Refining our knowledge of the Messinian salinity crisis records in the offshore domain through multi-site seismic analysis

Lofi, Johanna; Sage, Françoise; Déverchère, Jacques; Loncke, Lies; Maillard, Agnès; Gaullier, Virginie; Thinon, Isabelle; Gillet, Hervé; Guennoc, Pol; Gorini, Christian

doi:10.2113/gssgfbull.182.2.163

Cited by 136 publications

(170 citation statements)

References 67 publications

(126 reference statements)

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“…The reason for the 's' layer not being identified in other parts of the Western Mediterranean is probably two-fold: (1) the relatively high resolution of the deep-water seismic survey of the datasets analysed in this study; and (2) the possible dilution of gypsum and salt by clastics in the peripheral areas of the Western Mediterranean, with particular reference to the Gulf of Lion depocentre where most of the available information comes from. Following the MSC evolutionary model of Rouchy & Caruso (2006), Ryan (2008) and Lofi et al (2011b), we infer that the deposition of the 's' layer followed a second, short decrease in the base level. This secondary base level drop is correlatable to the intra-UU erosion (IES), which is well defined on the Sardinian continental slope (see also Geletti et al 2014).…”

Section: Discussionmentioning

confidence: 86%

Seismic imaging of Late Miocene (Messinian) evaporites from Western Mediterranean back-arc basins

Cin

Ben

Mocnik

et al. 2016

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An analysis of multichannel seismic reflection data was conducted focusing on the comparison between the Messinian Salinity Crisis (MSC) and Plio-Quaternary (PQ) evolution of the eastern Sardo-Provençal and northern AlgeroBalearic basins and related margins in the West Mediterranean Sea. Both basins were completely opened during the MSC and their well-defined seismic stratigraphy is very similar in the deep parts. The primary difference between these two basins is due to their different pre-MSC extensional history, including the opening age and the stretching factors. These factors influenced the occurrence of post-MSC salt tectonics on these margins.

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Section: Discussionmentioning

confidence: 86%

Seismic imaging of Late Miocene (Messinian) evaporites from Western Mediterranean back-arc basins

Cin

Ben

Mocnik

et al. 2016

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“…Flecker and Ellam, 2006;Fortuin and Krijgsman, 2003;Krijgsman and Meijer, 2008;Lugli et al, 2010;Meijer, 2012;Topper et al, 2011). In addition, it is difficult to envisage how enough salt could have been brought into the Mediterranean to explain the 1-3 km-thick Messinian evaporite sequence visible in the seismic record (Lofi et al, 2011;Ryan et al, 1973) without inflow from the Atlantic.…”

Section: Gypsum -Clastic Alternationsmentioning

confidence: 99%

Modelling global-scale climate impacts of the late Miocene Messinian Salinity Crisis

et al. 2014

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Abstract. Late Miocene tectonic changes in MediterraneanAtlantic connectivity and climatic changes caused Mediterranean salinity to fluctuate dramatically, including a tenfold increase and near-freshening. Recent proxy-and modelbased evidence suggests that at times during this Messinian Salinity Crisis (MSC, 5.96-5.33 Ma), highly saline and highly fresh Mediterranean water flowed into the North Atlantic Ocean, whilst at others, no Mediterranean Outflow Water (MOW) reached the Atlantic. By running extreme, sensitivity-type experiments with a fully coupled oceanatmosphere general circulation model, we investigate the potential of these various MSC MOW scenarios to impact global-scale climate.The simulations suggest that although the effect remains relatively small, MOW had a greater influence on North Atlantic Ocean circulation and climate than it does today. We also find that depending on the presence, strength and salinity of MOW, the MSC could have been capable of cooling mid-high northern latitudes by a few degrees, with the greatest cooling taking place in the Labrador, Greenland-IcelandNorwegian and Barents seas. With hypersaline MOW, a component of North Atlantic Deep Water formation shifts to the Mediterranean, strengthening the Atlantic Meridional Overturning Circulation (AMOC) south of 35 • N by 1.5-6 Sv. With hyposaline MOW, AMOC completely shuts down, inducing a bipolar climate anomaly with strong cooling in the north (mainly −1 to −3 • C, but up to −8 • C) and weaker warming in the south (up to +0.5 to +2.7 • C).These simulations identify key target regions and climate variables for future proxy reconstructions to provide the best and most robust test cases for (a) assessing Messinian model performance, (b) evaluating Mediterranean-Atlantic connectivity during the MSC and (c) establishing whether or not the MSC could ever have affected global-scale climate.

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“…Seismic profiling has also revealed an erosional unconformity around the higher parts of the Mediterranean, and reworking of evaporite detritus into the lower parts of the basin (e.g. Lofi et al, 2011). Hydrologic (Debenedetti, 1982;Blanc, 2006;Meijer and Krijgsman, 2005) and isostatic (Norman and Chase, 1986;Govers et al, 2009) modeling have helped clarify the response of the basin to changing climate, water supply, and sediment and water loads.…”

Section: Introductionmentioning

confidence: 99%

Evidence for deep-water deposition of abyssal Mediterranean evaporites during the Messinian salinity crisis

Christeleit

Brandon

Zhuang

2015

Earth and Planetary Science Letters

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Keywords:Messinian salinity crisis ACE index TEX 86 Mediterranean sea deep sea drilling project Scientific drilling of the abyssal evaporites beneath the deepest parts of the Mediterranean basin gave rise to the idea that the Mediterranean sea completely evaporated at the end of the Messinian. Herein, we show, using new organic geochemical data, that those evaporites were deposited beneath a deepwater saline basin, not in a subaerial saltpan, as originally proposed. Abundant fossil organic lipids were extracted from evaporites in Mediterranean Deep Sea Drilling Project cores. The archaeal lipid distribution and new analyses, using the ACE salinity proxy and TEX 86 temperature proxy, indicate that surface waters at the time of evaporite deposition had normal marine salinity, ranging from ∼26 to 34 practical salinity units, and temperatures of 25-28 • C. These conditions require a deep-water setting, with a mixed layer with normal marine salinity and an underlying brine layer at gypsum and halite saturation. After correction for isostatic rebound, our results indicate maximum drawdown of ∼2000 m and ∼2900 m relative to modern sea level in the western and eastern Mediterranean basins, respectively. Our results are consistent with previously proposed scenarios for sea level drawdown based on both subaerial and submarine incision and backfilling of the Rhone and Nile rivers, which require Messinian sea level drops of ∼1300 m and ∼200 m, respectively. This study provides new evidence for an old debate and also demonstrates the importance of further scientific drilling and sampling of deeper part of the abyssal Messinian units.

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Refining our knowledge of the Messinian salinity crisis records in the offshore domain through multi-site seismic analysis

Cited by 136 publications

References 67 publications

Seismic imaging of Late Miocene (Messinian) evaporites from Western Mediterranean back-arc basins

Seismic imaging of Late Miocene (Messinian) evaporites from Western Mediterranean back-arc basins

Modelling global-scale climate impacts of the late Miocene Messinian Salinity Crisis

Evidence for deep-water deposition of abyssal Mediterranean evaporites during the Messinian salinity crisis

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