Blog List

Friday 8 July 2016

NIAS BASIN

The Nias Basin (also known as the West Sumatra or Sibolga Basin) is a Forearc basin located off the western coast of SumatraIndonesia, in the Indian Ocean. The name is derived from the island that bounds its western edge, the island of Nias. The Nias Basin, the island of Nias (which is a subaerial part of the accretionary complex), and the offshore, submarine accretionary complex, together form a Forearc region on the Sunda Plate/Indo-Australian Platecollisional/subduction boundary. The Forearcregion is the area between an oceanic trenchand its associated volcanic arc. The oceanic trench associated with the Nias Basin is the Sunda Trench, and the associated volcanic arc is the Sunda Arc.


Nias Basin
The Nias Basin itself is structurally bounded to the west by the Mentawai Fault and bounded to the east by the Volcanic Arc island of Sumatra.[1] It is a geologically independent basin from its neighbor basins; the Simeulue Basin to the north, and the Mentawai and Enggano Basin to the south.The Nias Basin spans ~250 kilometer length-wise, and ~100 kilometers width-wise.[2] Overall, the Nias Basin can be divided into two sub-basins; the Singkel Basin to the north, and the Pini Basin to the south. These basins are distinguished by their independent development during the early formation of the primary basin, but later consolidated when subsidence of the area was more unified over the whole Nias Basin region.[2]

Basin Formation

The history of the Nias Basin begins with the initial subduction of the Indo-Australian plateunderneath the Sunda PlateSubduction of this plate, which was rich in water and volatiles, caused flux melting to occur in the mantle. This new magma eventually rose through the overriding plate, and formed the Sunda Arc. The sediment supply, and convergence rate in this case were adequate enough to allow for the Forearc to develop into an Accretionary Convergent Margin. This type of Forearc results in an accretionary complex forming along the Forearc-trench boundary, which resulted in uplift of that region. Uplift due to accretion formed a Forearc Ridge, which the island of Nias is part of. The resulting depression that formed between the Forearc Ridge and the primary volcanic ridge (Sunda Arc), allows for sediment deposition in that region. This depression in this case formed the Nias Basin. Presently, the Nias Basin lies under about 610 meters of water at its deepest point.[1][2]
The Nias Basin can be divided into 2 sub-basins; the Pini Basin to the South, and the Singkel Basin to the North. These basins evolved independently from each other originally during a time of sea-level regression. These sub-basins themselves are bounded by normal faults, which were formed due to depression of the region during sediment subsidence, and extension events.[3]
The Nias Basin itself is relatively shallow compared to its surrounding basins. This could be due to more carbonate reef activity in this region creating thicker carbonate deposits in the Nias Basin, resulting in more sediment deposition, and shallower water depth.[1]

Stratigraphy

The basement rock of the Nias Basin, at its greatest depth lies at about 4-6 kilometers under the seafloor.[4] This basement rock was determined to be the remains of an older accretionary complex that formed before the Indo-Australian/Sunda collision.[1] The stratigraphic sequence of this basin can be divided into 3 primary sequences.

1st sequence - Pre-NeogeneEdit


Stratigraphy of Nias Basin[4]
The lowest and oldest sequence consists of rocks that date to around the late Eocene. These rocks include pyritic shalesdolomitic limestones, and calcareous mudstones.[1] Above these rocks lie various volcanoclastic sandstones and claystonesfrom the early Oligocene.[1]

2nd sequence - Lower Miocene-Upper MioceneEdit

Above the Pre-Neogene sequence lies a major unconformity, overlain by early Miocene rocks.[1]This unconformity is the result of the area being subjected to subaerial erosion, but then was followed by a marine transgression, which deposited the overlaying Miocene rocks. This transgression originally deposited near-shore sands, followed by shallow water siltstones.[1]Towards the middle Miocene, the region developed into a carbonate shelf, and these carbonates make up the rest of this sequence. During the late Miocene, these carbonates were buried by large quantities of clastic sediments originating from the uplift of Sumatraduring this time. These sediments deposited faster than the rate of subsidence in the region, creating a continental shelf and slope in the west of the basin. The newly formed continental slope deposited turbidites over the early-middle Miocene sediment that the shelf did not cover.[1] This Sequence is about 1000 meters thick.[1] After the middle Miocene, there lies an unconformity which represents a ~10 million year depositional hiatus.[4]

3rd sequence - Lower Pliocene-RecentEdit

This sequence, which is also ~1000 meters thick[1] begins with an unconformity which lies at the top of the previous sequence. During this time, clastic sediments continue to be deposited, resulting in the shelf prograding further west, while the deep regions of the basin see continued turbidite deposition.[1]

Stratigraphic interpretationsEdit

Beginning with the 1st sequence, the lithologies are consistent with the formation of the basin along with the volcanic arc, the deposition of the volcanic arc sediments, and ultimate uplift of the basin region, which causes the erosional unconformity. The 2nd sequence stratigraphy displays a marine transgression, and ends with an erosional unconformity. This unconformity could be caused by subaerial erosion due to a regression following the transgression, but it is unknown because that stratigraphy has been eroded. The 3rd sequence shows a marine transgressive event following the previous unconformity, leading into the present day.[1][2][4]

Geologic Structures

The Nias Basin is an asymmetric basin, with the Mentawai Fault bounding its Western edge. The Mentawai Fault is a transform fault that parallels the Sunda Trench, and separates the accretionary complex of the fore-arc, from the fore-arc basin. This fault is the result of the oblique subduction nature of the Indo-Australian Plate. The Mentawai Fault also has a normal fault component to its behavior as well, assisting in the formation of the fore-arc basin, as well as creating more space for sediment deposition and subsidence.[3] The motion of the Mentawai Fault also results in accessory faults within the Nias Basin itself. These faults are also normal/transform in nature, and are the faults that bound the 2 sub-basins within the Nias Basin. These smaller faults form ~30 degrees to the Mentawai Fault, and create graben-like structures.[3]


Cross Section Of Nias Basin[1]

Natural Resources

The forearc basin depositional environment is characterized by a low geo-thermal gradient. This relatively cool environment, along with the shallow nature of the seafloor as well as the depositional beds provide a welcoming setting for the creation of hydrocarbons. The coal beds above the second unconformity would be the source of these hydrocarbons, but this area has only just begun being explored for oil/natural gas.[5]

References

  1. a b c d e f g h i j k l m n Barber, A.J., M.J. Crow, and M.E.M. de Smet, 2005, Tectonic evolution, in A. J. Barber, M. J. Crow and J. S. Milsom, eds., Sumatra: Geology, Resources and Tectonic Evolution: Memoir, v. 31, Geological Society, London, p. 234-259.
  2. a b c d R. G. Matson, G. F. Moore. "Structural Influences on Seismic Stratigraphy of Nias Forearc Basin, West of Central Sumatra: ABSTRACT." AAPG Bulletin.
  3. a b c Izart, A., B.mustafa Kemal, and J.a. Malod. "Seismic Stratigraphy and Subsidence Evolution of the Northwest Sumatra Fore-arc Basin." Marine Geology: 109-24.
  4. a b c d Beaudry, Desiree, and Gregory F. Moore. "Seismic-stratigraphic Framework of the Forearc Basin off Central Sumatra, Sunda Arc." Earth and Planetary Science Letters: 17-28.
  5. ^ Deighton, Mukti, Singh, Travis, Hardwick, Hernon. "NIAS BASIN, NW SUMATRA – NEW INSIGHTS INTO FOREARC STRUCTURE AND HYDROCARBON PROSPECTIVITY FROM LONG-OFFSET 2D SEISMIC DATA". http://tektonesiana.org. External link in |website=(help);

Wikipedia 

KUTAI BASIN

The Kutai sedimentary basin extends from the central highlands of Borneo, across the eastern coast of the island and into the Makassar Strait. With an area of 60,000 km2, and depths up to 15 km, the Kutai is the largest and deepest Tertiary age basin in Indonesia.[1]Plate tectonic evolution in the Indonesian region of SE Asia has produced a diverse array of basins in the Cenozoic.[2] The Kutai is an extensional basin in a general foreland setting. Its geologic evolution begins in the mid Eocene and involves phases of extension and rifting, thermal sag, and isostatic subsidence. Rapid, high volume, sedimentation related to uplift and inversion began in the Early Miocene.[1] The different stages of Kutai basin evolution can be roughly correlated to regional and local tectonic events.[2] It is also likely that regional climate, namely the onset of the equatorial ever wet monsoon in early Miocene, has affected the geologic evolution of Borneo and the Kutai basin through the present day.[3] Basin fill is ongoing in the lower Kutai basin, as the modern Mahakam Riverdelta progrades east across the continental shelf of Borneo.

LocationBorneo

Topography of Borneo. Kutai basin outlined in blue

Plate tectonic setting


The Cenozoic plate tectonics of the Indonesian region have generated a complex assemblage of micro-continental blocks and marginal ocean basins surrounded by extensional margins, subduction zones and major transcurrent faults.[4] The island of Borneo and the Kutai basin are located on the Sunda micro-plate, which is bounded to the north and west by the Eurasian plate, to the south by the Indo-Australian plate and to the west by the Philippine and Pacific oceanic plates. In the Cenozoic, the Indo-Australian plate has been moving north and subducting under Eurasia.[2] The collision of the Indian continent with Eurasia halted subduction and uplifted the Himalayas. In between the continents of India and Australia, the oceanic crust is still subducting under the Sunda plate, forming the Sunda trench and Sunda Arc. Australia and Australian derived micro-plates collided with the Sunda plate and Pacific plate in the Pliocene, creating a complex of subduction zones and island arcs. The Philippine plate has been obliquely subducting the Sunda plate for most of the Cenozoic.

Tectonic plates boundaries detailed-en

Sunda Plate map-fr
The complex interaction of the Sunda, Eurasian, Indo-Australian, Philippine and Pacific plates in the Cenozoic has controlled the evolution of approximately 60 Tertiary sedimentary basins in the Indonesian region. Many of these basins, including the Kutai, have formed in a back arc extensional setting, driven by passive or active subduction rollback. The mid Miocene episode of inversion in the Kutai can be linked to collision of continental fragments from the South China Sea with NW Borneo. The Pliocene inversion episode is contemporaneous with the collision of Australia with the Banda arc, with structural connections provided by strike-slip fault systems through Sulawesi.[2]

Geology of Borneo

The basement rock of Borneo is a complex mosaic of geologic terrains, commonly interpreted as the product of primarily Mesozoic accretion of micro-continental fragments, island arc material, oceanic crustal material and marginal basin fill onto the Paleozoic core of the Schwaner Mountains in the southwest of the island.[5] The Schwaner Mountain area consists of early-mid Cretaceous granitic batholiths intruded into Silurian to Permian age metamorphic units.[6] NW of the Schwaner Mountains is a small area of older continental basement consisting of Permo-Triassic granite and metamorphic rocks. SE of the Schwaner Mountains, volcanic island arc and ophilitic rocks emplaced in the late Cretaceous comprise the Meratus Mountains. The basement terrain of eastern and northern Borneo is interpreted to be Cretaceous subduction melange, mostly covered by tertiary sediment.[5] The basement of Western Borneo is an accreted melange of upper cretaceous to Paleocene age that formed the central Kalimantan Ranges as the result of SW directed subduction beneath the continental core of Borneo.[5][6]



Simplified geologic map of Kalimantan (Borneo) Island


Map of Borneo and surrounding features. Made using GeoMapApp
The Cenozoic evolution of Borneo is predominantly controlled by active regional and local tectonics and climate. In the Paleocene, Borneo was a promontory of SE Asia, partially separated by oceanic crust of the proto-South China Sea.[3] There is geologic evidence that suggests Borneo has rotated counter clock wise about 45° from its orentation at the end of the Oligocene while remaining to straddle the equator. This would indicate most of the Paleogene sediment in North Borneo was sourced from Indochina.[3] In the Mid Eocene formation of the Celebs Sea and Makassar Strait rifted the eastern margin of Borneo while subduction of oceanic crust occurred on the western margin, producing deep basins on both sides. In the late Oligocene to Early Miocene, the central mountain ranges of Borneo began to rise.[3] The equatorial perhumid climate provided intense chemical weathering and erosion of the newly uplifted rock and filled the marginal basins of Borneo with sediment. Neogene sediments are up to 9 km thick in sections of some basins.[6] Reconstruction of the sediment volume indicates that at least 6 km of crust was removed from the interior of Borneo in the Neogene.[3] A period of punctuated compressional events beginning in the mid Miocene affected the continued evolution of these basins, deforming and inverting them. Igneous activity continued throughout the Cenozoic but was particularly more active in the northern region of Borneo in the Neogene.

Basin Margins

The Kutai basin traverses the eastern slope of the island of Borneo down from the central highlands, across the modern coastline to the basin floor of the Makassar Straits. It is bound to the North by the Mangkalihat High and the Central Kalimantan Ranges, to the south by the Paternoster Platform, Adang fault zone and the Schwaner and Meratus mountains. The Muller mountains form the western basin margin. In its present configuraton, the basin can be divided into two parts. The western, or upper Kutai which has been inverted 1500-300' above sea level, and the eastern, or lower Kutai which is still receiving sediment.

Basin formation and evolution

Basin formation was initiated in the middle Eocene as extension related to the opening of the Makassar straits and Celebes Sea rifted the crust of Eastern Borneo.[1] This rifting created a broad system of half grabens that reverse polarity along NNE-SSW and N-S trending normal faultsThermal subsidence in the late Eocene and early Oligocene induced minor reactivation along the existing faults. During the late Oligocene there was a brief renewal of extension and rifting along the northern margin of the basin, while the other basin margins experienced uplift.[6] Inversion of the basin began in the Late Oligocene. Tectonic uplift of Borneo in the earliest Miocene inverted the Upper Kutai basin above sea level. Inversion continued in a punctuated fashion through the Miocene and Pliocene. A compressional regime is implied for the later inversion events with stresses transmitted from regional plate collisions.[4] The high angle normal faults were reactivated as thrust faults, inverting the half-grabens. The locus of inversion shifted east with each event.

Basin Fill

Sedimentation in the Kutai basin has been relatively constant throughout the Tertiary. Syn-rift deposition in the Eocene was focused in small, local depocenters within individual half-grabens.[7] Lithology of the initial graben fill is highly variable due to the wide zone of rifting, and ranges from fully terrestrial in the western basin, to fully marine in the eastern basin. A typical initial graben fill in the Kutai basin is composed of coarse and poorly sorted basement derived material. Syn-rift sedimentation following the initial graben fill is variable across the basin, but several distinct facies tracts have been identified. Non marine, deltaic, shallow marine, deep marine and carbonate platform syn-rift deposits are found in the basin.[7]
Sag phase deposition begins in the upper Eocene to Oligocene.[7] A more regional depocenter developed in response to marine inundation. The eastern basin, already influenced by marine conditions quickly transitioned to a deep marine depositional environment, while the western basin transitioned more slowly. A thick marine shale was deposited across much of the basin, while carbonate sedimentation continued on isolated high areas and basin margins.[7] The sag phase marine shale has been observed to lie directly upon basement, and is a regional "blanket" over the syn-rift lithologies.[7] Large carbonate platforms developed along the basin margins as the result of shallowing marine environments in the early phases of the Late Oligocene tectonic uplift event and a marine regression.[7] As tectonic uplift of central Borneo continued into the lower Miocene, the westernmost portion of the Kutai Basin was inverted above sea level, forming the Upper Kutai Basin.
There was a significant change in the character of sedimentation in the Kutai Basin in the Early Miocene.[3] Large amounts of clastic sediment derived from the rising central mountains, and the now inverted Paleogene poured into the lower Kutai Basin. The proto-Mahakam river began to prograde eastward. Subsequent tectonic inversion events in the middle Miocene and Pliocene continued to shift the deltaic depocenter of the Mahakam river eastward into the Makassar Strait. Compression in the middle Miocene produced a coast parallel anticlinorum into which the Mahakam river incised as the folds were inverted. This incision has prevented any lateral migration of the lowermost Mahakam river, creating a point source deltaic depocenter that has been active since the mid Miocene. Neogenesediments in the vicinity of the modern Mahakam delta are up to 9 kilometres (30,000 ft) thick. The total depth of the Kutai basin at this location could be up to 15 kilometres (49,000 ft).[8]

DEM of the Kutai Basin, East Kalimantan, Indonesia. Made using GeoMapApp.

Structure

The most prominent geologic structure in the Kutai Basin is the Samarinda anticlinorium—Mahakam foldbelt, a series of NNE-SSW trending folds and faults in Miocene deltaic strata that parallel the modern coast line.[9] The tightly folded, asymmetric, and thrust fault bound anticlines range from 2–5 km wide and 20–50 km long and separated by broad, open synclines.[4] Onshore, the anticline crests are commonly eroded and breached, and the amount of erosion and structural complexity increase toward the west. A detached fold belt in the westernmost region of the anticlinorium transitions to thrust cored folds in the central region and simple symmetric/asymmetric structures in the easternmost offshore region. The tectonic origin of the fold belt has been attributed to a number of geodynamic processes.[4] One explanation for the detachment folding is directly related to basement inversion along the rift stage normal faults, producing folding above a detachment surface in an underlying over-pressured shale.[8] Another is the inversion of delta top grabben systems. These syn-depositional faults form in conjunction with delta toe thrust faults due to differential loading. When contraction occurs while delta progradation is active, re-activation along these faults produces detached, uplifted anticlines[4]


Geologic Map of the Mahakam Delta showing thrust faulting, folding of Miocene strata, and the incision of the Mahakam River into the fold belt

Tertiary igneous activity

Three suites of intrusive and volcanic rocks are found in the Kutai Basin, and have been used to constrain the Tertiary stratigraphy . The felsic Nyaan volcanics, dated to 48-50 Ma may be related to the extensional tectonics that initiated basin formation. In some locations, the Nyaan volcanics and equivalents are at the base of the Tertiary sedimentary succession, while at other locations bedded tuffs, agglomerates and reworked pyroclastics are part of the late Eocene succession.[6] The Sintang Intrusive suite are mafic to felsic and have a fine crystalline nature which indicates high level emplacement. K-Ar dates of 41-8 Ma have been obtained from rocks assigned to the Sintang suite. Volcanics interpreted to be the sub-aerial products of the Sintang intrusion are found to be interbedded with Late Oligocene to middle Miocene sediments, suggesting that volcanism occurred before and after the early miocene inversion event.[6] The Metulang suite are mid to high-k calc-alkaline basalts and andesites with K-Ar ages between 2.4-1.7 Ma. They form high level intrusions and lava flows.

References

  1. a b c Cloke, I.R.; Moss, S.J.; Craig, J. (1 February 1999). "Structural controls on the evolution of the Kutai Basin, East Kalimantan". Journal of Asian Earth Sciences 17 (1): 137–156. doi:10.1016/S0743-9547(98)00036-1.
  2. a b c d Daly, M.C.; Cooper, M.A.; Wilson, I.; Smith, D.G.; Hooper, B.G.D. (February 1991). "Cenozoic plate tectonics and basin evolution in Indonesia"Marine and Petroleum Geology 8: 2–20. doi:10.1016/0264-8172(91)90041-x. Retrieved 23 February 2015.
  3. a b c d e f Hall, R.; Nichols, G. (2002). in Jones, S.J.; Frostick, L., eds. "Cenozoic sedimentation and tectonics in Borneo: climatic influences on orogenesis" (PDF)Geological Society, London, Special Publication no. 191: 5–22. Retrieved 4 March 2015.
  4. a b c d e McClay, Ken; Dooley, Tim; Ferguson, Angus; Poblet, Josep (June 2000). "Tectonic evolution of the Sanga Sanga block, Mahakam delta, Kalimantan, Indonesia"AAPG Bulletin 84 (6): 765–786. doi:10.1306/a96733ec-1738-11d7-8645000102c1865d. Retrieved 23 February 2015.
  5. a b c Hamilton, Warren (1979). Tectonics of the Indonesian Region. United States Geologic Survey Professional Paper 1078.
  6. a b c d e f Moss, S.J.; Chambers, J.; Cloke, I.; Satria, D.; Ali, J.R.; Baker, S.; Milsom, J.; Carter, A. 1997; . In: Frasier, A.J.; Matthews, S.J.; Murphy, R.W., eds. "New observations on the sedimentary and tectonic evolution of the Tertiary Kutai Basin, East Kalimantan" (PDF)Petroleum Geology of Southeast Asia. Geological Society Special Publication No. 126: 395–416. Retrieved 25 February 2015.
  7. a b c d e f Moss, S.J.; Chambers, J.L.C. (1 February 1999). "Tertiary facies architecture in the Kutai Basin, Kalimantan, Indonesia". Journal of Asian Earth Sciences 17 (1): 157–181. doi:10.1016/S0743-9547(98)00035-X.
  8. a b Chambers, J L C; Carter, I; Cloke, IR; Craig, J; Moss, SJ; Paterson, DW (2004). "Thin-skinned and Thick-skinned Inversion-Related Thrusting — A Structural Model for the Kutai Basin, Kalimantan, Indonesia" (PDF)AAPG Memoir 82: 614–634. Retrieved 16 November 2015.
  9. ^ Satyana, H.S; Nugroho, D.; Surantoko, I. (1 February 1999). "Tectonic Controls on the hydrocarbon habitats of the Barito, Kutei, and Tarakan basins, Eastern Kalimantan, Indonesia: major dissimilarities in adjoining basins". Journal of Asian Earth Sciences 17 (1): 99–122. doi:10.1016/S0743-9547(98)00059-2.

Wikipedia 

Advantages and Disadvantages of Fasting for Runners

Author BY   ANDREA CESPEDES  Food is fuel, especially for serious runners who need a lot of energy. It may seem counterintuiti...