Eastern Mediterranean Sea circulation inferred from the conditions of S1 sapropel deposition

Tachikawa, Kazuyo; Vidal, Ludovic‐Alexandre; Cornuault, Marine; Garcia, Marta; Pothin, A.; Sonzogni, Corinne; Bard, Édouard; Ménot, Guillemette; Revel, Michel

doi:10.5194/cp-11-855-2015

Cited by 44 publications

(54 citation statements)

References 82 publications

(132 reference statements)

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“…Furthermore, the premature oxic conditions in the Aegean Sea, as deduced from previous mostly benthic foraminifera-based studies, have led to the conclusion that sapropel formation terminated earlier than elsewhere, i.e. at 7.1 cal ka BP [Kuhnt et al, 2007;Kotthoff et al, 2008a;Schmiedl et al, 2010;Tachikawa et al, 2015]. From our record it is clear that indeed the resumption of deep-water formation has occurred at ca 7.4 cal ka BP, as inferred from the Mn/Al ratio and the benthic foraminifera record (Fig.…”

Section: Ending Of Sapropel S1mentioning

confidence: 51%

Eastern-Mediterranean ventilation variability during sapropel S1 formation, evaluated at two sites influenced by deep-water formation from Adriatic and Aegean Seas

Filippidi

Triantaphyllou

Lange

2016

Quaternary Science Reviews

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a b s t r a c tPresent-day bottom-water ventilation in the Eastern Mediterranean basin occurs through deep-water convection originating from the two marginal basins, i.e. Adriatic and Aegean Seas. In the paleo record, long periods of enhanced deep-water formation have been alternating with shorter periods of reduced deep-water formation. The latter is related mainly to low-latitude humid climate conditions and the enhanced deposition and preservation of organic-rich sediment units (sapropels). This study focuses on sedimentary archives of the most-recent sapropel S1, retrieved from two sites under the direct influence of the two deep-water formation areas. Restricted oxygen conditions have developed rapidly at the beginning of S1 deposition in the Adriatic site, but bottom-water conditions have not persistently remained anoxic during the full interval of sapropel deposition. In fact, the variability in intensity and persistence of sedimentary redox conditions at the two deep-water formation sites is shown to be related to brief episodes of climate cooling. In the Adriatic site, sapropel deposition appears to have been interrupted twice. The 8.2 ka event, only recovered at the Adria site, is characterized by gradually increasing suboxic to possibly intermittently oxic conditions and decreasing C org fluxes, followed by an abrupt re-establishment of anoxic conditions. Another important event that disrupted sapropel S1 formation, has taken place at ca. 7.4 cal ka BP. The latter event has been recovered at both sites. In the Adriatic site it is followed by a period of sedimentary conditions that gradually change from suboxic to more permanently oxic, as deduced from the Mn/Al pattern. Using the same proxy for suboxic/oxic sedimentary redox conditions, we observe that conditions in the Aegean Sea site shift to more permanently oxic from the 7.4 ka event onwards. However, at both sites the accumulation and preservation of enhanced amounts of organic matter have continued under these suboxic to intermittently oxic sedimentary conditions. It seems thus, that after 7.4 cal ka BP sapropel-like surface or deep-chlorophyllmaximum conditions including enhanced productivity continued, whereas bottom-water conditions were at least intermittently oxic. The latter is related to decreasing precipitation, i.e. run-off, and thus a progressive development and deepening of deep-water formation. The shallower Aegean site, would be affected earlier by such deepening ventilation than the slightly deeper Adriatic site. Finally, termination of sapropel S1 formation as deduced from diminished organic matter contents and Ba/Al, appears to have occurred almost simultaneously in the two areas, namely at 6.6 ± 0.3 and 6.3 ± 0.5 cal ka BP in Adriatic and Aegean sites, respectively.

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Section: Ending Of Sapropel S1mentioning

confidence: 51%

Eastern-Mediterranean ventilation variability during sapropel S1 formation, evaluated at two sites influenced by deep-water formation from Adriatic and Aegean Seas

Filippidi

Triantaphyllou

Lange

2016

Quaternary Science Reviews

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“…It has been previously suggested that processes leading to sapropel formation, that is, humid climate conditions, water column stagnation and/or increased primary productivity, started earlier than the reported age based on sedimentary records (de Lange et al, 2008;Rohling et al, 1993;Tachikawa et al, 2015;van Helmond et al, 2015). Northward migration of ITCZ promoted moisture transfer above the basin as well as enhanced runoff, thus leading to the hampering of deepwater ventilation.…”

Section: Initiation Of Sapropel (S1) Formationmentioning

confidence: 93%

“…Recent studies have indicated that sapropel deposition may not have occurred exclusively under permanently anoxic conditions (Casford et al, 2003;Siani et al, 2013) at least not for shallower depths (Filippidi et al, 2016). The sporadic renewal of the water column at intermediate water depths has been suggested (Casford et al, 2003;Rohling et al, 2015;Tachikawa et al, 2015), which could explain a continuous supply of riverine and oceanic-derived trace metals to these levels (Nijenhuis et al, 1999). In addition, distinct major sapropel interruption events have been reported for 8.2 and 7.4 cal.…”

Section: Variability During S1 Formationmentioning

confidence: 99%

Eastern Mediterranean Deep Water Formation During Sapropel S1: A Reconstruction Using Geochemical Records Along a Bathymetric Transect in the Adriatic Outflow Region

Filippidi

Lange

2019

Paleoceanog and Paleoclimatol

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Eastern Mediterranean thermohaline circulation is directly influenced by middle‐ and low‐latitude climate systems. The dramatic paleoclimate changes during the last African Humid Period (~10–6 ka BP) were captured in Mediterranean sediments as the distinctly organic‐rich unit sapropel S1. Here, deepwater formation variability during S1 deposition is reconstructed. We use geochemical records of three cores along a bathymetric transect (775‐, 1,359‐, and 1,908‐m water depths), at the transition between the Adriatic DW‐ formation area and the Eastern Mediterranean. In all three cores, sedimentation rates are distinctly higher during S1, corresponding with enhanced runoff emanating from the Adriatic hinterland. Hence, major runoff did not only come from southern but also from northern borderlands in this period. During sapropel formation, enhanced levels of primary productivity occurred in the surface waters and oxygen‐depleted conditions in the bottom waters for all sites. Conditions for sediment and bottom‐water below ~1.4 km water depth were sulfidic throughout S1, but for intermediate depth (775 m) were anoxic only during the first part (S1a). Bottom‐water oxygenation interrupted S1 formation at water depths down to ~1.4 km, during two brief episodes, at 8.2 and 7.4 cal. ka BP. From the 7.4 cal. ka BP ventilation onward, the transition to more oxygenated bottom‐water conditions was more progressive for the intermediate water depth site (775 m) than for the deeper sites. Conditions remained fully oxic for all water depths following the S1‐MarkerBed ventilation event. Possibly, the onset of continuously oxic conditions started slightly earlier at intermediate depth (775 m; 6.6 ± 0.3 cal. ka BP) than at greater depths (1,359 m, 1,908 m; 6.0 ± 0.3 cal. ka BP).

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“…In addition, the WIW, flowing between the MAW and the LIW, has also been observed along the Channel (Sammari et al, 1999). The core of the LIW is located at 400-450 m water depth in the Tyrrhenian Sea (Hopkins, 1988;Astraldi et al, 2002b), which is the depth range of CWC samples from the Sardinia Channel (RECORD 23; 414 m) (Taviani et al, 2015). The youngest CWC sample dated at ∼ 0.1 ka BP has an εNd value of −7.70 ± 0.10 (Table 1, Fig.…”

Section: Hydrological Changes In the Sardiniamentioning

confidence: 99%

“…Nineteen fragments were collected at various core depths from a coral-bearing sediment core (RECORD 23;38 • 42.18 N,08 • 54.75 E; Fig. 1) retrieved from 414 m water depth in the "Sardinian cold-water coral province" (Taviani et al, 2015) during the R/V Urania cruise RECORD in 2013. The core contains well-preserved fragments of M. oculata and L. pertusa embedded in a brownish muddy to silty carbonate-rich sediment.…”

Section: Cold-water Coral and Foraminifera Samplesmentioning

confidence: 99%

Hydrological variations of the intermediate water masses of the western Mediterranean Sea during the past 20 ka inferred from neodymium isotopic composition in foraminifera and cold-water corals

et al. 2017

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Abstract. We present the neodymium isotopic composition (εNd) of mixed planktonic foraminifera species from a sediment core collected at 622 m water depth in the Balearic Sea, as well as εNd of scleractinian cold-water corals (CWC; Madrepora oculata, Lophelia pertusa) retrieved between 280 and 442 m water depth in the Alboran Sea and at 414 m depth in the southern Sardinian continental margin. The aim is to constrain hydrological variations at intermediate depths in the western Mediterranean Sea during the last 20 kyr. Planktonic (Globigerina bulloides) and benthic (Cibicidoides pachyderma) foraminifera from the Balearic Sea were also analyzed for stable oxygen (δ 18 O) and carbon (δ 13 C) isotopes. The foraminiferal and coral εNd values from the Balearic and Alboran seas are comparable over the last ∼ 13 kyr, with mean values of −8.94 ± 0.26 (1σ ; n = 24) and −8.91 ± 0.18 (1σ ; n = 25), respectively. Before 13 ka BP, the foraminiferal εNd values are slightly lower (−9.28 ± 0.15) and tend to reflect higher mixing between intermediate and deep waters, which are characterized by more unradiogenic εNd values. The slight εNd increase after 13 ka BP is associated with a decoupling in the benthic foraminiferal δ 13 C composition between intermediate and deeper depths, which started at ∼ 16 ka BP. This suggests an earlier stratification of the water masses and a subsequent reduced contribution of unradiogenic εNd from deep waters. The CWC from the Sardinia Channel show a much larger scatter of εNd values, from −8.66 ± 0.30 to −5.99 ± 0.50, and a lower average (−7.31 ± 0.73; n = 19) compared to the CWC and foraminifera from the Alboran and Balearic seas, indicative of intermediate waters sourced from the Levantine basin. At the time of sapropel S1 deposition (10.2 to 6.4 ka), the εNd values of the Sardinian CWC become more unradiogenic (−8.38 ± 0.47; n = 3 at ∼ 8.7 ka BP), suggesting a significant contribution of intermediate waters originated from the western basin. We propose that western Mediterranean intermediate waters replaced the Levantine Intermediate WaPublished by Copernicus Publications on behalf of the European Geosciences Union. ter (LIW), and thus there was a strong reduction of the LIW during the mid-sapropel (∼ 8.7 ka BP). This observation supports a notable change of Mediterranean circulation pattern centered on sapropel S1 that needs further investigation to be confirmed.

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Eastern Mediterranean Sea circulation inferred from the conditions of S1 sapropel deposition

Cited by 44 publications

References 82 publications

Eastern-Mediterranean ventilation variability during sapropel S1 formation, evaluated at two sites influenced by deep-water formation from Adriatic and Aegean Seas

Eastern-Mediterranean ventilation variability during sapropel S1 formation, evaluated at two sites influenced by deep-water formation from Adriatic and Aegean Seas

Eastern Mediterranean Deep Water Formation During Sapropel S1: A Reconstruction Using Geochemical Records Along a Bathymetric Transect in the Adriatic Outflow Region

Hydrological variations of the intermediate water masses of the western Mediterranean Sea during the past 20 ka inferred from neodymium isotopic composition in foraminifera and cold-water corals

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Eastern Mediterranean Sea circulation inferred from the conditions of S1 sapropel deposition

Cited by 44 publications

References 82 publications

Eastern-Mediterranean ventilation variability during sapropel S1 formation, evaluated at two sites influenced by deep-water formation from Adriatic and Aegean Seas

Eastern-Mediterranean ventilation variability during sapropel S1 formation, evaluated at two sites influenced by deep-water formation from Adriatic and Aegean Seas

Eastern Mediterranean Deep Water Formation During Sapropel S1: A Reconstruction Using Geochemical Records Along a Bathymetric Transect in the Adriatic Outflow Region

Hydrological variations of the intermediate water masses of the western Mediterranean Sea during the past 20 ka inferred from neodymium isotopic composition in foraminifera and cold-water corals

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Hydrological variations of the intermediate water masses of the western Mediterranean Sea during the past 20 ka inferred from neodymium isotopic composition in foraminifera and cold-water corals