Description and age control of sediment core P362/2-33

A detailed description of core P362/2-33 and the age model were published previously in ref. [13]. The upper 70 cm of the 6-m long sediment core consist of brownish to greyish bioturbated sediments, below which faint laminations are observed between 75 and ∼105 cm core depth. Well-preserved millimeter-scale laminations are observed below 140 cm core depth and most probably result from deposition of highly dense, suspension-rich (hyperpycnal) flows formed by particle-laden seasonal Nile flood plumes in the water column [16]. The age model of the sediment core was based on fourteen ¹⁴C ages of fossil planktonic foraminifera shells, measured at the Leibniz-Laboratory for Radiometric Dating and Isotope Research (University of Kiel). Correction of reservoir ages and calibration of the ¹⁴C ages are described in ref. [13]. The core covers most of the Holocene, with the bottom of the core being dated at ∼9000 ¹⁴C yrs BP (9.5 ka BP) and the uppermost sediment sections were deposited prior to 1800AD. Sedimentation rates vary from ∼650 cm/kyr in the lower part of the core to ∼8 cm/kyr in the upper part.

Stable oxygen isotope of foraminifera

Stable oxygen isotopes (δ¹⁸O_C) were measured every 3 cm on the planktonic foraminifera G. ruber (white and >250 µm) at the GEOMAR (n = 176) (S1 Table). The sediment samples were washed and dry-sieved and ∼20 specimens were picked, crushed and gently cleaned with ultrapure (Milli-Q) water. The shells were dissolved in orthophosphoric acid at 70°C in a Kiel II carbonate device and the CO₂ released was analyzed by a Thermo Scientific MAT 252 isotope ratio mass spectrometer (IRMS). The ¹⁸O/¹⁶O ratios are reported in ‰ relative to the Vienna-Pee Dee Belemnite (VPBD) standard, where: δ¹⁸O = [((¹⁸O/¹⁶O)_sample/(¹⁸O/¹⁶O)_VPDB)-1]*1000. Analytical precision of <0.06 ‰ for the δ¹⁸O measurements was determined from repeated analyses of a Solnhofen limestone which is calibrated against NBS19 as internal standard.

Radiogenic neodymium and strontium isotope signature of detrital sediments

The methodology used for extracting neodymium (Nd) and strontium (Sr) signatures from detrital sediments is similar to that described in ref. [13]. However, the set of samples published in ref. [13] (a few grain-size fractions) is very different to the one we present here (bulk sediment measurements for the whole core), which is unpublished. The bulk sediment samples (∼3 g) were first decarbonated (using a buffered acetic acid solution, pH ∼4.5), then leached to remove any authigenic ferro-manganese coatings [17] (using a buffered hydroxylamine hydrochloride solution, pH ∼3.9) and finally ∼0.05 g of the homogenized detrital sediment was totally dissolved (using Aqua Regia, HNO₃ conc. and HF conc.) (S2 Table). The samples were purified and separated using standard ion-chromatography procedures [18], [19]. The Nd and Sr isotope compositions were measured on a Nu Instruments multi-collector inductively-coupled plasma mass spectrometer at GEOMAR. Blank concentrations were negligible for isotopic analyses (<0.3 ng for Nd and <3,4 ng for Sr).

External reproducibility (2σ) was first estimated by repeated measurements of in-house SPC and SPEX standards for Nd and the AA standard for Srranging from ±0.14 to ±0.63 εNd units (±14–63 ppm, n = 57) for Nd and from ±0.000009 to ±0.000048 (±12–68 ppm, n = 58) for Sr. External reproducibility was further assessed by repeated measurements of the JNdi standard for Nd isotopes and the NBS SRM 987 standard for Sr isotopes, and yielded 2σ uncertainties of ±0.3 εNd units (±30 ppm, n = 57) and ±0.00003 (±42 ppm, n = 58) for Sr. The isotope results reported were normalized to the accepted values of the JNdi standard for Nd (¹⁴³Nd/¹⁴⁴Nd = 0.512115) and of the NBS SRM 987 standard for Sr (⁸⁶Sr/⁸⁷Sr = 0.710245). The Nd isotope ratios are reported as εNd: [20].

Alkenones, stable carbon isotopes of n-alkanes and BIT index

The lipids were extracted from 43 sediment samples with a DIONEX Accelerated Solvent Extractor 200 at the NIOZ using a solvent mixture of 9∶1 (v/v) dichloromethane (DCM)/methanol (MeOH). After the addition of internal standards C₂₂ anti-isoalkane (n-alkanes), 10-nonadecanone (alkenones) and C₄₆ glycerol trialkyl glycerol tetraether (GDGTs), the total lipid extract was separated into apolar, ketone and polar fractions using pipette column chromatography loaded with aluminum oxide and the solvent mixtures 9∶1 (v/v) hexane/DCM, 1∶1 hexane/DCM and 1∶1 DCM/MeOH as eluents, respectively. The apolar fraction was then separated into saturated hydrocarbon (long-chain odd n-alkanes and the C₂₂ anti-iso standard) and aromatic fractions using pipette columns loaded with Ag⁺-impregnated silica and hexane and ethylacetate as eluents, respectively.

Molecular identification of the alkenones and n-alkanes was performed on a Thermo Finnigan Trace Gas Chromatograph (GC) Ultra coupled to a Thermo Finnigan DSQ mass spectrometer (MS). The alkenones and the n-alkanes were quantified using HP 6890 GCs with CP Sil-5 columns (50 m for the alkenones and 25 m for the n-alkanes) and helium as the carrier gas. The Uk₃₇′ index [21], defined as C_37∶2/(C_37∶2+C_37∶3), was used to estimate surface seawater temperatures (SSTs) for 39 samples run in duplicate (mean reproducibility of ±0.8°C) (S4 Table and S1b Fig.), following the equation [22], [23]: SST = −0.957+54.293(Uk₃₇′)−52.894(Uk₃₇′)²+28.321(Uk₃₇′)³.

The stable carbon isotope compositions of the long-chain odd n-alkanes were measured for 41 samples (in duplicate or triplicate) on an Agilent 6800 GC coupled to a ThermoFisher Delta V Isotope Ratio MS (S3 Table and S2 Fig.). Isotope values were measured against calibrated external reference gas and the performance was checked daily by injection of two calibrated n-C₂₀ and n-C₂₄ perdeuterated n-alkane standards. The ¹³C/¹²C isotope ratios of n-alkanes are reported in the standard delta notation (δ¹³C) in ‰ against the V-PDB standard: δ¹³C = [((¹³C/¹²C)_sample/(¹³C/¹²C)_VPDB)-1]*1000. The average reproducibility is 0.47‰ for the n-C₂₇ n-alkane, 0.32‰ for n-C₂₉, 0.29‰ for n-C₃₁ and 0.49‰ for n-C₃₃. The average reproducibility of the internal C₂₂ anti-iso standard was 0.9‰ (n = 62) and the reproducibility of an external n-C₂₄ standard was 0.46% (n = 31). A weighted average was calculated using the relative proportion (area under the peak divided by the sum of the areas of n-C₂₇, n-C₂₉, n-C₃₁ and n-C₃₃) and isotope ratio of each n-alkane (S2 Fig.). The estimation of the % fraction of C₄ plants (%C₄) was realized using a two end-members mixing equation [24]: %C₄ = 100-(−7.4627* δ¹³C_wax−160.82). The terrestrial provenance of the n-alkanes was assessed by calculating the carbon preference index (CPI), which is the ratio between odd and even n-alkanes [25]. Long-chain odd n-alkanes originate from terrestrial higher plants with a CPI of >3, whereas long-chain even n-alkanes originate from petroleum sources with a CPI of ∼1. The CPI in core P362/2-33 ranges from 3 to 9 with a mean value of 6.6, which indicates the terrestrial origin of the n-alkanes throughout the record.

The polar fraction of 41 samples (S4 Table), containing the GDGTs, was dissolved in a mixture of 99∶1 (v/v) hexane/propanol and filtered through 0.45 mm PFTE filters. GDGTs were analyzed (in triplicate) by high performance liquid chromatography (HPLC)/MS in single ion monitoring mode on an Agilent 1100 series LC/MSD SL [26], [27]. The Branched and Isoprenoid Tetraether (BIT) index was calculated following [28]: BIT =  (GDGT-I+GDGT-II+GDGT-III)/(GDGT-I+GDGT-II+GDGT-III+Crenarchaeol), whereby the GDGTs refer to structures shown in S3 Fig. The averaged standard deviation for the calculated BIT index is ±0.01.

Results and interpretations

The strength of river runoff is reconstructed from stable oxygen isotope compositions of surface seawater obtained from planktonic foraminifera (δ¹⁸O_SW) (Fig. 2a). The δ¹⁸O_SW record was obtained by correcting the measured δ ⁸O signature of planktonic foraminifera for changes in surface seawater temperature (SST) determined using the U^k′₃₇ paleothermometer (S1 Fig.). The SSTs reconstructed for core P362/2-33 fall in the same range as those previously reconstructed in the Levantine Basin (16 to 26°C) (S1b Fig.) [29], [30]. To estimate the δ¹⁸O_SW, we used the paleotemperature equation established for Orbulina universa [31] and applied a correction for changes in the ice volume [32]. The δ¹⁸O_SW values obtained for Late Holocene sediments are similar to the present-day eastern Mediterranean seawater δ¹⁸O [33] (S1c Fig.) and the values for the Holocene fall in a similar range and follow a trend similar to those previously obtained in the Levantine Basin (∼2 to −1‰) [29]. This demonstrates that the reconstructed δ¹⁸O_SW is not biased by the fact that foraminifera and coccolithophores bloom during different seasons (summer and spring, respectively) and therefore potentially recorded different SSTs (see discussion in ref. [29]). The δ¹⁸O_SW has primarily been related to the changes in surface seawater salinity (SSS) changes, which has been influenced by the precipitation/evaporation balance and by the changes in river runoff (amount effect) [34]. However, as recently shown [35], the δ¹⁸O_SW/SSS relationship may have varied during the Holocene due to changes in the δ¹⁸O of freshwater end-member (i.e., the precipitation and the Nile River water), resulting from changes in the hydrological cycle or in the provenance of the river water. In our case, these various effects cannot be deciphered but they all have the same effect on the δ¹⁸O_SW: a decrease in δ¹⁸O_SW can be interpreted as a decrease in salinity (either due to a higher precipitation/evaporation ratio or increased runoff), and/or as an increase in δ¹⁸O of the freshwater end-member (either due to a more intense convection or a dominant Blue Nile source for the river water [36], which both led to higher runoff). During the early Holocene, δ¹⁸O_SW values around 0‰ were closer to the present-day δ¹⁸O signature of Nile River water (0.8 to −0.6‰, ref. [36]) and might therefore reflect enhanced river runoff leading to lower salinities (S1c Fig.). During the early Holocene, the δ¹⁸O_SW exhibited large amplitude and high frequency variations, which might be related to a large variability of the Nile runoff during the so-called ‘Wild Nile’ period (Fig. 2a). The geomorphological record of this time interval has demonstrated the occurrence of very intense floods with Nile river levels up to 5 m higher than at present [15], [37]. This is also reflected by very high sedimentation rates and the deposition of mm-thick layers of flood-derived sediments in our record (Fig. 2f) [13].

Download:

• PPT
  PowerPoint slide
• PNG
  larger image
• TIFF
  original image

Figure 2. Changes in precipitation, vegetation and erosion dynamics in the Nile watershed during the Holocene.

A: Summer (June-August) insolation at 20°N [59] (dashed line) and oxygen isotope signature of the surface seawater (δ¹⁸O_SW) at the location of our core, which reflects changes in sea-surface salinity and river runoff (S1 Fig.) and has been controlled by orbitally-induced changes in precipitation. B:. Paleo-precipitation records obtained from a speleothem on the Oman Peninsula (δ¹⁸O), rainfall regime of which has been under influence of the Indian monsoon system [10] and obtained from marine sediments off the coast of Somalia (δD of n-alkanes), the rainfall regimes of which has been under the influence of deep-convection in the Indian Ocean [11]. C: Stable carbon isotope composition of higher-plant n-alkanes reflecting the proportion of C₄ (mainly grasses) versus C₃ plants (trees/shrubs). D: BIT index recording changes in the relative contribution of soil organic matter input. E: Radiogenic Sr and Nd isotope signatures of the bulk detrital fraction of the sediments documenting changes in sediment provenance. F: Sedimentation rates. Radiocarbon dates are indicated at the bottom of the panel as red triangles and black rectangles at the bottom of the figure indicate the laminated parts of the core (see “Material and Methods” section and ref. [13]).

https://doi.org/10.1371/journal.pone.0115958.g002

The close similarity in long-term trends between our δ¹⁸O_SW record and the speleothem δ¹⁸O record of paleo-precipitation on the Oman Peninsula suggest that river runoff responded quasi-linearly to changes in rainfall intensity in the Nile watershed (Fig. 2b) [10]. The speleothem record of Quunf Cave on the Oman Peninsula exhibits a gradual decline in precipitation throughout the Holocene that followed the changes in summer insolation, which is also observed in our δ¹⁸O_SW record. This implies that non-linear and threshold mechanisms (such as lake overflow) played a limited role in controlling freshwater discharge. Recently, another paleoprecipitation record was obtained from δD analyses of n-alkanes in marine sediments retrieved off the coast of Somalia/Ethiopia that challenged the prevailing consensus of a gradual wet/dry transition at the end of the AHP in Eastern Africa [11]. Contrary to the speleothem record from the Oman Peninsula and other regional records [2], [9], [10], this δD record exhibits a rapid decrease in rainfall/humdity between ∼6 and 4 ka BP (Fig. 2b). The authors infer that such a rapid termination of the AHP (which was also observed in other records from eastern African lakes [11]) was due to the fact that the hydroclimate regime on the Horn of Africa has mostly been under the influence of deep convection and sea surface temperatures in the western Indian Ocean.

New environmental information on the evolution of vegetation cover, soil dynamics and erosion patterns has been generated from sediment core P362/2-33. Changes in vegetation cover are reconstructed using the stable carbon isotope composition of long-chain odd n-alkanes, which originate from higher plant leaf waxes (δ¹³C_wax) (Fig. 2c). Plants with C₄ and C₃ photosynthetic pathways (essentially corresponding to warm-season grasses/sedges and cool-season grasses/trees/shrubs, respectively) produce leaf waxes with different δ¹³C values that are preserved during transport and sedimentation, and particularly during oxidative diagenesis [38]–[40]. Here we use the weighted average of δ¹³C of four n-alkanes (n-C₂₇, n-C₂₉, n-C₃₁ and n-C₃₃) to estimate changes in the contribution of plants using a C₄ metabolic pathway to the n-alkane pool (%C₄) in the drainage basin (Fig. 2c). Due to their CO₂-concentrating mechanism, C₄ plants (such as warm-season grasses and sedges) are generally isotopically enriched in ¹³C compared to C₃ plants, which include most trees, cool-season grasses, and sedges [40]. The δ¹³C records measured on each n-alkanes have similar long-term trends, with higher values (reaching −21‰ for n-C₃₃) between 9.5 and 8 ka BP and lower values (down to −30‰ for n-C₃₁) between 6 and 0 ka BP (S2 Fig.). The estimation of the % fraction of C₄ plants (% C₄) was realized using the 2 end-members mixing equation from ref. [24] and the terrestrial provenance of the n-alkanes was assessed by calculating the Carbon Preference Index (see “Material and Methods”). The n-alkanes can be transported by wind or rivers but it is assumed here that they have been mainly transported to the core site by the Nile River because the concentration and accumulation rates of n-alkanes show a long-term trend similar to that of the branched GDGTs, which are transported only by rivers (S3a,b Fig.) [28]. Furthermore, Blanchet et al. [13] have shown that at core site P362/2-33, the terrigenous sedimentation has been largely controlled by fluvial inputs and that eolian inputs were significant only around 3–4 ka BP, when the amount of n-alkanes was low in the sediments (S3a Fig.). The δ¹³C_wax varied by 5‰ in our record, which corresponds to proportional abundances of C₄ plants between ∼80 and 40% (Fig. 2c), although these numbers have to be interpreted with some care due to the widely varying concentrations of n-alkanes in C3 and C4 plants [41]. The prevalence of C₄ grasses during the AHP reflects the northward migration of the African Rain Belt that led to the expansion of C₄-dominated savannah-type vegetation into areas of the Sahara that are not vegetated today (Fig. 1b) [42], [43]. A rapid stepwise decrease in δ¹³C_wax between 8.5 and ∼7.8 ka BP and between 6.5 and 6 ka BP (from −24 to −28‰) documents a drastic reduction in C₄ plant cover, which was a consequence of the retreat of the vegetation in the Sahara during the southward migration of the African Rain Belt at the end of the AHP.

Another prominent feature of our record is the abrupt switch in sediment provenance accompanied by a decrease in soil organic matter input and erosional activity. The amount of soil organic matter input to the sediments was estimated using the Branched and Isoprenoid Tetraethers (BIT) index (Fig. 2d), which is the ratio between the contents in terrigenous branched GDGTs and marine crenarchaeol [28]. Castañeda et al. [30] showed that the BIT index can be strongly influenced by the production of marine crenarchaeol and therefore advised to compare the contents and accumulation rates of branched GDGTs and crenarchaeol to the BIT index. At the site of core P362/2-33, the BIT index has obviously been affected by changes in the soil organic matter content rather than by the changes in crenarchaeol content (S3b,c,d Fig.), which suggests that the changes in the BIT index most likely reflect changes in soil formation and erosion. A marked decrease in soil organic matter input is documented by the BIT index from 0.7 to 0.2–0.3 between ∼9 and 7.3 ka BP (Fig. 2d). This decrease in soil organic matter input is nearly synchronous with a switch in sediment provenance recorded in the radiogenic Nd and Sr isotope signatures (εNd and ⁸⁷Sr/⁸⁶Sr) of the detrital sediment fraction (Fig. 2e). As shown on Fig. 1a, the sources of the Nile River are characterized by specific εNd and ⁸⁷Sr/⁸⁶Sr signatures depending on their lithology [44]. At 8.7 ka BP, the εNd and ⁸⁷Sr/⁸⁶Sr of the detrital sediment fraction recorded an abrupt shift from more basaltic (εNd ∼−3 and ⁸⁷Sr/⁸⁶Sr ∼0.707) to more granitic (εNd ∼−4 and ⁸⁷Sr/⁸⁶Sr ∼0.71) signatures. This documents a decrease in the proportion of sediments originating from the Blue Nile (Ethiopian Highlands) and an increased supply of sediments from the White Nile/Sahara regions (Fig. 2e). This enhanced contribution from the White Nile/Sahara regions was already reported in core P362-2/33 based on the grain-size distribution of the terrigenous fraction (i.e., changes in the proportion of grain-size end-members) [13]. This switch in sediment provenance was accompanied by a drop in sedimentation rate from 6 mm/yr to less than 2 mm/yr between 9 and 8.7 ka BP (Fig. 2f) and implies that the massive erosion of Blue Nile soils due to intense flooding activity decreased abruptly at 8.7 ka BP and thus preceded the rapid degradation of the green Sahara.