Deformation within an exposed salt wall

Recumbent folding and extrusion of evaporites in the Dead Sea Basin

G. I. Alsop, R. Weinberger, T. Levi, S. Marco

Research output: Contribution to journalArticle

19 Citations (Scopus)

Abstract

Despite the enormous global interest in salt tectonics, which is largely driven by its importance to hydrocarbon exploration, direct field-based studies of salt exposed at the Earth's surface are rare. However, Mount Sedom, located at the western side of the Dead Sea Basin, presents one such opportunity for detailed analysis of salt and the associated sedimentary and structural record of its movement. The Sedom salt wall is a 10 km × 1.5 km N–S trending ridge comprising a range of Late Miocene-Pliocene evaporites and clastics, which have penetrated the overlying Pleistocene clastic sequence. The salt wall displays a moderate-steep west dipping western margin and an overturned (west-dipping) eastern flank. The sedimentary record of passive wall growth includes sedimentary breccia horizons that locally truncate underlying beds and are interpreted to reflect sediments having been shed off the crest of the growing salt wall. Structurally, the overturned eastern flank is marked by upturn within the overburden, extending for >300 m from the salt wall. Deformation within the evaporites is characterised by ductile folding and boudinage, while a 200 m thick clastic unit within the salt wall forms a tight recumbent fold traceable for 5 km along strike and associated with a 500 m wide inverted limb. This overturned gently-dipping limb is marked by NE-directed folding and thrusting, sedimentary injections, and a remarkable attenuation of the underlying salt from ∼380 m to <20 m over just 200 m of strike length. The inverted limb is overlain by an undeformed anhydrite, gypsum and clastics caprock, thought to be the residue from a now dissolved salt sheet that extruded over the top of the fold. Expulsion of salt down the regional slope towards the NE, combined with subsequent dissolution of evaporites, may have resulted in local ‘pinching shut’ of the salt wall, leading to a distinctive hour-glass map pattern. This area also coincides with deposition of a thicker overlying clastic sequence, indicating continued subsidence of this part of the salt wall. Our detailed fieldwork forms the first direct observation and description of large recumbent folds within salt walls, and permits analysis below the limits of seismic resolution. It thereby allows more rigorous testing of salt tectonic models and mechanisms.
Original languageEnglish
Pages (from-to)95-118
Number of pages24
JournalJournal of Structural Geology
Volume70
Early online date3 Dec 2014
DOIs
Publication statusPublished - Jan 2015

Fingerprint

extrusion
evaporite
folding
salt
basin
salt tectonics
limb
fold
sea
boudinage
hydrocarbon exploration
anhydrite
breccia
overburden
gypsum
fieldwork
Pliocene
subsidence
glass
dissolution

Keywords

  • salt tectonics
  • salt wall
  • salt sheet
  • sedom
  • Dead Sea

Cite this

Deformation within an exposed salt wall : Recumbent folding and extrusion of evaporites in the Dead Sea Basin. / Alsop, G. I.; Weinberger, R.; Levi, T.; Marco, S.

In: Journal of Structural Geology, Vol. 70, 01.2015, p. 95-118.

Research output: Contribution to journalArticle

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note = "Acknowledgements GIA is grateful for funding from the Carnegie Trust for the Universities of Scotland that enabled fieldwork for this project. RW was supported by the Israel Science Foundation (ISF grant No. 1245/11). SM was supported by the Israel Science Foundation (ISF grant No. 1736/11). We thank Ian Davison and Chris Talbot for their careful and constructive reviews of the manuscript.",
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N1 - Acknowledgements GIA is grateful for funding from the Carnegie Trust for the Universities of Scotland that enabled fieldwork for this project. RW was supported by the Israel Science Foundation (ISF grant No. 1245/11). SM was supported by the Israel Science Foundation (ISF grant No. 1736/11). We thank Ian Davison and Chris Talbot for their careful and constructive reviews of the manuscript.

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