Journal cover Journal topic
Climate of the Past An interactive open-access journal of the European Geosciences Union
Journal topic
CP | Articles | Volume 15, issue 5
Clim. Past, 15, 1757–1769, 2019
https://doi.org/10.5194/cp-15-1757-2019
© Author(s) 2019. This work is distributed under
the Creative Commons Attribution 4.0 License.
Clim. Past, 15, 1757–1769, 2019
https://doi.org/10.5194/cp-15-1757-2019
© Author(s) 2019. This work is distributed under
the Creative Commons Attribution 4.0 License.

Research article 16 Sep 2019

Research article | 16 Sep 2019

Enhanced Mediterranean water cycle explains increased humidity during MIS 3 in North Africa

Enhanced Mediterranean water cycle explains increased humidity during MIS 3 in North Africa
Mike Rogerson1, Yuri Dublyansky2, Dirk L. Hoffmann3, Marc Luetscher2,4, Paul Töchterle2, and Christoph Spötl2 Mike Rogerson et al.
  • 1School of Environmental Sciences, University of Hull, Cottingham Road, Hull, HU6 7RX, UK
  • 2Institute of Geology, University of Innsbruck, Innrain 52, 6020 Innsbruck, Austria
  • 3Department of Human Evolution, Max Planck Institute for Evolutionary Anthropology, Deutscher Platz 6, 04103, Leipzig, Germany
  • 4Swiss Institute for Speleology and Karst Studies (ISSKA), Rue de la Serre 68, 2300 La Chaux-de-Fonds, Switzerland

Correspondence: Mike Rogerson (m.rogerson@hull.ac.uk)

Abstract
Back to toptop

We report a new fluid inclusion dataset from northeastern Libyan speleothem SC-06-01, which is the largest speleothem fluid inclusion dataset for North Africa to date. The stalagmite was sampled in Susah Cave, a low-altitude coastal site, in Cyrenaica, on the northern slope of the Jebel Al-Akhdar. Speleothem fluid inclusions from the latest Marine Isotope Stage (MIS) 4 and throughout MIS 3 (∼67 to ∼30 kyr BP) confirm the hypothesis that past humid periods in this region reflect westerly rainfall advected through the Atlantic storm track. However, most of this moisture was sourced from the western Mediterranean, with little direct admixture of water evaporated from the Atlantic. Moreover, we identify a second moisture source likely associated with enhanced convective rainfall within the eastern Mediterranean. The relative importance of the western and eastern moisture sources seems to differ between the humid phases recorded in SC-06-01. During humid phases forced by precession, fluid inclusions record compositions consistent with both sources, but the 52.5–50.5 kyr interval forced by obliquity reveals only a western source. This is a key result, showing that although the amount of atmospheric moisture advections changes, the structure of the atmospheric circulation over the Mediterranean does not fundamentally change during orbital cycles. Consequently, an arid belt must have been retained between the Intertropical Convergence Zone and the midlatitude winter storm corridor during MIS 3 pluvials.

1 Introduction
Back to toptop

Atmospheric latent heat is a major component of global and regional climate energy budgets, and changes in its amount and distribution are key aspects of the climate system (Pascale et al., 2011). Equally, in mid- and low-latitude regions, changes in the water cycle have more impact on landscapes and ecosystems than changes in sensible heat (Black et al., 2010). Rainfall in semiarid regions is thus one of the key climate parameters that understanding future impact on human societies depends upon (IPCC, 2014), making constraining of midlatitude hydrology a globally significant research priority. These regions, however, have a particularly sparse record of palaeoclimate due to typically poor preservation of surface sedimentary archives (Swezey, 2001). North Africa is a region that fully exhibits these limitations, and large areas present either no pre-Holocene record or else they present highly discontinuous deposits indicating major reorganisation of the hydroclimate, which are challenging to date (Armitage et al., 2007). North Africa also fully exhibits the progress palaeoclimatologists have made in understanding continental hydrological change from its impact on the marine system; our understanding of past North African hydroclimate is disproportionately drawn from records from the Mediterranean Sea (Rohling et al., 2015) and the eastern central Atlantic (deMenocal et al., 2000; Adkins et al., 2006; Goldsmith et al., 2017).

1.1 Past changes in North African hydroclimate

Marine-based evidence offers a coherent model in which changes in the spatial distribution of insolation alter atmospheric circulation on orbital timescales (104 to 105 years) and force major reorganisations of rainfall in semiarid regions such as the Sahel and southern Saharan regions (Rohling et al., 2015; Goldsmith et al., 2017). This result is at least partially confirmed in climate modelling experiments (Tuenter et al., 2003; Bosmans et al., 2015) and provides a conceptual framework in which fragmentary evidence of hydrological change on the adjacent continent can be understood (Rowan et al., 2000). There is (1) strong geochemical evidence that runoff from the African margin initiated the well-known “sapropel” thermohaline crises of the eastern Mediterranean (Osborne et al., 2008, 2010) and (2) convincing evidence that the southern margin of the Mediterranean was more variable than the northern in terms of the relative magnitude of precipitation changes and the distribution of flora, fauna and hominid populations (Drake et al., 2011). However, we emphasise the fact that this understanding is largely drawn from evidence from outside continental North Africa and that this limits our knowledge about the nature and impact of hydrological changes in this region.

There is strong evidence for a more humid climate throughout the Sahara and Sahel regions during the Early Holocene (Fontes and Gasse, 1991; Gasse and Campo, 1994; Jolly et al., 1998; Prentice and Jolly, 2000; Gasse, 2002; Collins et al., 2017) and in older interglacial periods (Armitage et al., 2007; Drake et al., 2008; Vaks et al., 2013). This evidence has been interpreted to indicate that humid conditions extended from the modern Sahel (∼15 N) to the Mediterranean coast (30–35 N). However, this only partially agrees with model results, which do indicate orbitally forced migration of the monsoon belt but not across such a large spatial scale as suggested by the empirical data. Model experiments indicate that monsoonal rainfall occurring within the Intertropical Convergence Zone (ITCZ) likely extended no further north than ∼23 N (Harrison et al., 2015). This well-recognised lack of agreement between rainfall fields in model experiments for the past and reconstructed hydrographies from the distribution of lakes and vegetation (via pollen) (Peyron et al., 2006) remains a major research problem. While some models also suggest that during times of high Northern Hemisphere insolation, enhanced westerlies advected Atlantic moisture into the basin (Tuenter et al., 2003; Brayshaw et al., 2009; Bosmans et al., 2015), high-resolution regional modelling indicates that this primarily affected the northern Mediterranean margin (Brayshaw et al., 2009). This result is consistent with evidence of enhanced runoff at these times from the southern margin of Europe (Toucanne et al., 2015). On the African coast east of Algeria, the southern limit of enhanced precipitation arising from increased westerly activity within model experiments essentially lies at the coastline (∼32 N) and does not appear to drive terrestrial hydrological changes. Overall, there is therefore a striking mismatch between the apparent humidity of Africa between 23 and 32 N in the empirical record (a zonally oriented belt ∼1000 km in width) and the climate models. This region encompasses southern Tunisia, in which multiple lines of evidence for distinct and widespread periods of increased humidity provide a highly secure basis for enhanced rainfall during Northern Hemisphere insolation maxima (Ballais, 1991; Petit-Maire et al., 1991), the Fezzan basin, in which compelling evidence for multiple lake highstands exists (Drake et al., 2011), and western Egypt, where large tufa deposits attest to higher past groundwater tables (Smith et al., 2004).

An emerging picture of Marine Isotope Stage (MIS) 3 as a humid period within the Mediterranean basin is developing (Langgut et al., 2018), and the current study focusses on this time period. However, MIS 3 is not well expressed in the Sahara region. The Libyan interior is considered to have been arid or even hyperarid throughout the last glacial period (Cancellieri et al., 2016). Recent re-evaluation of palaeolake levels in southwestern Egypt indicates a groundwater-fed system active around 41 ka (Nicoll, 2018), which is similar to dates for springline tufa systems at Kharga Oasis (Smith et al., 2007). We are not aware of continental MIS 3 pollen records from the region, but marine pollen from Tunisia indicates more arid conditions through the last glacial than during the Holocene (Brun, 1991). There is a triple peak in runoff from the Nile recorded in the marine sediment record, with maxima at ∼60, ∼55 and ∼35 ka, indicating higher rainfall within the upper Nile catchment (Revel et al., 2010).

It is unlikely that significant further progress will be made in understanding the palaeoclimate of North Africa without new empirical evidence of regional hydrological changes from which atmospheric dynamics can be delineated.

1.2 The central North African speleothem record

Speleothem palaeoclimatology has high potential for North Africa, but it is only recently becoming established through key records developed for Morocco (Wassenburg et al., 2013, 2016; Ait Brahim et al., 2017). Until recently, the only speleothem record published from central North Africa was a single continuous record from 20 to 6 kyr BP from northern Tunisia (Grotte de la Mine). This record shows a large deglacial transition in both δ13C and δ18O (Genty et al., 2006), with oxygen isotopes indicating a two-step change from a relatively isotopically heavy (−5 ‰) Last Glacial Maximum (20–16 kyr BP), through an intermediate (−6 ‰ to −7 ‰) deglacial period (16–11.5 kyr BP) to a relatively isotopically light Early Holocene. The δ13C record indicates cool periods exhibiting higher carbon isotope values, more clearly delineating the Bølling–Allerød/Younger Dryas oscillation than δ18O. This is assumed to reflect higher soil respiration during warm periods (Genty et al., 2006). A major change in the carbon isotopic composition occurred across the transition from the relatively arid glacial to the more humid Early Holocene and indicates a significant reorganisation of the regional hydroclimate. However, it is difficult to interpret these data in isolation. A recently reported speleothem record (SC-06-01) indicates that conditions in northern Libya during Marine Isotope Stage 3 (MIS 3) were more humid than today and shows isotopic evidence of a teleconnection between temperature in Greenland and rainfall at the southern Mediterranean margin (Hoffmann et al., 2016). The oxygen isotope record indicates that the water dripping into the cave during MIS 3 was isotopically too heavy for the moisture to be sourced from within the monsoon system (Hoffmann et al., 2016). However, beyond ruling out a southern source δ18Occ values alone are not sufficient to determine the origin of atmospheric vapour. Three distinct humid phases within MIS3 are reported from this speleothem: 65–61, 52.5–50.5 and 37.5–33 ka. Phases I and III occur during times of low precession parameter, when summer insolation on the Northern Hemisphere is relatively increased. Phase II represents the first evidence for high obliquity being able to cause a pluvial period in the North African subtropics in the same manner as precession (Hoffmann et al., 2016). In SC06-01, all three growth phases are fractured into multiple short periods of growth and show a marked temporal coherence with Greenland Dansgaard–Oeschger interstadials (Hoffmann et al., 2016). Here, we report fluid inclusion data from this speleothem and discuss how this helps resolve some of the issues discussed above.

1.3 Fluid inclusions

Speleothem fluid inclusions are small volumes of water that were enclosed between or within calcite crystals as they grew, ranging in size from less than 1 µm to hundreds of micrometres (Schwarcz et al., 1976). This water represents quantities of ancient drip water that can be interrogated directly to ascertain the isotopic properties of the oxygen (δ18OFI) and hydrogen (δ2HFI) it comprises. This powerful approach circumvents some of the uncertainty inherent in the interpretation of the stable isotopic values preserved in the calcite comprising the speleothem itself (δ18Occ, δ13Ccc). Fluid inclusion isotopes have been used to demonstrate changes in air temperatures (Wainer et al., 2011; Arienzo et al., 2015; Meckler et al., 2015) and in the origin of the moisture from which precipitation was sourced (McGarry et al., 2004; Van Breukelen et al., 2008). Fluid inclusions from speleothems in Oman have also been used to identify monsoon-sourced precipitation during interglacial phases (Fleitmann et al., 2003), providing a rationale for similar investigation of fluid inclusion isotope behaviour in North Africa.

In the case of fluid inclusions from northeastern Libyan speleothems, the boundary conditions for atmospheric moisture supply are (1) the sea-surface temperature of the Atlantic and Mediterranean, (2) the surface water δ18Osw of the same ocean regions, (3) land surface temperature of Africa and to a lesser extent southern Europe, (4) insolation (especially with respect to ITCZ position), and (5) the zonal pressure gradient across North Africa.

1.4 Modern rainfall system

Modern rainfall in central North Africa is dominated by relatively wet winters and summers with little, if any, precipitation. Convective systems, cyclones, upper-level troughs and static instabilities can all drive rainfall patterns in the Mediterranean basin, and these modes are reviewed in Dayan et al. (2015). Convection essentially reflects the relatively high sea surface temperature (SST) of the Mediterranean during the winter, but rising air masses generally also need significant advection of moisture to drive significant rainfall. Upper-level troughs reflect large-scale circulation (e.g. Red Sea trough), or they reflect lee effects downstream of mountains in the western Mediterranean and promote rainfall in their regions of formation. The dominant cyclogenic centre is in the Gulf of Genoa, and secondary centres are placed in southern Italy, Crete and Cyprus. Cyclonic systems can also penetrate from the Atlantic, where the high SST of the winter Mediterranean tends to sustain and amplify them, in close analogy to convection forcing. The key static instability is the penetration of the tropical air mass into the subtropical Mediterranean, forming a “Saharan cloud band” at middle and upper atmospheric levels. These originate from within the ITCZ. Libya is very sparsely instrumented, so we assume that synoptic processes are similar to the Levant region. Here, most rainfall falls under winter, low pressure conditions, and it is convective (Peleg and Morin, 2012). The responsible low pressure systems can relate to transient, shallow lows north of the area in which rainfall is occurring or less frequently more long-lasting Cyprus lows or Red Sea trough systems (Peleg and Morin, 2012).

2 Material and methods
Back to toptop

SC-06-01 is a 93 cm long stalagmite from Susah Cave (Fig. 1; 3253.419 N, 2152.485 E), which lies on a steep slope ∼200 m above sea level in the Al Akhdar massif in Cyrenaica, Libya (Fig. 1). The region is semiarid today, with a mean annual temperature of ∼20C and receiving less than 200 mm precipitation per year, mostly in the winter (October to April). The Al Akhdar massif has thin soil cover and a Mediterranean “maquis” vegetation. Susah Cave is hydrologically inactive today, and all formations are covered with dust. The chronology of the speleothem and the general features of its growth and δ18Occ record are published elsewhere (Hoffmann et al., 2016), and this study focusses on fluid inclusion isotopes, their impact on the interpretation of δ18Occ and to a lesser extent on δ13Ccc and Sr isotopes.

https://www.clim-past.net/15/1757/2019/cp-15-1757-2019-f01

Figure 1Map showing the location of Susah Cave (filled circle) and GNIP sites (open circles) used in Sect. 4.1. Blue stars indicate sources of marine water evaporation discussed in the text. Grey arrows indicate recent average winter wind direction.

Fluid inclusions were examined in doubly polished, thick section (100 µm) slides, using a Nikon Eclipse E400 POL microscope. The isotope composition of fluid inclusion water was measured at the University of Innsbruck using a Delta V Advantage IRMS coupled to a Thermal Combustion/Elemental Analyser and a ConFlow II interface (Thermo Fisher) using the line, crusher and cryo-focussing cell described in Dublyansky and Spötl (2009). Samples were cut with a diamond band saw along visible petrographic boundaries in the speleothem and, therefore, represent specific growth increments. Samples were analysed at least in duplicate, with the standard sampling protocol used on the Innsbruck instrument (Dublyansky and Spötl, 2009). To exclude the possibility of post-depositional diagenetic alteration, petrographic thin sections were investigated using transmitted light microscopy. Results are detailed in the Supplement.

Optical emission spectroscopy (OES) was used to measure a variety of elemental concentrations, including Sr, along the main growth axis of SC-06-01. The low spatial resolution of trace elemental analyses (every 10 mm) does not allow the investigation of time series of elemental variation but was useful to assess Sr contents of the samples for Sr isotope measurements by thermal ionisation mass spectrometry (TIMS). The samples for TIMS analyses were drilled using a handheld microdrill with a tungsten carbide drill bit. Sample sizes range between 2 and 4 mg; thus we achieved a minimum Sr load of 100 ng on the Re filaments for TIMS. Chemical sample preparation and subsequent TIMS measurement were done following standard protocols (Charlier et al., 2006). No spike was added to the samples prior to chemical purification. The Sr isotope measurements were done on a Triton TIMS housed at the Bristol Isotope Group laboratory, University of Bristol.

3 Results
Back to toptop

3.1 Fluid inclusions

Petrographic analysis of the thick sections indicates that the distribution of fluid inclusions is highly variable, with macroscopically opaque “milky” calcite typical of rapidly growing intervals containing sometimes very abundant inclusions and the discoloured, translucent calcite of the slowly growing intervals being almost inclusion-free (Fig. 2). In most samples, two distinct populations of inclusions were identified with numerous small intra-crystalline inclusions and larger, but less frequent, inter-crystalline inclusions. Consequently, the volume of water analysed per sample was very variable (Fig. 3). Indeed, a significant proportion of individual fluid inclusion measurements had analyte volumes too small (< 0.1 µL) to have confidence in the isotope results. A small number of analyses failed due to excessive water saturating the detector, and these have not been included in the datasets presented here. The major impact of the highly variable availability of inclusions in the speleothem is a significant bias in the analyses towards the most rapidly growing, and therefore probably humid, time periods. Three rapidly growing phases are reported in SC-06-01, named Phase I (62–67 ka), Phase II (53–50 ka) and Phase III (37–33 ka) (Hoffmann et al., 2016). Fluid inclusions for Phases I and III are isotopically similar (with δ18OFI ranging from −7.5 ‰ to −3.8 ‰ and from −8.5 ‰ to −3.2 ‰ respectively and δ2HFI ranging from −26.7 ‰ to −18.6 ‰ and from −29.4 ‰ to −16.1 ‰ respectively). However, compositions for Phase II are different, particularly with respect to deuterium (δ18OFI ranging from −8.9 ‰ to −4.5 ‰ and δ2HFI ranging from −38.3 ‰ to −25.1 ‰).

https://www.clim-past.net/15/1757/2019/cp-15-1757-2019-f02

Figure 2Macroscopic structure of SC-06-01 speleothem, showing alternation of transparent and milky fabrics.

Download

https://www.clim-past.net/15/1757/2019/cp-15-1757-2019-f03

Figure 3Variability of water content (µL) per unit mass of speleothem (g) in SC-06-01 fluid inclusion samples. Grey area shows working range of instrument.

Download

In most samples, achieving within-error replication (δ2H± 1.5 ‰, δ18O: ±0.5 ‰) of both δ18OFI and δ2HFI was difficult. This must reflect more than one population of inclusions with different properties being present within at least some samples, and each replicate analysis represents some proportion of mixing between these populations. This suggests significant short-term variability in the composition of the water stored in the presumably rather small soil–epikarst zone overlying the cave. Consequently, any given time interval risks being under-sampled with regard to variability at that time. Although there is some visual correspondence between the δ18OFI, δ2HFI and δ18Occ data series (Fig. 4), it seems that the fluid inclusion time series risks aliasing changes seen in the calcite isotope time series. Consequently, the usefulness of interpretation that can be drawn from the episodic SC-01-06 fluid inclusion dataset when arranged as a time series is limited, and we therefore largely focus our discussion to the properties of the population of waters as a full dataset. This approach minimises the impact the different populations can have on interpretation.

https://www.clim-past.net/15/1757/2019/cp-15-1757-2019-f04

Figure 4(a) Fluid inclusion oxygen isotope values (δ18OFI; black crosses) compared to calcite oxygen isotope values (δ18Occ; blue circles and line). (b) Fluid inclusion hydrogen isotope values (δ2HFI; black crosses) compared to δ18Occ (blue circles and line). Growth Phases I, II and III are shown as grey areas.

Download

Figure 5 shows the SC-06-01 fluid inclusion dataset alongside Global Network of Isotopes in Precipitation (GNIP) datasets from Tunis World Meteorological Office (WMO station 6071500), Sfax (6075000) and Bet Dagan (4017900) (locations in Fig. 1) and other published precipitation datasets. The Tunisian datasets fit within a trend typical of the global meteoric water line (GMWL) (δ2H=8δ18O+10). However, all these data lie along a single moisture evolution trend, and the Tunis and Sfax populations overlap. The data from Bet Dagan exhibit a trend which is extremely close to being parallel to the global trend dominating in Tunisia, but translated by +10 ‰ in δ2H, reflecting greater deuterium excess. This is typical of the Mediterranean meteoric water line (MMWL) (Ayalon et al., 1998; Gat et al., 2003) and reflects internal recycling of water with consequent deuterium enrichment in the eastern Mediterranean and its bordering continental areas.

https://www.clim-past.net/15/1757/2019/cp-15-1757-2019-f05

Figure 5(a) Regional precipitation isotope data. The thick line represents global meteoric water line, the dashed thick line the Mediterranean meteoric water line and thin lines the expected range of deviation (±10 ‰ δ2Hppt) below GMWL and above MMWL. Bet Dagan, Tunis and Sfax GNIP datasets (http://www-naweb.iaea.org/napc/ih/IHS_resources_gnip.html, last access: 16 August 2016). Sfax Atlantic and Mediterranean rainfall are taken from Celle-Jeanton et al. (2001). (b–d) Summarised precipitation isotopes and fluid inclusion measurements for SC-06-01 for Phases I, II and III respectively.

Download

The values of δ2HFI and δ18OFI fit within the range of values for modern precipitation, giving confidence that these measurements do reflect past precipitation composition despite the influence of multiple inclusion populations. The lack of apparent scatter towards positive δ18O values both in the precipitation and fluid inclusion datasets further indicates that the data represent little-altered precipitation values and that surface re-evaporation was minor at least during humid phases. However, the range of fluid inclusion values is inconsistent with either an exclusively Tunis-type or an exclusively Bet Dagan-type moisture source for precipitation in Cyrenaica during MIS 3. Even when all but the subset of fluid inclusion analyses whose replicates are similar are excluded (Fig. 6), the population is split between the Tunisian and Israeli precipitation endmembers.

https://www.clim-past.net/15/1757/2019/cp-15-1757-2019-f06

Figure 6Double-replicated fluid inclusion measurements from SC-06-01 as well as regional precipitation isotope trends.

Download

3.2 Strontium isotopes

The 87Sr∕86Sr signal in the SC-06-01 record is rather invariable (Fig. 7), with all analyses indicating values within analytical error. Mean values vary between 0.708275 and 0.708524 and although there is an apparent trend from maxima at 34 and 64 kyr BP with a minimum at 52 kyr BP, which mimics the precession history, this is too weak to be significant relative to the error.

https://www.clim-past.net/15/1757/2019/cp-15-1757-2019-f07

Figure 787Sr∕86Sr record for SC-06-01, compared to calcite δ18Occ record (light grey line). Error bars are 2σ. Growth Phases I, II and III are shown as grey areas.

Download

3.3 Calcite carbon isotopes

Both δ13Ccc and δ18Occ show similar trends throughout the record (Fig. 8), indicating that depleted oxygen isotopes coincide with depleted carbon isotope values. This does not appear to arise from fractionation on the speleothem surface (Hoffmann et al., 2016), so it represents changes in soil bioproductivity acting in concert with changes in precipitation.

https://www.clim-past.net/15/1757/2019/cp-15-1757-2019-f08

Figure 8Carbon isotope (δ13Ccc) record for SC-06-01 compared to oxygen isotope record (δ18Occ; Hoffmann et al., 2016). Growth Phases I, II and III are shown as grey areas.

Download

4 Discussion
Back to toptop

4.1 Moisture advection during Libyan humid phases

The range of values of both individual and replicated fluid inclusion measurements can only be reconciled with multiple moisture sources. Most of the fluid inclusion data cluster between the weighted mean value for precipitation collected at Sfax with a mixed source from the Atlantic and western Mediterranean (“Sfax Mixed” δ18Oppt=-4.93 ‰, δ2Hppt=-26 ‰; Fig. 9) and high precipitation events at Bet Dagan (δ18Oppt=-6.33 ‰, δ2Hppt=-21.46 ‰; Fig. 9). However, the fluid inclusion data cluster also extends to the endmember reflecting pure western Mediterranean sources at Sfax (δ18Oppt=-3.99 ‰, δ2Hppt=-20.3 ‰; Fig. 9), indicating a third endmember composition with higher δ18Oppt. The weighted mean value for Atlantic-sourced precipitation events in Sfax (δ18Oppt=-6.7 ‰, δ2Hppt=-37.7 ‰) is distant from any observed fluid inclusion value (Fig. 9). A simple three-endmember unmixing of fluid inclusion isotope values using the quantitative approach of Rogerson et al. (2011) indicates that Atlantic-sourced water supplied no more than 15 % of the mass for any given fluid inclusion analysis. However, the coherence of fluid inclusion isotope ratios with the weighted mean of “mixed” Atlantic and Mediterranean precipitation at Sfax suggests that this small Atlantic influence is nevertheless persistent, and this must reflect synoptic westerly storms (Celle-Jeanton et al., 2001).

https://www.clim-past.net/15/1757/2019/cp-15-1757-2019-f09

Figure 9Fluid inclusion measurements relative to summarised precipitation data and the modern precipitation endmembers used in Sect. 4.1. Solid lines are the meteoric water lines as in Fig. 5a. Precipitation and fluid inclusion measurements are as shown in Fig. 5b. “Mean Atlantic”, “Sfax Mixed”, “Sfax Med” and “High Precip Atlantic” indicate the mean of measurements in Celle-Jeanton et al. (2001) originating from Atlantic moisture, mixed source, Mediterranean moisture and high precipitation measurements from an Atlantic moisture source (as described in Sect. 4.1) respectively. “Mean Bet Dagan” is the mean of GNIP measurements from this location, and “High Precip Bet Dagan” is the subset of high precipitation measurements as described in Sect. 4.1.

Download

The simplest interpretation of the Susah Cave fluid inclusion data is therefore that they reflect a dynamic balance of moisture sources contributing to rainfall in Cyrenaica which resembles modern precipitation in Tunisia and Israel in roughly equal proportions. An alternative way to explain the trend of some points towards enriched δ18O values on the GMWL would be the temperature-dependent fractionation that would be caused by a shift to summertime precipitation. We do not favour this explanation, as it requires a more fundamental reorganisation of regional atmospheric circulation than our suggestion that the winter storms observed today penetrated further east in the past.

Although the isotopic composition of Mediterranean water will have been more enriched during MIS 3 due to ice-volume effects and increased Mediterranean water residence time (Rohling and Bryden, 1994), the similar mean values of the SC-06-01 fluid inclusion waters compared to modern precipitation indicates the meteoric waterline at this time was not displaced to more enriched isotope values. This could reflect balancing of source water effects by changes in kinetic fractionation during evaporation (Goldsmith et al., 2017), which is controlled by normalised relative humidity. This would imply that the Mediterranean air masses were less saturated with moisture than today during MIS 3, which is consistent with the high deuterium excess δ2Hexcess values found in some fluid inclusion samples (Fig. 10), but it is difficult to reconcile with the increased precipitation recorded in SC-06-01. In addition, changes in cloud height and cloud formation processes could possibly alter the isotopic fractionation in the atmosphere. Alternatively, the source water effect may be countered by increased runoff from the margins of the Mediterranean supplying isotopically depleted water to evaporating surface water. Isotopic “residuals” consistent with this argument are identified throughout MIS 3 in the eastern Mediterranean marine core LC21 (Grant et al., 2016), and this is also consistent with higher rainfall in Cyrenaica. We therefore favour the latter explanation.

Although we find that our results likely reflect patterns of atmospheric transport in MIS 3 comparable to today, it is possible that some moisture was drawn from re-evaporation of monsoon rain falling further south, with no modern analogue in the region (Aggarwal et al., 2016). This water would likely be extremely isotopically light, reflecting both monsoon-type compositions and further fractionation during secondary evaporation. Moreover, a shift to more southerly sourced regions is inconsistent with Sr-isotope data from Susah Cave. Sr isotopes are known to be sensitive to changes in transport of Saharan dust (Frumkin and Stein, 2004), but even considering the most slowly growing and most rapidly growing parts of SC-06-01, no significant difference in 87Sr∕86Sr has been identified. Although at times of extreme rainfall in the region, Saharan–Sahelian dust production is suppressed, this is not true during MIS 3 (Collins et al., 2013). It seems that despite changes in the intensity of moisture transport during the period 65–30 kyr BP, there is no large-scale change in atmospheric dust transport direction. This further supports our conclusion from the fluid inclusions that the eastern Mediterranean rainfall operating during precession parameter minima reflects enhanced internal convection rather than transport of moisture from the east or south with an atmospheric circulation pattern that prevails today.

4.2 Different sources at different times?

Phase II fluid inclusions are exceptional, because none show compositions consistent with a Bet Dagan source. This is most clearly reflected in the δ2Hexcess values (Fig. 10), which show consistently low values across Phase II comparing well to the western water endmember (∼10 ‰) and not the eastern water endmember (∼30 ‰). The lack of eastern water during Phase II seems to reflect a fundamental difference between this period and Phases I and III, as during this time all precipitation was drawn from synoptic westerly storms in the winter. Consequently, it would seem that during the obliquity-forced period of humidity, the Israeli-mode precipitation did not occur in the manner that it did during both precession-forced periods of humidity. This difference in the origin of the moisture feeding rainfall may explain the difference in average δ18Occ during these different phases (Hoffmann et al., 2016), and why some periods in Susah Cave show strong correlation with North Atlantic temperature whereas others do not (Hoffmann et al., 2016).

4.3 Palaeoclimatological significance

Most of the precipitation supplied to Cyrenaica during MIS 3 was sourced from within the Mediterranean basin, which exhibited a similar meteoric water cycle to that observed today, albeit with more freshwater influence. This is a critical observation, as the precipitation feeding runoff must be externally sourced if it is to materially change Mediterranean functioning, as is observed during sapropel events (Rohling et al., 2015). The internally cycled water we report from Susah Cave cannot alter the basin-scale hydrological balance, and therefore it is a minor influence on deep convection in the Mediterranean Sea (Bethoux and Gentili, 1999): put simply, this means evidence of increased rainfall in the coastal Mediterranean does not provide evidence for decreased net evaporation in the marine system. This observation is critical, as it decouples the processes of precipitation on the Mediterranean margins with sapropel formation, and consequent changes in buoyancy transfer from the North Atlantic (Rogerson et al., 2012).

Despite the low level of Atlantic moisture contributing to rainfall in Libya in MIS 3, the western-sourced moisture is transported ∼1500 km eastwards to reach Cyrenaica, which must reflect the midlatitude storm track (Brayshaw et al., 2009). Consequently, although it does not seem that Atlantic moisture is important to the climatology of Cyrenaica, the momentum derived from Atlantic winter storms predicted by regional climate modelling (Brayshaw et al., 2009) and observed on the northern Mediterranean margin (Toucanne et al., 2015) remains pivotal to supplying moisture to North Africa. Consequently, the North Atlantic heat budget has provided an important control on North African rainfall in the past. In contrast, this control cannot explain changes in the eastern-sourced rainfall revealed by our analysis. Eastern-sourced rainfall may occasionally relate to wintertime storms, as today (Gat et al., 2003), but essentially reflects convective rainfall with relatively small advection distances. It is likely this arises due to greater atmospheric convergence due to northward displacement of the annual average position of the ITCZ (Tuenter et al., 2003).

Palaeoclimatologically, our analysis reveals that (1) during Northern Hemisphere insolation peaks reflecting precession, coastal Libya experiences greater westerly advection of water due to an increase in Atlantic heat and greater convective rainfall due to migration of the ITCZ, whereas (2) insolation peaks reflecting obliquity show increased Atlantic heat and westerlies but no comparable change in the ITCZ position.

https://www.clim-past.net/15/1757/2019/cp-15-1757-2019-f10

Figure 10Fluid inclusion deuterium excess (δ2Hexcess−FI) relative to calcite δ18Occ. Note some fluid inclusions (70 to 60 kyr BP and 40 to 30 kyr BP) show high (δ2Hexcess−Fi) indicative of an eastern Mediterranean source. Growth Phases I, II and III are shown as grey areas.

Download

4.4 Implications for Susah Cave δ18Occ

Aside from those data with high deuterium excess, which reflect influence from the eastern Mediterranean source, much of the variance in the fluid inclusion dataset is captured by a two-endmember mixing system resembling modern rainfall in Tunisia. One endmember is the western Mediterranean source of Celle-Jeanton et al. (2001), but the other is isotopically too heavy to be identified with the Atlantic source. Rather, it resembles the “Sfax mixed” population defined by Celle-Jeanton et al. (2001), reflecting a mixed source of moisture from both the western Mediterranean and Atlantic. Consequently, although quantitatively minor amounts of Atlantic water reached the site, changes in the moisture advection driven by westerly winds had a strong influence on δ18Odripwater trends in time. At Sfax today, this influence causes a prominent bimodal behaviour with two rainfall maxima with different δ18Oppt, which eliminates a simple and quantitative rainfall amount control on precipitation as observed at Tunis (WMO code 6071500, https://nucleus.iaea.org/wiser/gnip.php, last access: 16 August 2016). Furthermore, addition of heavy rain events derived from the eastern Mediterranean aliases the tendency towards depleted δ18Odripwater, as this water is also more depleted than modern western Mediterranean precipitation. In the Bet Dagan data, there is also a tendency to lower δ18Oppt with higher precipitation amount, but the relationship between rainfall amount and rainfall isotope composition is not identical to Tunis. Ultimately, it seems likely that rainfall amount changes at Susah Cave do cause depleted (enriched) δ18Occ values to be associated with high (low) rainfall, but this is too complicated by independent changes in westerly moisture advection and in convergence. Qualitatively, all these parameters are expected symptoms of North African humid phases and so these trends remain a valuable expression of climatic variability. Quantitatively, more information is required to translate the trends into fully functional palaeoclimatologies, and this analysis pivots on whether δ18Occ trends reflect changes in water deficit/surplus in Cyrenaica.

Although it is likely the oxygen isotope fractionation during calcite precipitation occurred close to isotope equilibrium (Hoffmann et al., 2016), there is a good degree of correspondence between positive and negative phases in δ18Occ and δ13Ccc, indicating a shared control. Indeed, δ13Ccc has a markedly higher amplitude variability than δ18Occ. More isotopically depleted carbon may represent increased incorporation of respired soil carbon, increased dominance of C3 over C4 plants, and/or decreased degassing of aquifer water (Baker et al., 1997). Today, the Susah Cave location on Jebel Malh has very thin soil cover, colonised by shrubby maquis vegetation. Soil respiration and colonisation by C3 plants is limited by the strong water deficit of the region, and aquifer water outgassing is enhanced by long residence times due to low water infiltration. Increased water availability will progressively deplete the δ13C of drip water by all three mechanisms described above. Consequently, all three of these processes promote correlation between δ13Ccc and precipitation amount. Within the δ18Occ data series, peak growth rates occur both during relatively enriched and relatively depleted isotope stages. This is not the case for δ13Ccc, which more consistently shows depleted values during times of rapid growth (SC-06-01 growth phases shown in Fig. 11). We therefore consider it likely that δ13Ccc indeed more accurately records rainfall amount than δ18Occ does.

5 Conclusions and implications
Back to toptop

A key feature of this combined dataset is the long-term sinusoidal trend in both the δ18Occ and δ2HFI, reflecting the differing rainfall regimes dominant between Humid Phases I and III compared to Phase II. This is not developed in δ13Ccc implying that the process forcing the long-term cycle in moisture source is not impacting on carbon dynamics in the soil and epikarst. We therefore conclude that there is a mixed amount and source control on δ18O and δ2H in the SC-01-06 record, whereas δ13C is dominantly controlled by water availability.

The fluid inclusions from SC-06-01 show that rainfall compositions in the southeastern Mediterranean region during MIS 3 were comparable to modern rainfall compositions recorded in regional GNIP datasets. However, the diversity of compositions is impossible to explain with a single rainfall source, rather indicating that moisture derived from the Atlantic, the western Mediterranean and the eastern Mediterranean basins have all contributed to MIS 3 precipitation in Libya. This requires both enhanced westerly advection of moisture to this region, reflecting the Atlantic storm track, and enhanced convective rainfall within the eastern Mediterranean basin. There is some indication that these two mechanisms differ in terms of their response to orbital forcing, with precession parameter minima enhancing westerly advection and internal convection, whereas obliquity minima enhance westerly advection without significantly altering internal convection.

Crucially, this picture is most consistent with atmospheric circulation over the Mediterranean remaining essentially unchanged during precession cycles. This is consistent with regional climate model experiments showing major enhancement of winter westerly storm activity, but it is not consistent with the extreme migration of the ITCZ, where the monsoon belt approaches the North African coast. The strong implication is that a significant arid belt is retained between the Mediterranean and the ITCZ, even when northernmost Africa is experiencing significantly enhanced rainfall.

It is likely that rainfall amount played a role in controlling the isotopic composition of the calcite in this speleothem (δ18Occ). However, the more depleted values reflecting higher rainfall are also consistent with different mixing between the endmembers identified by the fluid inclusion analysis. The structure of the δ13Ccc record provides an independent means of assessing changes in water surplus/deficit, as more depleted values will reflect lower aquifer residence times, enhanced soil respiration and changes in vegetation structure, all of which are limited by water availability in this semiarid environment. Combined analysis of the proxies provides a powerful new demonstration that the northeastern Libyan climate was more humid during millennial-scale warm periods in the North Atlantic realm, but quantification will be dependent on generating unambiguous independent evidence for water availability in the soil and epikarst.

Data availability
Back to toptop
Data availability. 

New data presented in this MS are now available under the following link: https://doi.pangaea.de/10.1594/PANGAEA.904801 (last access: 14 August 2019) (Rogerson et al., 2019).

Supplement
Back to toptop
Supplement. 

The supplement related to this article is available online at: https://doi.org/10.5194/cp-15-1757-2019-supplement.

Competing interests
Back to toptop
Competing interests. 

The authors declare that they have no conflict of interest.

Author contributions
Back to toptop
Author contributions. 

MR, YD and CS designed the study. Fluid inclusion measurements were performed by MR and YD, assisted by ML, and data were reduced by PT. Strontium isotope measurements were performed by DLH, who also provided the chronology of the record. MR analysed the data, with assistance from ML, CS and YD. MR wrote the first draft of the paper, and all authors collaborated to work it into its final form.

Acknowledgements
Back to toptop
Acknowledgements. 

We thank the Royal Geographical Society for the pump-priming investment that began this work (Thesiger-Oman International Fellowship 2009), the Natural Environment Research Council for providing the funds that made the analytical work on this project possible (NE/J014133/1) and The Leverhulme Trust for funding activities within the associated International Network (IN-2012-113). We also thank two anonymous reviewers for considerably improving the quality and accessibility of this paper.

Financial support
Back to toptop
Financial support. 

This research has been supported by the NERC (grant no. NE/J014133/1).

Review statement
Back to toptop
Review statement. 

This paper was edited by Dominik Fleitmann and reviewed by two anonymous referees.

References
Back to toptop

Adkins, J., Demenocal, P., and Eshel, G.: The “African humid period” and the record of marine upwelling from excess 230Th in Ocean Drilling Program Hole 658C, Paleoceanography and Paleoclimatology, 21, PA4203, https://doi.org/10.1029/2005PA001200, 2006. 

Aggarwal, P. K., Romatschke, U., Araguas-Araguas, L., Belachew, D., Longstaffe, F. J., Berg, P., Schumacher, C., and Funk, A.: Proportions of convective and stratiform precipitation revealed in water isotope ratios, Nat. Geosci., 9, 624–629, 2016. 

Ait Brahim, Y., Cheng, H., Sifeddine, A., Wassenburg, J. A., Cruz, F. W., Khodri, M., Sha, L., Pérez-Zanón, N., Beraaouz, E. H., Apaéstegui, J., Guyot, J.-L., Jochum, K. P., and Bouchaou, L.: Speleothem records decadal to multidecadal hydroclimate variations in southwestern Morocco during the last millennium, Earth Planet. Sc. Lett., 476, 10010, https://doi.org/10.1016/j.epsl.2017.07.045, 2017. 

Arienzo, M. M., Swart, P. K., Pourmand, A., Broad, K., Clement, A. C., Murphy, L. N., Vonhof, H. B., and Kakuk, B.: Bahamian speleothem reveals temperature decrease associated with Heinrich stadials, Earth Planet. Sc. Lett., 430, 377–386, 2015. 

Armitage, S. J., Drake, N. A., Stokes, S., El-Hawat, A., Salem, M., White, K., Turner, P., and McLaren, S. J.: Multiple phases of north African humidity recorded in lacustrine sediments from the fazzan basin, Libyan sahara, Quat. Geochronol., 2, 181–186, 2007. 

Ayalon, A., Bar-Matthews, M., and Sass, E.: Rainfall-recharge relationships within a karstic terrain in the Eastern Mediterranean semi-arid region, Israel: δ18O and δD characteristics, J. Hydrol., 207, 18–31, 10.1016/S0022-1694(98)00119-X, 1998. 

Baker, A., Ito, E., Smart, P. L., and McEwan, R. F.: Elevated and variable values of 13C in speleothems in a British cave system, Chem. Geol., 136, 263–270, 1997. 

Ballais, J.-L.: Evolution holocène de la Tunisie saharienne et présaharienne, Méditerranée, 74, 31–38, 1991. 

Bethoux, J. P. and Gentili, B.: Functioning of the Mediterranean Sea: past and present changes related to freshwater input and climate changes, J. Marine Syst., 20, 33–47, 1999. 

Black, E., Brayshaw, D. J., and Rambeau, C. M. C.: Past, present and future precipitation in the Middle East: Insights from models and observations, Philos. T. R. Soc. A, 368, 5173–5184, https://doi.org/10.1098/rsta.2010.0199, 2010. 

Bosmans, J. H. C., Drijfhout, S. S., Tuenter, E., Hilgen, F. J., Lourens, L. J., and Rohling, E. J.: Precession and obliquity forcing of the freshwater budget over the Mediterranean, Quaternary Sci. Rev., 123, 16–30, https://doi.org/10.1016/j.quascirev.2015.06.008, 2015. 

Brayshaw, D. J., Woollings, T., and Vellinga, M.: Tropical and Extratropical Responses of the North Atlantic Atmospheric Circulation to a Sustained Weakening of the MOC, J. Climate, 22, 3146–3155, https://doi.org/10.1175/2008jcli2594.1, 2009. 

Brun, A.: Reflections on the pluvial and arid periods of the Upper Pleistocene and of the Holocene in Tunisia, Palaeoecology of Africa and the surrounding islands, Vol. 22, Proc. symposium on African palynology, Rabat, Morocco, 15–21 May 1989, 157–170, 1991. 

Cancellieri, E., Cremaschi, M., Zerboni, A., and di Lernia, S.: Climate, Environment, and Population Dynamics in Pleistocene Sahara, in: Africa from MIS 6-2, Vertebrate Paleobiology and Paleoanthropology, edited by: Jones, S. C. and Stewart, B. A., Springer, Dordrecht, the Netherlands, 2016. 

Celle-Jeanton, H., Zouari, K., Travi, Y., and Daoud, A.: Caractérisation isotopique des pluies en Tunisie. Essai de typologie dans la région de Sfax, Sciences de la Terre et des planètes, 333, 625–631, 2001. 

Charlier, B., Ginibre, C., Morgan, D., Nowell, G., Pearson, D., Davidson, J., and Ottley, C.: Methods for the microsampling and high-precision analysis of strontium and rubidium isotopes at single crystal scale for petrological and geochronological applications, Chem. Geol., 232, 114–133, 2006. 

Collins, J. A., Govin, A., Mulitza, S., Heslop, D., Zabel, M., Hartmann, J., Röhl, U., and Wefer, G.: Abrupt shifts of the Sahara–Sahel boundary during Heinrich stadials, Clim. Past, 9, 1181–1191, https://doi.org/10.5194/cp-9-1181-2013, 2013. 

Collins, J. A., Prange, M., Caley, T., Gimeno, L., Beckmann, B., Mulitza, S., Skonieczny, C., Roche, D., and Schefuß, E.: Rapid termination of the African humid period triggered by northern high-latitude cooling, Nat. Commun., 8, 1372, https://doi.org/10.1038/s41467-017-01454-y, 2017. 

Dayan, U., Nissen, K., and Ulbrich, U.: Review Article: Atmospheric conditions inducing extreme precipitation over the eastern and western Mediterranean, Nat. Hazards Earth Syst. Sci., 15, 2525–2544, https://doi.org/10.5194/nhess-15-2525-2015, 2015. 

deMenocal, P., Ortiz, J., Guilderson, T., Adkins, J., Sarnthein, M., Baker, L., and Yarusinsky, M.: Abrupt onset and termination of the African Humid Period: rapid climate responses to gradual insolation forcing, Quaternary Sci. Rev., 19, 347–361, 2000. 

Drake, N. A., El-Hawat, A. S., Turner, P., Armitage, S. J., Salem, M. J., White, K. H., and McLaren, S.: Palaeohydrology of the Fazzan Basin and surrounding regions: The last 7 million years, Palaeogeogr. Palaeocl., 263, 131–145, https://doi.org/10.1016/j.palaeo.2008.02.005, 2008. 

Drake, N. A., Blench, R. M., Armitage, S. J., Bristow, C. S., and White, K. H.: Ancient watercourses and biogeography of the Sahara explain the peopling of the desert, P. Natl. Acad. Sci. USA, 108, 458–462, https://doi.org/10.1073/pnas.1012231108, 2011. 

Dublyansky, Y. V. and Spötl, C.: Hydrogen and oxygen isotopes of water from inclusions in minerals: Design of a new crushing system and on-line continous-flow isotope ratio mass spectrometric analysis, Rapid Commun. Mass Sp., 23, 2605–2613, https://doi.org/10.1002/rcm.4155, 2009. 

Fleitmann, D., Burns, S. J., Neff, U., Mangini, A., and Matter, A.: Changing moisture sources over the last 330 000 years in Northern Oman from fluid-inclusion evidence in speleothems, Quaternary Res., 60, 223–232, https://doi.org/10.1016/S0033-5894(03)00086-3, 2003. 

Fontes, J. C. and Gasse, F.: PALHYDAF (Palaeohydrology in Africa) program: objectives, methods, major results, Palaeogeogr. Palaeocl., 84, 191–215, https://doi.org/10.1016/0031-0182(91)90044-R, 1991. 

Frumkin, A. and Stein, M.: The Sahara-East Mediterranean dust and climate connection revealed by strontium and uranium isotopes in a Jerusalem speleothem, Earth Planet. Sc. Lett., 217, 451–464, https://doi.org/10.1016/s0012-821x(03)00589-2, 2004. 

Gasse, F. and Campo, E. V.: Abrupt post-glacial climate events in west Asia and north Africa monsoon domains, Earth Planet. Sc. Lett., 126, 435–456, 1994. 

Gasse, F.: Diatom-inferred salinity and carbonate oxygen isotopes in Holocene waterbodies of the western Sahara and Sahel (Africa), Quaternary Sci. Rev., 21, 737–767, 2002. 

Gat, J. R., Klein, B., Kushnir, Y., Roether, W., Wernli, H., Yam, R., and Shemesh, A.: Isotope composition of air moisture over the Mediterranean Sea: An index of the air-sea interaction pattern, Tellus B, 55, 953–965, https://doi.org/10.1034/j.1600-0889.2003.00081.x, 2003. 

Genty, D., Blamart, D., Ghaleb, B., Plagnes, V., Causse, C., Bakalowicz, M., Zouari, K., Chkir, N., Hellstrom, J., Wainer, K., and Bourges, F.: Timing and dynamics of the last deglaciation from European and North African δ13C stalagmite profiles-comparison with Chinese and South Hemisphere stalagmites, Quaternary Sci. Rev., 25, 2118–2142, 2006. 

Goldsmith, Y., Polissar, P. J., Ayalon, A., Bar-Matthews, M., deMenocal, P. B., and Broecker, W. S.: The modern and Last Glacial Maximum hydrological cycles of the Eastern Mediterranean and the Levant from a water isotope perspective, Earth Planet. Sc. Lett., 457, 302–312, https://doi.org/10.1016/j.epsl.2016.10.017, 2017. 

Grant, K. M., Grimm, R., Mikolajewicz, U., Marino, G., Ziegler, M., and Rohling, E. J.: The timing of Mediterranean sapropel deposition relative to insolation, sea-level and African monsoon changes, Quaternary Sci. Rev., 140, 125–141, https://doi.org/10.1016/j.quascirev.2016.03.026, 2016. 

Harrison, S., Bartlein, P., Izumi, K., Li, G., Annan, J., Hargreaves, J., Braconnot, P., and Kageyama, M.: Evaluation of CMIP5 palaeo-simulations to improve climate projections, Nat. Clim. Change, 5, 735–743, 2015. 

Hoffmann, D. L., Rogerson, M., Spötl, C., Luetscher, M., Vance, D., Osborne, A. H., Fello, N. M., and Moseley, G. E.: Timing and causes of North African wet phases during MIS 3 and implications for Modern Human migration, Nat. Sci. Rep., 6, 36367, https://doi.org/10.1038/srep36367, 2016. 

IPCC: Climate Change 2014: Impacts, Adaptation, and Vulnerability. Part B: Regional Aspects, Contribution of Working Group II to the Fifth Assessment Report of the Intergovernmental Panel on Climate Change, UK and New York, USA, 688 pp., 2014. 

Jolly, D., Prentice, I. C., Bonnefille, R., Ballouche, A., Bengo, M., Brenac, P., Buchet, G., Burney, D., Cazet, J. P., Cheddadi, R., Edorh, T., Elenga, H., Elmoutaki, S., Guiot, J., Laarif, F., Lamb, H., Lezine, A. M., Maley, J., Mbenza, M., Peyron, O., Reille, M., Reynaud-Farrera, I., Riollet, G., Ritchie, J. C., Roche, E., Scott, L., Ssemmanda, I., Straka, H., Umer, M., Van Campo, E., Vilimumbalo, S., Vincens, A., and Waller, M.: Biome reconstruction from pollen and plant macrofossil data for Africa and the Arabian peninsula at 0 and 6000 years, J. Biogeogr., 25, 1007–1027, 1998. 

Langgut, D., Almogi-Labin, A., Bar-Matthews, M., Pickarski, N., and Weinstein-Evron, M.: Evidence for a humid interval at ∼56–44 ka in the Levant and its potential link to modern humans dispersal out of Africa, J. Hum. Evol., 124, 75–90, https://doi.org/10.1016/j.jhevol.2018.08.002, 2018. 

McGarry, S., Bar-Matthews, M., Matthews, A., Vaks, A., Schilman, B., and Ayalon, A.: Constraints on hydrological and paleotemperature variations in the Eastern Mediterranean region in the last 140 ka given by the δD values of speleothem fluid inclusions, Quaternary Sci. Rev., 23, 919–934, https://doi.org/10.1016/j.quascirev.2003.06.020, 2004. 

Meckler, A. N., Affolter, S., Dublyansky, Y. V., Krüger, Y., Vogel, N., Bernasconi, S. M., Frenz, M., Kipfer, R., Leuenberger, M., Spötl, C., Carolin, S., Cobb, K. M., Moerman, J., Adkins, J. F., and Fleitmann, D.: Glacial–interglacial temperature change in the tropical West Pacific: A comparison of stalagmite-based paleo-thermometers, Quaternary Sci. Rev., 127, 90–116, https://doi.org/10.1016/j.quascirev.2015.06.015, 2015. 

Nicoll, K.: A revised chronology for Pleistocene paleolakes and Middle Stone Age – Middle Paleolithic cultural activity at Bîr Tirfawi – Bîr Sahara in the Egyptian Sahara, Quatern. Int., 463, 18–28, https://doi.org/10.1016/j.quaint.2016.08.037, 2018. 

Osborne, A., Vance, D., Rohling, E., Barton, N., Rogerson, M., and Fello, N.: A humid corridor across the Sahara for the migration of early modern humans out of Africa 120 000 years ago, P. Natl. Acad. Sci. USA, https://doi.org/10.1073/pnas.0804472105, 2008. 

Osborne, A. H., Marino, G., Vance, D., and Rohling, E. J.: Eastern Mediterranean surface water Nd during Eemian sapropel S5: monitoring northerly (mid-latitude) versus southerly (sub-tropical) freshwater contributions, Quaternary Sci. Rev., 29, 2473–2483, https://doi.org/10.1016/j.quascirev.2010.05.015, 2010. 

Pascale, S., Gregory, J. M., Ambaum, M., and Tailleux, R.: Climate entropy budget of the HadCM3 atmosphere-ocean general circulation model and of FAMOUS, its low-resolution version, Clim. Dynam., 36, 1189–1206, https://doi.org/10.1007/s00382-009-0718-1, 2011. 

Peleg, N. and Morin, E.: Convective rain cells: Radar-derived spatiotemporal characteristics and synoptic patterns over the eastern Mediterranean, J. Geophys. Res.-Atmos., 117, D15116, https://doi.org/10.1029/2011JD017353, 2012. 

Petit-Maire, N., Burollet, P. F., Ballais, J.-L., Fontugne, M., Rosso, J.-C., Lazaar, A., and Gauthier-Villars, I.: Paléoclimats holocènes du Sahara septentrional, Dépôts lacustres et terrasses alluviales en bordure du Grand Erg Oriental à l'extrême-Sud de la Tunisie, Comptes rendus de l'Académie des sciences, Série 2, Mécanique, Physique, Chimie, Sciences de l'univers, Sciences de la Terre, 312, 1661–1666, 1991. 

Peyron, O., Jolly, D., Braconnot, P., Bonnefille, R., Guiot, J., Wirrmann, D., and Chalie, F.: Quantitative reconstructions of annual rainfall in Africa 6000 years ago: Model-data comparison, J. Geophys. Res.-Atmos., 111, D24110, https://doi.org/10.1029/2006JD007396, 2006. 

Prentice, I. C. and Jolly, D.: Mid-Holocene and glacial-maximum vegetation geography of the northern continents and Africa, J. Biogeogr., 27, 507–519, 2000. 

Revel, M., Ducassou, E., Grousset, F. E., Bernasconi, S. M., Migeon, S., Revillon, S., Mascle, J., Murat, A., Zaragosi, S., and Bosch, D.: 100 000 Years of African monsoon variability recorded in sediments of the Nile margin, Quaternary Sci. Rev., 29, 1342–1362, https://doi.org/10.1016/j.quascirev.2010.02.006, 2010. 

Rogerson, M., Schönfeld, J., and Leng, M.: Qualitative and quantitative approaches in palaeohydrography: A case study from core-top parameters in the Gulf of Cadiz, Mar. Geol., 280, 150–167, 2011. 

Rogerson, M., Rohling, E. J., Bigg, G. R., and Ramirez, J.: Palaeoceanography of the Atlantic-Mediterranean Exchange: Overview and first quantitative assessment of climatic forcing, Rev. Geophys., 50, RG2003, https://doi.org/10.1029/2011RG000376, 2012. 

Rogerson, M., Dublyansky, Y., Hoffmann, D. L., Luetscher, M., Töchterle, P., and Spötl, C.: Fluid inclusion oxygen and hydrogen stable isotopes in a speleothem from Susah Cave, Libya, PANGAEA, https://doi.pangaea.de/10.1594/PANGAEA.904801, last access: 14 August 2019. 

Rohling, E., Marino, G., and Grant, K.: Mediterranean climate and oceanography, and the periodic development of anoxic events (sapropels), Earth-Sci. Rev., 143, 62–97, 2015. 

Rohling, E. J. and Bryden, H. L.: Estimating past changes in the Eastern Mediterranean freshwater budget, using reconstructions of sea level and hydrography, Proceedings Koninklijke Nederlandse Akademie van Wetenschappen, Serie B, 97, 201–217, 1994. 

Rowan, J. S., Black, S., Macklin, M. G., Tabner, B. J., and Dore, J.: Quaternary environmental change in Cyrenaica evidenced by U-Th, ESR and OSL of coastal alluvial fan sequences, Libyan Studies, 31, 5–16, 2000. 

Schwarcz, H. P., Harmon, R. S., Thompson, P., and Ford, D. C.: Stable isotope studies of fluid inclusions in speleothems and their paleoclimatic significance, Geochim. Cosmochim. Ac., 40, 657–665, https://doi.org/10.1016/0016-7037(76)90111-3, 1976. 

Smith, J. R., Giegengack, R., Schwarcz, H. P., McDonald, M. M. A., Kleindienst, M. R., Hawkins, A. L., and Churcher, C. S.: A reconstruction of quaternary pluvial environments and human occupations using stratigraphy and geochronology of fossil-spring tufas, Kharga Oasis, Egypt, Geoarchaeology, 19, 407–439, 2004. 

Smith, J. R., Hawkins, A. L., Asmerom, Y., Polyak, V., and Giegengack, R.: New age constraints on the Middle Stone Age occupations of Kharga Oasis, Western Desert, Egypt, J. Hum. Evol., 52, 690–701, 2007. 

Swezey, C.: Eolian sediment responses to late Quaternary climate changes: temporal and spatial patterns in the Sahara, Palaeogeogr. Palaeocl., 167, 119–155, 2001.  

Toucanne, S., Angue Minto'o, C. M., Fontanier, C., Bassetti, M.-A., Jorry, S. J., and Jouet, G.: Tracking rainfall in the northern Mediterranean borderlands during sapropel deposition, Quaternary Sci. Rev., 129, 178–195, https://doi.org/10.1016/j.quascirev.2015.10.016, 2015. 

Tuenter, E., Weber, S. L., Hilgen, F. J., and Lourens, L. J.: The response of the African summer monsoon to remote and local forcing due to precession and obliquity, Global Planet. Change, 36, 219–235, 2003. 

Vaks, A., Woodhead, J., Bar-Matthews, M., Ayalon, A., Cliff, R., Zilberman, T., Matthews, A., and Frumkin, A.: Pliocene–Pleistocene climate of the northern margin of Saharan–Arabian Desert recorded in speleothems from the Negev Desert, Israel, Earth Planet. Sc. Lett., 368, 88–100, 2013. 

Van Breukelen, M., Vonhof, H., Hellstrom, J., Wester, W., and Kroon, D.: Fossil dripwater in stalagmites reveals Holocene temperature and rainfall variation in Amazonia, Earth Planet. Sc. Lett., 275, 54–60, 2008. 

Wainer, K., Genty, D., Blamart, D., Daëron, M., Bar-Matthews, M., Vonhof, H., Dublyansky, Y., Pons-Branchu, E., Thomas, L., van Calsteren, P., Quinif, Y., and Caillon, N.: Speleothem record of the last 180 ka in Villars cave (SW France): Investigation of a large δ18O shift between MIS6 and MIS5, Quaternary Sci. Rev., 30, 130–146, https://doi.org/10.1016/j.quascirev.2010.07.004, 2011. 

Wassenburg, J. A., Immenhauser, A., Richter, D. K., Niedermayr, A., Riechelmann, S., Fietzke, J., Scholz, D., Jochum, K. P., Fohlmeister, J., Schröder-Ritzrau, A., Sabaoui, A., Riechelmann, D. F. C., Schneider, L., and Esper, J.: Moroccan speleothem and tree ring records suggest a variable positive state of the North Atlantic Oscillation during the Medieval Warm Period, Earth Planet. Sc. Lett., 375, 291–302, https://doi.org/10.1016/j.epsl.2013.05.048, 2013. 

Wassenburg, J. A., Dietrich, S., Fietzke, J., Fohlmeister, J., Jochum, K. P., Scholz, D., Richter, D. K., Sabaoui, A., Spötl, C., Lohmann, G., Andreae, M. O., and Immenhauser, A.: Reorganization of the North Atlantic Oscillation during early Holocene deglaciation, Nat. Geosci., 9, 602–605, https://doi.org/10.1038/ngeo2767, 2016. 

Publications Copernicus
Download
Short summary
Rainfall in North Africa is known to vary through time and is likely to change as global climate warms. Here, we provide a new level of understanding about past rainfall in North Africa by looking at a stalagmite which formed within northeastern Libya between 67 and 30 thousand years ago. We find that at times more rain falls, and the associated moisture is mostly derived from the western Mediterranean during winter storms. Sometimes, water comes from the eastern Mediterranean.
Rainfall in North Africa is known to vary through time and is likely to change as global climate...
Citation