coastal zone (Second Planated Surface). In addition, the Second and Third Planated Surfaces as well as the Rugged Central Highlands of Sri Lanka (Fourth Planated Surface), together with glacial deposits that are older than those of Pleistocene Glaciation provide conclusive evidence for Sri Lanka had endured palaeoclimatic changes and glaciations. Figure 5: A gravel hummock at Leekolawewa (coordinates 7°42'N, 80°02'E), about 40m above MSL, in Northwestern Province. Figure 6: Ranale Gravel Deposit (coordinates 6°55'N, 80° 02'E), 22m above MSL in Western Province (as streams fed deposits) Katupotha /Journal of Tropical Forestry and Environment Vol. 3, No. 01 (2013) 45-57 53 Acknowledgments My profound thanks go to Mr Nimal Ranasinghe, former Director, Geological Survey Department of Sri Lanka and Dr. Risto Hamari, Pahnakalliontie 4 C 14, 48400 Kotka, Finland for their pertinent suggestions and editing of the manuscript. I am deeply grateful to Professor Gamini Adikari, Director General, Central Cultural Fund of Sri Lanka and International Water Management Institute (IWMI) for providing ready assistance for all field visits, and also this study has been completed based on the Research and Development Allowance paid by University (Management Services Circular No: 44 and the Letter of UGC/C/PS/7 - dated 14 March, 2011). References ChakrabortyChandan and GhoshSanjoy Kumar., 2008. 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