Abstract

AbstractA study of an International Continental Drilling Program core recovered from the middle of the modern Dead Sea has identified microbial traces within this subsurface hypersaline environment. A comparison with an active microbial mat exhibiting similar evaporative processes characterized iron‐sulphur mineralization and exopolymeric substances resulting from microbial activity. Exopolymeric substances were identified in the drilled sediment but unlike other hypersaline environments, it appears that they have a limited effect on the precipitation of calcium carbonate in the sedimentary column. Sulphate reduction, however, plays a role in all types of evaporative facies, leading to the formation of diagenetic iron sulphides in glacial and interglacial intervals. Their synthesis seems to occur under progressive sulphidation that generally stops at greigite because of incomplete sulphate reduction. The latter may be caused by a lack of suitable organic matter in this hypersaline, hence energy‐demanding, environment. Pyrite may be found in periods of high lake productivity, when more labile organic matter is available. The carbon and sulphur cycles are thus influenced by microbial activity in the Dead Sea environment and this influence results in diagenetic transformations in the deep sediment.

Highlights

  • The Dead Sea is one of the most saline lakes in the world

  • Halite mixed with gypsum is analogous to that of interglacial periods, except that it is completely embedded in EPS

  • The Dead Sea is a unique system that can hardly be compared to any other hypersaline systems

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Summary

Introduction

The Dead Sea is one of the most saline lakes in the world It has extremely high levels of divalent cations Ca2+ and Mg2+, making it even harder for life to cope with its chemistry (Nissenbaum, 1975). While few microbes have adapted to such environments, successful colonists include Archaea members of the extreme halophilic class Halobacteria, as well as a few halophilic Bacteria (Bodaker et al, 2010; Rhodes et al, 2012). In such an environment, salinity gradients encourage and support life. The highly labile organic matter produced by the autotrophic eukaryotes would have been immediately degraded by blooms of Halobacteria (Oren, 1983)

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