Characteristics of the Paleozoic slope break system and its control on strati-graphic-lithologic traps: An example from the Tarim Basin, western China

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Abstract

Based on comprehensive analyses of seismic and log data, this study indicates that mainly four widespread angular to minor angular unconformities (Tg8, Tg51, Tg5 and Tg3) were formed during the Paleozoic. Through the interpretation of structural unconformities, calculation of eroded thickness, correction of palaeo-water depth and compaction and compilation of the Early Paleozoic structural maps, the Early Paleozoic slope break belt (geomorphologic unit) of the Tarim Basin is subdivided into uplift area, subaqueous uplift area, rift slope break belt, flexure slope break belt (slope belt), depression area and deep basin area. Palaeogeomorphology of the Cambrian-Early Ordovician was approximately in EW trend within which three tectonic units including the Tabei Palaeo-uplift, the northern Depressional Belt and the southern Palaeo-uplift developed respectively and are grouped into two slope break systems namely as the Tabei Palaeo-uplift and the southern Palaeo-uplift. These tectonic units obviously control the deposition of isolated platform, open platform, restricted platform and deep basin. Influenced by extrusion in the Mid-Late Ordovician, the southern and northern subaqueous uplifts gradually elevated and then were eroded. Resultantly two slope break systems developed, namely as the northern and central Palaeo-uplifts which obviously controlled the deposition of provenance area, isolated platform, mixed continental shelf, slope and basin facies. The intensive extrusion of the Mid-Late Ordovician leads to significant tectonic deformation of the Tarim Basin: large area of uplifting and erosion and development of EW trending anticline and syncline. Deposition of shore, tidal flat, delta, shallow marine clastics and deep marine facies is obviously controlled by the Tabei, the southern and the Tadong Palaeo-uplifts. Slope break systems control development of stratigraphic unconformity and thus truncation and onlap unconformity zones become favorable areas in a palaeo-uplift and at a palaeo-slope belt for forming important unconformity traps; Whereas slope (slope break) belt along a palaeo-uplift margin is a geomorphologic unit where high-energy sedimentary facies widely develops, such as reef, oolitic sandy clastics or bioclastic limestone beach bar facies, thus litho-structural composite hydrocarbon accumulations usually develop when tectonic condition is suitable. In addition, large-scale palaeo-uplifts are the most favourable areas for hydrocarbon accumulation development.

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	Articles by authors
	Hao Liu
	Chang-Song Lin
	Rui-Bo Guo
	Min Zhu
	Yong-Qian Cui

Key words: Early Paleozoic structural unconformity slope break system stratigraphic-lithologic trap Tarim Basin

Received: 17 March 2015

Corresponding Authors: E-mail address: lhcugb@163.com.

Cite this article:

Hao Liu,Chang-Song Lin,Rui-Bo Guo et al. Characteristics of the Paleozoic slope break system and its control on strati-graphic-lithologic traps: An example from the Tarim Basin, western China[J]. Journal of Palaeogeography, 2015, 4(3): 284-304.

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http://www.journalofpalaeogeography.org/EN/10.3724/SP.J.1261.2015.00081 OR http://www.journalofpalaeogeography.org/EN/Y2015/V4/I3/284

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