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Timing of the Saalian- and Elsterian glacial cycles and the implications for Middle – Pleistocene hominin presence in central Europe


By establishing a luminescence-based chronology for fluvial deposits preserved between the Elsterian- and Saalian tills in central Germany, we obtained information on the timing of both the Middle Pleistocene glacial cycles and early human appearance in central Europe. The luminescence ages illustrate different climatic driven fluvial aggradation periods during the Saalian glacial cycle spanning from 400–150 ka. The ages of sediments directly overlying the Elsterian till are approximately 400 ka and prove that the first extensive Fennoscandian ice sheet extension during the Quaternary correlates with MIS 12 and not with MIS 10. Furthermore, the 400 ka old fluvial units contain Lower Paleolithic stone artefacts that document the first human appearance in the region. In addition, we demonstrate that early MIS 8 is a potential date for the onset of the Middle Paleolithic in central Germany, as Middle Paleolithic stone artefacts are correlated with fluvial units deposited between 300 ka and 200 ka. However, the bulk of Middle Paleolithic sites date to MIS 7 in the region. The fluvial units preserved directly under the till of the southernmost Saalian ice yield an age of about 150 ka, and enable a correlation of the Drenthe stage to late MIS 6.


The timing of the Middle Pleistocene glacial-interglacial cycles and the feedback mechanisms between climatic shifts and earth-surface processes are still poorly understood. This is largely due to a lack of dating results of sediments representing the advance and retreat of Middle Pleistocene ice sheets, as well as periglacial, interglacial or interstadial environments.

One key issue is the onset of the Elsterian glaciation, which was the first and southern-most ice advance of Fennoscandian ice sheets into the European continent1, and its relationship with the Middle Pleistocene Revolution (hereafter MPR). The MPR describes the shift from 41 ka–100 ka climate cycles that occurred ~1.5 Ma–0.5 Ma ago2. That significant change in climate cyclicity occurred without any change in external isolation forcing3, and huge ice sheets might have played a key role in this4,5, as they balanced insolation maxima3. To understand the feedback between earth ice sheets and the MPR, it is crucial to understand when this southern-most advance of Fennoscandian glaciers occurred. The timing of this important event is still a matter of debate1,6,7,8,9.

Several Early- and Middle-Pleistocene expansions of the British and Scandinavian ice are documented from the North Sea Basin8,9,10,11,12. The first basin-wide ice sheet expansion corresponds with Marine Isotope Stage (hereafter MIS) 128,13, but it is debatable if this ice advance correlates to what is, per definition, the Elsterian glaciation because the typo region for the latter is located much further south in central Germany14,15,16,17 and resilient chronological data from this isn’t available yet. Consequently, the correlation between the Elsterian glaciation and MIS 10 is still discussed6. The latter is mainly linked to the stratigraphical position of the Elsterian prior to the Holsteinian interglacial1. For the Holsteinian, a correlation with MIS 11 or MIS 9 is still debated, as it is mainly linked to the chronology of the Bossel-profile7,18, Lower Saxony/Germany. The latter is regarded as a typo-profile for the Holsteinian and the corresponding U-series ages point to a correlation with MIS 9. Consequently, the German Stratigraphic Table6, which is a fundamental stratigraphical reference, states an age of 320-300 ka for the Holsteinian. However, potential problems with U/Th-dating of peat due to the open system behavior of U-series were recently outlined by Sierralta et al.19 for another Holsteinian type profile from Wedel, Schleswig-Holstein/Germany and the Paleolithic site of Schöningen, Lower Saxony/Germany. Furthermore, other studies20,21,22,23,24,25 deliver evidence of a correlation of the Holsteinain with MIS 11 and further clarification is needed.

With regard to the Saalian glacial cycle, more chronological data is needed to reconstruct the timing and extension of the two significant ice advances and spatial variations among different parts of Europe.

Furthermore, during most of the Saalian glacial cycle central Europe was characterized by periglacial environmental conditions14,17,26. Chronological data of sediment archives representing periglacial but also potentially warmer Saalian climate periods are very sparse until now. Therefore, there is a lack of knowledge about the response of sedimentary systems to climatic shifts during the Saalian period.

A better understanding of Middle Pleistocene palaeoenvironmental changes is also of high relevance for the understanding of human dispersal into central Europe, as well as the timing of technological changes within the archaeological record. The Middle Pleistocene is the time period from which we start to have major archaeological evidence for human presence together with the emergence of the Middle Paleolithic (‘MP’; see e.g27,28,29,30,31.) in central Europe. Therefore, the oldest traces of human appearance in central Germany post-date the Elsterian glaciation (see e.g27,28,32,33,34,35,36,37,38). Whether this first glaciation eroded traces of prior human occupation, or whether the Baltic flint transported to large parts of the central European lowlands attracted humans as a high quality raw material source, remains an open question. Nevertheless, the age of the Elsterian glaciation is crucial for our understanding of when humans (re-)populated the European lowlands. Additionally, a higher resolution dating of the time period between the Elsterian and Saalian glaciations may help to understand when and under which palaeoenvironmental conditions the transition from the Lower to the Middle Paleolithic occurred in the study area.

The most suitable area to investigate the above questions is the type area for the Elsterian- and Saalian glacial cycles, located in central Germany15 (Saxony, Saxony-Anhalt and Thuringia, Fig. 1a). This is where the gravel deposits of the rivers Saale- and Elster intertwine with tills and meltwater deposits of both glacial cycles in proximity to the maximum extensions of the Fennoscandian ice sheets in Central Europe17,39,40,41,42. To obtain chronological data for the timing of the Elsterian- and Saalian glacial cycles, we used feldspar luminescence dating stimulating the feldspar-luminescence signal at elevated temperatures43,44,45,46.

Figure 1

(a) Ice marginal positions of the main ice advances into central Germany17 and (b) map showing the distribution of the Saalian Main Terrace (SMT) in the study area and the location of investigated sites. (a) The green box marks the study area. The 2 ice advances (Older and Younger Elster) during the Elsterian stage are also termed Zwickau phase (1st ice advance) and Markranstädt Phase (2nd ice advance) in the Leipzig Lowlands. The tills are separated by melt- water-sands of the so called “Miltitz- Intervall”. Both significant ice advances during the Elsterian stage are estimated to have occurred during the late Elsterian17,96,97. During the Saalian glacial cycle, the first and southern-most ice sheet extension into the Leipzig lowlands (Older Saale) reached the city of Zeitz (Zeitz-phase). The Zeitz-phase correlates to the late Saalian Drenthe stadial1,17. The Younger Saalian ice advance (Warthe) did not reach the study area. Warm stage deposits between the different Saalian ice advances are not documented1. We composed the map using SRTM 1Arc-Second Global data for elevation ( and processed it with the GNU General Public License software QGIS Version 2.18 ( (b) The SMT was formed by several rivers within the Saale-Elbe area and the term “Saalian” refers to the formation of the fluvial units during the Saalian glacial cycle. The terminus Main “Terrace”98 is not used in a morphological sense. The stacked fluvial units accumulated in several phases between the Holsteinian interglacial and the Saalian ice advance of the Zeitz-phase17,39,52. The map was redrawn from Eissmann99 using Adobe Illustrator CS6.

As tills cannot be dated using luminescence dating, the fluvial units of the so called ‘Hauptterrasse’ (Fig. 1b) or Saalian Main Terrace (hereafter SMT) are pertinent to these issues. Its stacked sediment-units are preserved between the tills of the Elsterian and Saalian glaciations.

Additionally, the basal part of the SMT is associated with Middle- and Lower Paleolithic stone artifacts32,33,47,48,49,50,51.

By dating the SMT, it is therefore possible:

  1. A.

    to get reliable chronological control for the Elsterian and Saalian ice advances.

  2. B.

    to reconstruct the climatically driven fluvial aggradation within the Saalian glacial cycle.

  3. C.

    to obtain minimum ages for the embedded Middle- and Lower Paleolithic stone artefacts.



The lithology and facies architecture of the SMT as well as the stratigraphical position of associated paleolithic artefact findings have been well documented in several studies14,16,17,32,39,42,50,52,53. The very bottom part of the SMT, when preserved, is built by the Corbicula-fluvial unit which contains warm-stage fossils54,55. This points to an initial formation of the SMT under warm climate conditions, but a reworking of the fossils must be considered. All overlying units of the SMT have been attributed to cold climate56 as evidenced by the fluvial facies architecture and cryoturbation features including several levels of ice wedges. Furthermore, mammal remains such as Mammuthus primigenius or Ovibos moschatus are suggestive of the formation of the SMT in a periglacial environment.

Only a small number of infrared-radiofluorescence ages of SMT- sediments, ranging from 306 ± 23 ka to 227 ± 15 ka57 are available from different sites in eastern Germany, however these ages were presented without stratigraphical context, making the interpretation challenging.

The currently exposed lithostratigraphy of the SMT sites of Rehbach, Zwenkau and Schladebach/Wallendorf was documented during recent luminescence sampling-campaigns. The site of Markkleeberg is no longer accessible and luminescence samples were provided by the Freiberg (Saxony) dating laboratory. The lithological description of the site is based on the work of E. Miersch58.

The sedimentary units of all sites under investigation are outlined in Fig. 2, which also illustrates the stratigraphical position of stone artefacts.

Figure 2

Lithostratigraphy of the fluvial units exposed at Schladebach/Wallendorf, Rehbach, Zwenkau and Markkleeberg including pIRIR290 luminescence ages. A summary of all luminescence ages is given in Supplementary Table S2. The green-colored ages are infrared-radiofluorescence ages formerly presented by Krbetschek et al.61 (see results chapter). At Schladebach and Rehbach, the Saalian Main Terrace is visibly capping the Elsterian till. Only the first Elsterian till is preserved whereas the upper Elsterian till was eroded and only a boulder pavement as a till-residuum is found. At Markkleeberg, only the boulder pavement is preserved. At Schladebach and Rehbach, fragments of the ice-dammed lake sediments of the Dehlitz-Leipzig warved clay41 are preserved below the SMT. The SMT itself is mostly horizontally bedded but also shows some cross-beddings. The upper fluvial sand and gravel are characterized by permafrost features such as ice wedges, and at Rehbach and Markkleeberg, the “Markkleeberg cryoturbation horizon” is preserved. The Markkleeberg cryoturbation horizon is a wide-spread, silt-rich unit that was not found at the outcrop at Zwenkau. The SMT is concordantly capped by the Böhlen warved clays and the up to 2 m thick Saalian till (Drenthe). The fluvial sequence in Markkleeberg was formed by the Pleiße/Gösel-river system. The gravel of the SMT at Rehbach and Zwenkau were deposited by the Weiße Elster river and the petrographic composition shows a high percentage of Nordic material (e.g. flint) as well as quartz, greywacke and chert (Kieselschiefer) documenting the catchment area of the Weiße Elster river in eastern Thuringia and the Vogtland. The SMT deposits at Schladebach correlate to the Saale-Unstrut river system14. The gravel composition of these deposits is characterized by high percentages of limestone originating from the Triassic sediment formations located south of the section in addition to Scandinavian rock components including flint.

Luminescence chronology


The luminescence samples taken from the very bottom part of the SMT exposed at Schladebach, which contain reworked clay and organic rich sediments and directly cap the Elsterian till, yield ages ranging from 387 ± 42 ka –447 ± 52 ka (Fig. 2; Supplementary Table S2). The ages overlap within the error-range and point to an initial period of fluvial aggradation of the SMT during MIS 11 or early MIS 1059. The decalcification of the basal gravels in the Schladebach/Wallendorf SMT and the presence of mollusks60 support an onset of the fluvial aggradation during moderate climate conditions33. These luminescence ages deliver a minimum age for the embedded Lower Paleolithic stone artefacts of approximately 400 ka.

The pIRIR290 luminescence age estimates obtained from the upper- and middle part of the Schladebach section are 343 ± 42 ka, 360 ± 34 ka and 338 ± 31 ka. This age-cluster points to the aggradation of several meters of sand and gravel during MIS 10.


The luminescence ages of Rehbach are indicative of 4 phases of fluvial aggradation. The ages obtained from the very bottom part of the SMT, preserved fragmentarily above the Elsterian till, are 423 ± 48 and 387 ± 48 ka, and are similar to the corresponding luminescence ages obtained at Schladebach. Therefore, at Rehbach the initial formation of the SMT correlates to MIS 11/ early MIS 10 too.

The capping fluvial unit is dated to 239 ± 31 ka and correlates to late MIS 8 or MIS 7. Therefore, a significant chronological gap of around 150 ka is documented within the Rehbach sedimentary sequence.

The central part of the SMT at Rehbach is dated to 173 ± 16 ka, suggesting a 3rd period of fluvial aggradation during MIS 6.

The top part of the SMT, which directly underlies the till of the southern-most ice sheet extension (Zeitz phase) during the Saalian glacial cycle, yields luminescence ages of 144 ± 13 ka and 160 ± 13 ka. These ages correlate to a later period of MIS 6, and constitute maximum ages for the till of the Zeitz-phase (Drenthe).


At Zwenkau, only approximately 3 meters of fluvial sand and gravel are exposed. The bottom portion was dated to 280 ± 45 ka (MIS 8). The capping unit, here discordantly underlying the Saalian till of the Zeitz phase, is dated to 185 ± 22 and 183 ± 21 ka. This suggests that the main part of the preserved SMT at Zwenkau dates to early MIS 6 and can chronostratigraphically be correlated to the middle part of the Rehbach-section. Late MIS 6 fluvial sediments are not preserved at Zwenkau.


The archeologically important site of Markkleeberg is no longer accessible due to the closing of the former pit. The dating material from the SMT was taken by Matthias Krbetschek (1956–2012) from the University of Freiberg (Saxony) in the early 2000s. Some of the K-feldspar samples were kindly provided to us by Freiberg University. Unfortunately, no material was available from the bottom portion of the SMT, from which most of the stone artefacts derive. The only chronological information of this basal unit is based on preliminary infrared-radiofluorescence (IR-RF) ages42,57,61 pointing to an aggradation around 250 ka (236 ± 23 ka)61. However, a quality-validation of this IR-RF age is not possible.

The pIRIR290 luminescence ages from the top-part of the SMT at Markkleeberg are 217 ± 24 ka (the sediments underlying the Markkleeberg silt and cryoturbation horizon), and the unit concordantly underlying the Saalian till yields luminescence ages of 164 ± 16 and 159 ± 17 ka. The pIRIR290 ages are in very good agreement with the IR-RF ages obtained from the same samples presented by Krbetschek et al.61.


From the middle of the 20th century until today, more than 6700 Lower Paleolithic artefacts were recovered from the base of the SMT sequence and the coarse gravel dump at the gravel pits of Schladebach and Wallendorf32,33. During luminescence sampling and additional surveys, a number of additional finds were documented including 6 fragmented animal bones, 10 simple flake cores (Supplementary Figures S23S25), 16 flakes and 3 tools (Fig. 3A), all of which derive from the exposed basal parts of the SMT sequence (see Supplementary Figures S19S21). The artefacts are primarily of Lower Paleolithic character, though only one flake has a slightly faceted platform (see Supplementary Tables S3 and S4), indicating a trend towards the Middle Paleolithic. This slight trend has already been observed in the earlier collections32,33. The luminescence ages of approximately 400 ka (Fig. 2) indicate a human presence in central Germany that is characterized by a Lower Paleolithic stone tool industry including sparse MP features32,33 during MIS 11 or early MIS 10 (Fig. 4). No knapping sites were documented in the basal gravels, either within our own or previous surveys. Instead, the artefacts are scattered along the whole basal SMT sequence. Sharp edged artefacts are rare in the older collections33. During our own survey, the recovered artefacts (see Supplementary Tables S3 and S4) are a mixture of lightly edge damaged pieces (e.g. Fig. 3A-7), edge damaged flakes (e.g. Fig. 3A-2) and rolled artefacts (e.g. Fig. 3A-5). Indications show that artefacts were predominantly reworked during the onset of the fluvial aggradation. Therefore, they are likely slightly older than the ages of the SMT at the Schladebach pit presented here. In other words, the ages for the sediment that contains the artefacts should be interpreted as a minimum age for the human presence at the site. As the basal sediments of the SMT suggest temperate climatic conditions60, and the artefacts are found in sediments overlying Elsterian glacial deposits, an MIS 11 age for the artefacts can be inferred. Given that fact that the artefacts only occur within the basal layers of the sequence as well as the ages for the whole sequence are older than MIS 9 (except the age on top of the gravel accumulation; Fig. 2), an age younger than MIS 10 for the artefacts along with the human presence can be excluded.

Figure 3

Artefacts found during sampling for luminescence dating and additional surveys in Schladebach (A), Rehbach (B) and during a formerly survey in Zwenkau-“Bösdorf” (C). A: 1–scraper (11263:1000:8); 2–7–flakes (2–11263:1000:1; 3–11263:1000:23; 4–11263:1000:11; 5–11263:1000:13; 6–11263:1000:24; 7–11263:1000:3); 8–flake with potentially retouched notch (11263:1000:29); B: 1–prepared core (REH-09/1/2); 2–flake (REH-09/1/3); C: bifacial scraper (BQF-04/1/1). Scale: ½ original size. Numbers given for Schladebach are the inventory numbers of the Landesamt für Denklmalpflege und Archäologie Sachsen-Anhalt–Landesmuseum für Vorgeschichte; the numbers given for Rehbach and Bösdorf are the inventory numbers of the Landesamt für Archäologie Sachsen. Drawings: A and B: M. Weiss; C: W. Bernhardt.

Figure 4

Middle Pleistocene climatic fluctuations100 as well as luminescence ages from this study indicating periods of Middle-Pleistocene fluvial aggradation of the SMT. Within the bottom part of the graph, next to the boxes with site labels, the direct dated sites Weimar-Ehringsdorf71,72,82 and Schöningen34,78 are added to complete the picture of human presence in central Germany. The MIS boundaries59 referred to in that paper are: 13/12 = 478 ka; 12/11 = 424 ka; 11/10 = 374 ka; 10/9 = 337 ka; 9/8 = 300 ka; 8/7 = 243 ka; 7/6 = 191 ka; 6/5 = 130 ka. First traces of humans in central Germany (Schladebach/Wallendorf) are most likely connected to the Holsteinain (MIS 11). The blue arrows mark a: the first significant ice advances of Fennoscandian glaciers during the Quaternary (Elsterian glacial cycle) within MIS 12 and b: the southernmost ice sheet extension during the Saalian glacial cycle (Zeitz-phase; Drenthe).

In conclusion, Schladebach/Wallendorf is now the oldest directly dated archaeological site in central Germany27 and is among the oldest sites in central Europe (the Biśnik cave in Poland provided some similar and some older dates, predating MIS 1262).

From the Middle Paleolithic site of Markkleeberg, we were able to date two of the three reported find layers49 present in the SMT sequence (Fig. 2): The upper find horizon, where artefacts were potentially preserved in primary position, yields an age of about 160 ka. This is evidence for human presence in central Germany during cold conditions prior to the first Saalian ice advance. The upper part of the Middle find horizon, where rolled artefacts in secondary context were excavated49, has an age of approximately 220 ka. Additionally, the IR-RF age (236 ± 23 ka) from the bottom part of the sequence (Krbetschek et al.61) indicates an MIS 7 age of these artefacts.

The MP artefacts from the former open-cast brown coal mine of Zwenkau were recovered from the base of the exposed SMT sequence. The already published assemblages50 were named after the former villages within the Zwenkau quarry “Eythra” and “Bösdorf”, which were destroyed by mining. The date for the base of the SMT presented here (Fig. 2) provides an age of 280 ± 45 ka for the artefacts, and is characterized by a sophisticated MP bifacial tool production system50. In the area of the western slope, from which the luminescence samples derive, a bifacial scraper was found in stratigraphic position at the basal part of the SMT during former surveys (Fig. 3C, pers. comm. W. Bernhardt, November 20th 2017, who recovered and documented the artefact). The luminescence ages demonstrate the presence of humans with a fully developed MP stone tool industry between early MIS 8 and MIS 7 in central Germany (Fig. 4).

During sampling for luminescence dating in the gravel pit of Rehbach, a typical MP Levallois core and a flake were found (Fig. 3B) within dislocated SMT basal gravels. Additionally, a damaged, potentially artificial flint flake was found in stratigraphic position within the approximately 240 ka old gravel unit (see Supplementary Figure S27), that makes a correlation of all artefacts to that unit likely.

The age of around 240 ka for the basal fluvial sediments at Rehbach is younger compared to the age of around 280 ka obtained at the basal sedimentary sequence at Zwenkau, especially if the sites are part of the same fluvial terrace. Nevertheless, the age for the find bearing basal part of the SMT at Rehbach of 239 ± 31 ka overlaps the lower error range with the age obtained for the basal part of the SMT at Zwenkau (Fig. 2; Fig. 4). This overlap confirms the MP human presence in central Germany around MIS 8–7.

Discussion and Conclusion

Implications of the SMT chronology for the timing of the Fennoscandian ice sheet extension, and the age of the Holsteinian

The ages of the lower-most gravel unit of the SMT, ranging from 447 ± 52 ka-387 ± 48 ka, post-date the Elsterian till. This highlights the fact that the Elsterian glacial cycle cannot be correlated with MIS 10 and therefore correlates to MIS 12. These age estimates deliver the first resilient chronological control for the Elsterian glacial cycle from its typo region and demonstrate that there is limited temporal gap between the end of Middle Pleistocene Revolution and the onset of the huge Middle Pleistocene glaciations in Europe.

As the Elsterian glacial cycle is terminated by the Holsteinian interglacial, the ages presented here support the suggestion of a correlation of the Holsteinian with MIS 11.

The top part of the SMT yields luminescence ages ranging from 164 ± 16 ka - 144 ± 13 ka, and was deposited during the later MIS 6. The stratigraphic position of theses layers directly under the Saalian till or Saalian warved clays shows that the southernmost Saalian ice advance in the region occurred during late MIS 6, hence at the end of the Saalian glacial cycle. The new data delivers important supplementary ages to the recently by Lang et al.63 published chronological data for the extension of the Saalian ice sheet into Germany. The pIRIR290 luminescence ages demonstrate that there might have been spatial- and chronological variations for the Middle-Pleistocene Fennoscandian ice sheet oscillations. For the region of northern Germany Roskosch et al.64 documented a higher number of Middle Pleistocene ice advances relative to our study area. More resilient chronological data of sediments correlating to ice sheet fluctuations along a European transect may be mandatory to better understand these spatial differences in the future.

Driving forces and timing of fluvial aggradation within the SMT

The luminescence age estimates of the SMT point to several periods of fluvial aggradation spanning from about 400 ka–150 ka. The exposed fluvial sand and gravel cover a time span of approximately 250 ka, and the accumulation of the sedimentary sequences might be explained by the interplay of relatively rapid fluvial aggradation interrupted by periods of erosion or less fluvial activity.

MIS 11-10

At Rehbach and Schladebach, the very basal part of the exposed fluvial units contains gravel and sand partly including reworked clay-rich and seldom organic deposits which are indicative of the onset of increased fluvial activity, including the reworking of warm-stage (Holsteinian) deposits during the MIS 11–MIS 10 transition. The dating-precision does not allow for the separation between MIS 11 or early MIS 10. However, an increased mobilization of gravel and corresponding aggradation is more likely to correspond to the climatic shift towards colder climatic periods65 than during an interglacial with presumably stabilized landscape surfaces.

The pIRIR290 luminescence age estimates obtained from the upper- and middle part of the section at Schladebach overlap within the error and are indicative of the aggradation of several meters of sand and gravel during MIS 10. Ice wedges inside the sedimentary sequence support the idea of fluvial activity at Schladebach under periglacial, cold climate conditions. The luminescence ages do not allow us to distinguish between various aggradation periods during MIS 10, but the ice wedges at different elevation levels suggest a periodically stable terrace surface. Generally, several fluvial aggradation events during MIS 10 can be assumed.

MIS 9-6

MIS 9 sediments are not preserved at the investigated sites. The luminescence ages obtained from Rehbach and Zwenkau clearly show significant chronological gaps between the fluvial units. The most substantial hiatus was documented at the basal part of the Rehbach-section, where the approximately 400 ka old basal unit is capped by around 240 ka old deposits. This hiatus indicates significant erosion, most likely during MIS 8.

At Rehbach, Zwenkau and Markkleeberg the main periods of fluvial aggradation occurred between MIS 8 or the MIS 8 - MIS 7 transition to late MIS 6.

MIS 6 aggradation is shown at Rehbach, Zwenkau and Markkeeberg. The fluvial sequence at Rehbach represents the climatic shift from early- to late MIS 6 in the middle- to upper part of the sedimentary sequence. The deposits preserved at the middle part of the section, dated to 173 ± 16 ka show no permafrost features such as ice wedges whereas the upper part, dated to 144 ± 13 and 160 ± 13 ka, represents permafrost conditions towards the glacial maximum of MIS 6.

Fluvial aggradation in the study area may have been driven mainly by climatic shifts towards colder climate conditions during the Middle Pleistocene. The most rapid fluvial aggradation documented in this study occurred during MIS 10 and MIS 6.

Interpretation of the ages for the Middle- and Lower Paleolithic stone artefact assemblages, and the implications for human dispersal into central Germany

The first hominin occupation of Europe and the human dispersal is discussed in several studies (27,28,66,67 among others), however evidence for the presence of sites older than 250 ka in central Europe is relatively sparse27,28. Therefore, the Schladebach/Wallendorf site, directly dated in the present study to MIS 11 or early MIS 10 (Figs 2; 4), adds an important data point to the ongoing debate about the human occupation and dispersal into central Europe. Another important site potentially attributed to the MIS 11 interglacial in central Germany36 is the Thuringian travertine site of Bilzingsleben68,69,70 (for a summary of the geology, the age estimations and the research history see the article by C. Pasda35). Unfortunately, 230Th/U dating on micro samples has thus far been unsuccessful, largely due to strong weathering of the travertine, resulting in open system behavior for U71. Nevertheless, because U series activity ratios yielded values close to the radioactivity equilibrium, it was suggested that the age of the site is likely ≥300 ka71,72. Although the anthropogenic origin of the majority of the artefacts has recently been questioned35, human cranial remains prove the presence of humans in Bilzingsleben73. A recent study of the megafauna from the site74 confirms the natural accumulation of many of the bones and also demonstrates ephemeral evidence for a human accumulation agent. We provide evidence here that Wallendorf/Schladebach, with more than 670032,33 stone artefacts, confirms the presence of humans in central Germany around MIS 11 and/or early MIS 10. These humans had a Lower Paleolithic stone tool industry, with few MP features (e.g. prepared cores32,33) at that time.

Schöningen in Lower Saxony75,76,77 is the next younger Lower Paleolithic site confirming human presence in central Germany during the MIS 9 interglacial34,36,78 (Fig. 4). Although the MIS 9 ages based on 230Th/U dating on peat78 were rejected recently due to U-series open system behavior19, we favor the MIS 9 interpretation for the find layer of Schöningen based on: (1) the interpretation of the geological succession following the Elsterian sediments36, (2) a palynological record which is distinct from the Holsteinian79, and (3) the recently published MIS 9 ages based on luminescence dating of heated flint34. Besides exceptional faunal remains, like teeth and a humerus fragment of a saber-toothed cat, the site is famous for the preservation of wooden spears75,80. These thrusting spears demonstrate the manufacture and use of wooden hunting weapons in the Lower Paleolithic. Like in Schladebach/Wallendorf, the stone artefacts from Schöningen are attributed to the (late) Lower Paleolithic: prepared cores are not present, the tools and the blank production is based on rather thick and broad flakes and, although evidence for bifacial shaping is present, handaxes themselves are missing81.

During the following MIS 8, we have archaeological evidence in central Germany (Fig. 4) from Rehbach and Zwenkau. Previously, the lower find horizon of Markkleeberg was suggested to have an early MIS 8 age49 as well, but the IR-RF ages of M. Krbetschek (Fig. 2) indicate an MIS 7 age for the lower find horizon. The age we present for the base of the SMT in Zwenkau is suggestive of an onset of the MP in the region in early MIS 8, however, the relatively skewed De-distribution of sample L-Eva 1614 (overdispersion = 31%) may indicate an age-overestimation. Recent evidence from the site Kesselt-Op de Schans/Belgium also suggests an age for the Lower to Middle Paleolithic transition in Northwestern Europe during the end of MIS 9 and the onset of MIS 8, about 280 ka31. This matches the range of our age from Zwenkau. However, given the results of a recent comparative study about the early MP record in western and northern Europe28, there are only a few sites that have layers correlated with MIS 8, and there is little evidence for human presence during the MIS 8 Pleniglacial. The majority of the early MP sites in Europe are in fact associated with MIS 728,30.

Considering this European evidence, an MIS 7 age for the occurrence of the fully developed MP in central Germany is more likely. This is underlined by the fact that the date for the basal SMT of Zwenkau overlaps in its lower error range with the MIS 7 age of Rehbach (which points to the MIS 8/ MIS 7 boundary), as well as the MIS 7 IR-RF ages for the basal find horizon of Markkleeberg. The hypothesis is reinforced by the Thuringian travertine site Weimar-Ehringsdorf. Several attempts71,72,82 have dated the formation of the travertine in Weimar-Ehringsdorf to MIS 7. The artefact assemblage found in several layers within the travertine of Weimar-Ehringsdorf is attributed to the Middle Paleolithic83,84,85. Importantly, several of the human skeletal remains have Neanderthal features86. Among them are the cranial remains of a female, and partial skeleton remains of a child86. The clearly identified Neanderthal features87 of the human remains indicate that with the emergence of the fully developed MP during MIS 8 (?) - MIS 7 in central Germany, the Neanderthal lineage was linked to this stone tool industry.

During the MIS 6 cold stage (Fig. 4), we have evidence from the upper find layer of Markkleeberg that humans adapted to the cold stage environment and were present in central Germany shortly before the major Saalian ice advance around 150 ka. The finds were described as sharp edged in situ artefacts, preserved in gravel lenses within small fluvial channels49. Therefore, we can infer that the finds were not reworked and/or transported from an older find horizon.

From the archaeological evidence in central Germany and the dates presented in this study, we can infer that:

  1. (1)

    The Lower Paleolithic human presence started in MIS 11 and lasted until about MIS 9.

  2. (2)

    Due to a significant chronological gap within the sedimentary units of the SMT, spanning from MIS 9-8, a reconstruction of human occupation during this time period is difficult. The basal age of Zwenkau (280 ± 45 ka) and the lower error range of the Rehbach basal date (239 ± 31 ka) point to human presence in the region of potentially early MIS 8. Furthermore, if we accept that the region was not inhabited during the MIS 8 glacial maximum, humans may have been present at the boundary of MIS 8 and MIS 7. With regard to the dates from sites like Markkleeberg and Ehringsdorf, we can infer that the bulk of MP sites dates to the beginning of MIS 7 in central Germany, at the latest.

  3. (3)

    The age of the upper find horizon in Markkleeberg is suggestive of human presence during the cold phases of MIS 6.

Materials and Methods



The gravel pit of Schladebach, Saxony-Anhalt (51°18′22.66′′N, 12° 6′17.28′′E), is situated about 20 km west of Leipzig. Here, the SMT gravels of the Saale-Unstrut-river system are exploited by mining. About 3 km to the north are the former gravel pits of Wallendorf32,33. Here, more than 6700 artefacts were recovered from the base of the same SMT sequence and from the SMT coarse gravel dump of the pits. The artefacts were described as having a Lower Paleolithic character32,33. The flakes were detached from simple flake cores, with changing striking platforms and directions. Among the tools, notched pieces are the most numerous, followed by simple scrapers. Nevertheless, some MP traits were reported32,33: A small number of cores can be classified as prepared or Levallois cores (unfortunately no numbers are given in the cited publications), and some flakes show facetted platforms. Additionally, some bifacially worked tools, like simple handaxe-like forms, occur in the assemblage. During a survey at the exposed SMT base at the Schladebach pit, which was conducted by the authors in addition to the luminescence sampling, 10 cores (Supplementary Figures S23S25), 16 flakes, 2 scrapers, and a potentially notched tool (Fig. 3A) were recovered (see also Supplementary Tables S3 and S4.

The luminescence samples were taken from the exposed SMT sequence of the ongoing gravel pit.


Markkleeberg (51°16′15.29′′N, 12°24′5.35′′E), Saxony, is situated about 8 km south of the center of Leipzig, and is one of the most important sites for the early MP in Germany. The first artefacts were found at the end of the 19th and the beginning of the 20th century88 in several gravel pits within the SMT sequence (Pleiße/Gösel-river system). These finds were comprehensively published by Grahmann in 195548. Later, at the end of the 1970s until the beginning of the 1980s, about 4500 artefacts were recovered and partly excavated from the base of the fluvial sequence47. Archaeological surveys were carried out as accompanying measures to the open-cast brown coal mining, which took place east of the town of Markkleeberg and affected the formerly described find locations of the artefacts. The last excavations in Markkleeberg took place between 1999 and 200149, when the mine was continuously flooded to create a lake. From this recent excavation, three find horizons were reported:49 (1) the main find horizon at the base of the terrace sequence with partly in situ find concentrations, where also the artefacts found between 1977–198047 were recovered, (2) the middle find horizon, with rolled, re-deposited artefacts, and (3) an upper find horizon at the top of the SMT sequence with sharp-edged, in situ artefacts, corresponding to the layers were the artefacts were recovered at the beginning of the 20th century49 (pit “Markleeberg d”). The artefact assemblages from Markkleeberg can be characterized as typical MP, with prepared or Levallois cores, scrapers and bifacial tools such as handaxes47,48,49.

The site of Markkleeberg is no longer accessible. The luminescence samples were taken by M. Krbetschek during fieldwork campaigns between 1999 and 2001, and were made accessible to us by the Freiberg (Saxony) dating laboratory.


The MP artefacts were recovered in a former brown coal open-cast mine named Zwenkau, Saxony (51°14′11.68′′N, 12°16′11.88′′E), which is approximately 14 km south-east of the center of Leipzig. Within the open-cast mine, the SMT sequence of the Elster-river system was accessible. Because of villages situated formerly in the area of the mine, the artefacts are published under the site names “Eythra” and “Bösdorf”50 (Fig. 3C). 1850 artefacts50 were recovered during surveys of the base of the SMT. The high proportion of bifacial tools is a particularly significant feature of this collection. About 50% of all tools are bifaces such as handaxes, knives and bifacial scrapers. Levallois cores are present, but are not very common. The majority of the cores are opportunistic flake cores, with several exploition surfaces (pers. comm. W. Bernhardt, Schkeuditz, who recovered and documented the artefacts).

The luminescence samples derive from a part of the SMT sequence which is preserved in the western slope of the former open-cast brown coal mine. In this area, a bifacial scraper was found in the profile of the basal part of the SMT (Fig. 3C, pers. comm. W. Bernhardt, November 20th 2017, who recovered and documented the artefact).


The gravel pit of Rehbach, Saxony (51°16′11.43′′N, 12°16′59.46′′E), is situated approximately 4 km north-west of the former coal mine Zwenkau, and is situated within the gravels of the same SMT (Elster-river system) sequence. During sampling for luminescence dating, we recovered a typical MP Levallois core and a flake (Fig. 3B) from dislocated SMT basal gravels. Another flint flake was found in stratigraphic position within the SMT sequence (Supplementary Figure S27).

The luminescence samples were taken from the exposed SMT sequence of the ongoing gravel pit.


Luminescence sample preparation and instrumental details

Luminescence-samples and material for gamma spectrometry were taken at equal positions. Sample preparation followed the common steps, including the removal of carbonates and organic matter in HCl and H2O2. To separate feldspar from heavy minerals and quartz, either density separation using lithium heterotungstate, or, for samples from Markkleeberg and Zwenkau, the flotation technique89 was used. All samples from the section Markkleeberg were etched for 40 min using 10% HF to remove the alpha-ray affected outer rim of the coarse feldspar grains.

Finally, the sample material was mounted on steel discs (aliquots) using silicon spray.

Equivalent dose (De) measurements were undertaken using automated Risø TL-DA-20 reader. The feldspar signal was stimulated using IR light-emitting diodes transmitting at 870 nm (145 mW/cm2) and the feldspar signal was detected in the blue-violet wavelength region. Irradiation was provided by a calibrated 90Sr/90Y beta source with a dose-rate of ~0.24 Gy/s.

Dose rate determination

Dose rates were determined based on high resolution germanium gamma spectrometric analysis of the activities of uranium, thorium, potassium, and their daughter isotopes. All samples were measured on the bulk material at the “Felsenkeller” laboratory (VKTA) in Dresden.

Dose rate attenuation by moisture was accounted for using water content values of 15 ± 10%. The cosmic-dose rate contribution to the ionization of minerals was based on Presscot and Hutton90.

The internal potassium content was assumed to be at 12.5 ± 0.5%91.

To account for alpha efficiency an a-value of 0.11 ± 0.02 92was used for non-etched samples and the dose rate conversion factors were taken from Guerin et al.93.

Equivalent dose measurements

Luminescence dating was applied to coarse-grained K-feldspar using the pIRIR290 approach similar to Thiel et al.45. Prior to the detection of the elevated temperature feldspar signal at 290 °C for 200 seconds, the IR50 signal, mostly affected by higher rates of anomalous fading, was depleted by stimulating with infrared-diodes for 100 seconds. The measurement protocol is shown in Supplementary Table S1. The pIRIR290 approach was chosen due to its high signal stability (negligible fading) and as its suitability to date Middle Pleistocene sediments46.

For equivalent dose measurements, grain size fractions of 180–250 microns were used for material from the sites Rehbach, Zwenkau and Schladebach/Wallendorf.

For the samples from Markkleeberg, the 90–160 microns fraction was used.

All equivalent dose measurements were conducted using very small aliquots with a sample-diameter between 0.5 mm–1 mm. Hence, only a very few grains were put on one aliquot allowing to point out if there was any skewness in equivalent dose distribution due to insufficient bleaching.

For each sample, 3–5 artificial doses were inserted to create the dose response curve.

At the end of the measurement cycle of the pIRIR290 SAR approach, the first artificial dose was inserted again to measure the recycling ratio as quality criteria. For final equivalent dose estimation, only aliquots yielding recycling ratios deviating within 10% from unity were accepted.

Equivalent dose overdispersions are mostly >25% (see Supplementary Table S2) and equivalent dose distributions indicate mostly sufficient bleaching (see Supplementary Figures S1S18). Therefore the Central Age Model94 was used for age calculations.

Dose recovery tests were conducted on samples L-Eva 1594, 1599, 1600 and 1612. Therefore, the sample material was bleached for 24 hrs under a solar simulator (UVA cube 400). Remaining dose residuals were then measured for respectively 3 aliquots from each sample. A further 3 aliquots were irradiated with a known dose close to the assumed natural one, and afterwards the precision of the recovered dose was tested. All residual subtracted measured to given dose ratios are within ±10% deviation from unity and are at 1.08 ± 0.04 (L-Eva 1594), 1.09 ± 0.07 (L-Eva 1599), 0.93 ± 0.22 (L-Eva 1600) and 1.09 ± 0.02 (L-Eva 1612).

Fading measurements following Huntley and Lamothe95 were conducted on 6 aliquots from samples L-Eva 1594, L-Eva 1612 and L-Eva 1638. The pIRIR290 g-values are at 2.4 ± 0.37, 1.53 ± 0.59 and 1.37 ± 0.20 respectively.

The presented ages are non-fading corrected as obtained pIRIR290 fading rates are low and fading is interpreted to have only negligible effect on the equivalent doses.

Additionally, pIRIR225 measurements43,44 were conducted on samples L-Eva 1594 and L-Eva 1597 (Rehbach gravel pit). The pIRIR225 ages are presented and discussed in the supplementary part of the paper.

Data Availability

The datasets generated during the current study are available from the corresponding author on reasonable request.


  1. 1.

    Litt, T., Behre, K.-E., Meyer, K.-D., Stephan, H.-J. & Wansa, S. Stratigraphische Begriffe für das Quartär des norddeutschen Vereisungsgebietes. Eiszeitalter und Gegenwart. Quat. Sci. J. 56, 7–65 (2007).

    Google Scholar 

  2. 2.

    Head, M. J. & Gibbard, P. L. Early-Middle Pleistocene transitions: an overview and recommendation for the defining boundary. Geol. Soc. London, Spec. Publ. 24, 1–18 (2005).

    ADS  Article  Google Scholar 

  3. 3.

    Bintanja, R. & van de Wal, R. S. W. North American ice-sheet dynamics and the onset of 100,000-year glacial cycles. Nature 454, 869–872 (2008).

    ADS  CAS  Article  PubMed  Google Scholar 

  4. 4.

    Mudelsee, M. & Schulz, M. The Mid-Pleistocene climate transition: onset of 100 ka cycle lags ice volume build-up by 280 ka. Earth Planet. Sci. Lett. 151, 117–123 (1997).

    ADS  CAS  Article  Google Scholar 

  5. 5.

    Clark, P. U. Northern Hemisphere Ice-Sheet Influences on Global Climate Change. Science (80-.). 286, 1104–1111 (1999).

    CAS  Article  Google Scholar 

  6. 6.

    Deutsche Stratigraphische Kommission. Stratigraphische Tabelle Deutschland 2016. in (eds Menning, M. & Hendrich, A.) (GeoForschungsZentrum, 2016).

  7. 7.

    Geyh, M. H. & Müller, H. Numerical 230Th/U dating and a palynological review of the Holsteinian/Hoxnian Interglacial. Quat. Sci. Rev. 24, 1861–1872 (2005).

    ADS  Article  Google Scholar 

  8. 8.

    Toucanne, S. et al. A 1.2 Ma record of glaciation and fluvial discharge from the West European Atlantic margin. Quat. Sci. Rev. 28, 2974–2981 (2009).

    ADS  Article  Google Scholar 

  9. 9.

    Böse, M., Lüthgens, C., Lee, J. R. & Rose, J. Quaternary glaciations of northern Europe. Quat. Sci. Rev. 44, 1–25 (2012).

    ADS  Article  Google Scholar 

  10. 10.

    King, E. L., Haflidason, H., Sejrup, H. P. & Løvlie, R. Glacigenic debris flows on the North Sea Trough Mouth Fan during ice stream maxima. Mar. Geol. 152, 217–246 (1998).

    ADS  Article  Google Scholar 

  11. 11.

    Stewart, M. A. & Lonergan, L. Seven glacial cycles in the middle-late Pleistocene of northwest Europe: Geomorphic evidence from buried tunnel valleys. Geology 39, 283–286 (2011).

    ADS  Article  Google Scholar 

  12. 12.

    Lamb, R. M., Harding, R., Huuse, M., Stewart, M. & Brocklehurst, S. H. The early Quaternary North Sea Basin. J. Geol. Soc. London. jgs 2017-057, (2017).

  13. 13.

    Laban, C. & van der Meer, J. J. M. Pleistocene glaciation in The Netherlands. Developments in Quaternary Science 15 (2011).

  14. 14.

    Eissmann, L. Das Quartär der Leipziger Tieflandsbucht und angrenzender Gebiete um Saale und Elbe (1975).

  15. 15.

    Eissmann, L.; Litt, T.; Wansa, S. Elsterian and Saalian deposits in their type area in central Germany. In Glacial deposits north-east Europe (eds Ehlers, J., Kozarski, S. & Gibbard, P. L.) 439–464 (1995).

  16. 16.

    Eissmann, L. Das quartäre Eiszeitalter in Sachsen und Nordostthüringen. Altenburg. naturwissenschaftliche Forschungen 8, 1–98 (1997).

    Google Scholar 

  17. 17.

    Eissmann, L. Quaternary geology of eastern Germany (Saxony, Saxon-Anhalt, South Brandenburg, Thüringia), type area of the Elsterian and Saalian Stages in Europe. Quat. Sci. Rev. 21, 1275–1346 (2002).

    ADS  Article  Google Scholar 

  18. 18.

    Geyh, M. A. & Krbetschek, M. R. Zum radiometrischen Alter des Holstein-Interglazials. In Die chronologische Einordnung der paläolithischen Fundstellen von Schöningen. The chronological setting of the Palaeolithic sites of Schöningen (ed. Behre, K.-E.) 155–170 (Verlag des Römisch-Germanischen Zentralmuseums, 2012).

  19. 19.

    Sierralta, M., Urban, B., Linke, G. & Frechen, M. Middle Pleistocene interglacial peat deposits from Northern Germany investigated by 230 Th/U and palynology: case studies from Wedel and Schöningen. Zeitschrift der Dtsch. Gesellschaft für Geowissenschaften 168, 373–387 (2017).

    Article  Google Scholar 

  20. 20.

    Nitychoruk, J., Bińka, K., Ruppert, H. & Schneider, J. Holsteinian Interglacial = Marine Isotope Stage 11? Quat. Sci. Rev. 25, 2678–2681 (2006).

    ADS  Article  Google Scholar 

  21. 21.

    Koutsodendris, A. et al. A short-term climate oscillation during the Holsteinian interglacial (MIS 11c): An analogy to the 8.2 ka climatic event? Glob. Planet. Change 92–93, 224–235 (2012).

    Article  Google Scholar 

  22. 22.

    Scourse, J. D., Ansari, M. H., Wingfield, R. T. R., Harland, R. & Balson, P. S. A middle pleistocene shallow marine interglacial sequence, inner silver pit. Quat. Sci. Rev. 17, (871–900. Pollen and dinoflagellate cyst stratigraphy and sea-level history, Southern North Sea, 1998).

    Google Scholar 

  23. 23.

    Scourse, J. Comment on: Numerical 230Th/U dating and a palynological review of the Holsteinian/Hoxnian Interglacial by Geyh and Müller. Quaternary Science Reviews 25, 3070–3071 (2006).

    ADS  Article  Google Scholar 

  24. 24.

    Preece, R. C. et al. Terrestrial environments during MIS 11: evidence from the Palaeolithic site at West Stow, Suffolk, UK. Quat. Sci. Rev. 26, 1236–1300 (2007).

    ADS  Article  Google Scholar 

  25. 25.

    Schreve, D. C. Differentiation of the British late Middle Pleistocene interglacials: The evidence from mammalian biostratigraphy. In Quaternary Science Reviews 20, 1693–1705 (2001).

    ADS  Article  Google Scholar 

  26. 26.

    Eissmann, L. Periglaziäre Prozesse und Permafroststrukturen aus sechs Kaltzeiten des Quartärs. Ein Beitrag zur Periglazialgeologie aus der Sicht des Saale-Elbe Gebietes. Altenburger Naturwissenschaftliche Forschungen 1 (1981).

  27. 27.

    Haidle, M. N. & Pawlik, A. F. The earliest settlement of Germany: Is there anything out there? Quat. Int. 223–224, 143–153 (2010).

    Article  Google Scholar 

  28. 28.

    Hérisson, D. et al. The emergence of the Middle Palaeolithic in north-western Europe and its southern fringes. Quat. Int. 411, 233–283 (2016).

    Article  Google Scholar 

  29. 29.

    Richter, J. Leave at the height of the party: A critical review of the Middle Paleolithic in Western Central Europe from its beginnings to its rapid decline. Quat. Int. 411, 107–128 (2016).

    Article  Google Scholar 

  30. 30.

    Wiśniewski, A. The beginnings and diversity of Levallois methods in the early Middle Palaeolithic of CentralEurope. Quat. Int. 326–327, 364–380 (2014).

    Article  Google Scholar 

  31. 31.

    van Baelen, A. The Lower to Middle Palaeolithic transition in northwestern Europe. Evidence from Kesselt-Op de Schans. (Leuven University Press, 2017).

  32. 32.

    Laurat, T., Rudolph, A. & Bernhardt, W. The Lower Palaeolithic site of Wallendorf in Saxony-Anhalt (Germany). In Archaeology and Palaeoecology of Eurasia (in Russian) (eds. Derevyanko, A. N. & Nochrina, T. I.) 232–244 (Institute of Archaeology and Ethnology, Russian Academy of Science, 2004).

  33. 33.

    Laurat, T., Rudolph, A. & Bernhardt, W. Zu den Gerätetypen der altpaläolithischen Fundstelle Wallendorf (Sachsen-Anhalt). Archäologisches Korrespondenzblatt 34, 1–19 (2004).

    Google Scholar 

  34. 34.

    Richter, D. & Krbetschek, M. The age of the Lower Paleolithic occupation at Schöningen. J. Hum. Evol. 89, 46–56 (2015).

    Article  PubMed  Google Scholar 

  35. 35.

    Pasda, C. A study of rocks and flints from Bilzingsleben. Quartaer 59, 7–46 (2012).

    Google Scholar 

  36. 36.

    Jöris, O. & Baales, M. Zur Altersstellung der Schöninger Speere. In Erkenntnisjäger. Kultur und Umwelt des frühen Menschen. Festschrift für Dietrich Mania (eds. Burdukiewicz, J. M., Fiedler, L., Heinrich, W.-D., Justus, A. & Brühl, E.) 281–288 (Landesamt für Denkmalpflege und Archäologie Sachsen-Anhalt, Landesmuseum für Vorgeschichte, 2003).

  37. 37.

    Meng, S. & Wansa, S. Lithologie, Stratigraphie und Paläoökologie des Mittelpleistozäns von Uichteritz im Markröhlitzer Tal (Lkr. Weißenfels/Sachsen-Anhalt). Eiszeitalter und Gegenwart 55, 174–214 (2005).

    Google Scholar 

  38. 38.

    Rudolph, A., Laurat, T. & Bernhardt, W. Die altpaläolithischen Artefaktfunde von Uichteritz, Ldkr. Weißenfels. Eiszeitalter und Gegenwart 55, 215–226

  39. 39.

    Eissmann, L., Litt, T. Das Quartär Mitteldeutschlands. Ein Leitfaden und Exkursionsführer. Mit einer Übersicht über das Präquartär des Saale-Elbe-Gebietes. (1994).

  40. 40.

    Eissmann, L. S. In Das Quartär Deutschlands 148–198 (Borntraeger, 1995).

  41. 41.

    Junge, F. W. D. B. Mitteldeutschlands und angrenzender Gebiete - Ein regionaler Beitrag zur quartären Stausee-Entwicklung im Randbereich des elsterglazialen skandinavischen Inlandeises. Altenburg. Naturwissenschaftliche Forschungen 9, 210 (1998).

    Google Scholar 

  42. 42.

    Eissmann, L. Die Erde hat Gedächtnis. 50 Millionen Jahre mitteleuropäische Erd- und Klimageschichte. (2008).

  43. 43.

    Thomsen, K. J., Murray, A. S., Jain, M. & Bøtter-Jensen, L. Laboratory fading rates of various luminescence signals from feldspar-rich sediment extracts. Radiat. Meas. 43, 1474–1486 (2008).

    CAS  Article  Google Scholar 

  44. 44.

    Buylaert, J. P., Murray, A. S., Thomsen, K. J. & Jain, M. Testing the potential of an elevated temperature IRSL signal from K-feldspar. Radiat. Meas. 44, 560–565 (2009).

    CAS  Article  Google Scholar 

  45. 45.

    Thiel, C. et al. Luminescence dating of the Stratzing loess profile (Austria) - Testing the potential of an elevated temperature post-IR IRSL protocol. Quat. Int. 234, 23–31 (2011).

    Article  Google Scholar 

  46. 46.

    Buylaert, J. P. et al. A robust feldspar luminescence dating method for Middle and Late Pleistocene sediments. Boreas 41, 435–451 (2012).

    Article  Google Scholar 

  47. 47.

    Baumann, W., Mania, D., Toepfer, V. & Eißmann, L. Die paläolithischen Neufunde von Markkleeberg bei Leipzig. (1983).

  48. 48.

    Grahmann, R. The Lower Palaeolithic site of Markkleeberg and other comparable localities near Leipzig. Trans. Am. Philos. Soc. 45, 509–687 (1955).

    Article  Google Scholar 

  49. 49.

    Schäfer, J., Laurat, T. & Kegler, J. F. Bericht zu den Ausgrabungen am altsteinzeitlichen Fundplatz Markkleeberg 1999 bis 2001. Arbeits- und Forschungsberichte zur sächsischen Bodendenkmalpfl. 45, 13–47 (2003).

  50. 50.

    Rudolph, A., Bernhardt, W. & Eissmann, L. Die Acheuléenfunde von Eythra bei Leipzig. Archäologisches Korrespondenzblatt 25, 275–289 (1995).

    Google Scholar 

  51. 51.

    Bernhardt, W.; Thum, J.; Schneemilch, M.; Rudolph, A. Flußschotter als Schaufenster in die Zeit der ältesten Besiedlung Mitteldeutschlands. Die altsteinzeitlichen Artefaktfunde von Wallendorf bei Merseburg. Archäologie in Sachsen-Anhalt 7 (1997).

  52. 52.

    Eissmann, L. Die stratigraphischen und paläogeographischen Hauptbefunde im Saale-Elbe-Raum und ihre Bedeutung für die mitteleuropäische Quartärgeologie. Ethnogr.-Archäol. Z. 30, 596–635 (1989).

    Google Scholar 

  53. 53.

    Wansa, S. & Junge, F. Quaternary geology and prehistory in the type region of the Elsterian cold stage and of the Saalian cold stage in the Halle (Saale) area. In From the northern ice shield to the Alpine glaciations A Quaternary field trip through Germany; Excursion guide of the pre-congress field trip of the INQUA Congress in Bern, Switzerland, 21– 27 July 2011. (ed. Sauer, D.) 88 (2011).

  54. 54.

    Steinmüller, A. Die jungpleistozäne Schichtenfolge von Kösen-Lengefeld und zur Gliederung der Saale-Eiszeit. Geologie 21, 1173–1195 (1972).

    Google Scholar 

  55. 55.

    Meng, S. & Wansa, S. Sediments and processes at the borderline of Saalian glaciation southwest of Halle (Saale). Zeitschrift der Dtsch. Gesellschaft für Geowissenschaften 159, 205–220 (2008).

    Article  Google Scholar 

  56. 56.

    Junge, F. W., Novenko, E., Seifert-Eulen, M. & Boettger, T. Early Saalian landscape dynamics in the Saale-Elbe region (Profen opencast mine, Central Germany): fluvial sedimentation, vegetation history and geochemistry. Zeitschrift der Dtsch. Gesellschaft für Geowissenschaften 159, 221–235 (2008).

    Article  Google Scholar 

  57. 57.

    Krbetschek, M. R., Degering, D. & Alexowsky, W. Infrarot-Radiofluoreszenz-Alter (IR-RF) unter-saalezeitlicher Sedimente Mittel- und Ostdeutschlands <BR> [Infrared radiofluorescence ages (IR-RF) of Lower Saalian sediments from Central and Eastern Germany]. Zeitschrift der Dtsch. Gesellschaft für Geowissenschaften 159, 133–140 (2008).

    Article  Google Scholar 

  58. 58.

    Miersch, E. Geologisch sedimentologische Analyse fluviatiler Sedimente aus der Frühsaale und dem Frühpleistozän Mitteldeutschlands - Diploma thesis. (Freiberg (Saxony) University, 2002).

  59. 59.

    Lisiecki, L. E. & Raymo, M. E. A Plio-Pleistocene stack of 57 globally distributed benthic [delta]18O records. Paleoceanography 20, PA1003 (2005).

    ADS  Google Scholar 

  60. 60.

    Weber, T. & Thum, J. Prospektion in Tagebaugebieten und Rekonstruktion der Siedlungsgeschichte im Paläolithikum. Veröffentlichungen des Museums für Ur- und Frühgeschichte Potsdam 25, 21–25 (1991).

    Google Scholar 

  61. 61.

    Krbetschek, M.R.; Erfurt, G., Degering, D. Radiofluorescence dating: A novel method for age determination of clastic sediment deposits from about 20 ka to 300 ka. Poster presentation; XVI Inqua Congress, Reno (USA) (2003).

  62. 62.

    Cyrek, K., Sudoł, M., Czyżewski, Ł., Osipowicz, G. & Grelowska, M. Middle Palaeolithic cultural levels from Middle and Late Pleistocene sediments of Biśnik Cave, Poland. Quat. Int. 326–327, 20–63 (2014).

    Article  Google Scholar 

  63. 63.

    Lang, J., Lauer, T. & Winsemann, J. New age constraints for the Saalian glaciation in northern central Europe: Implications for the extent of ice sheets and related proglacial lake systems. Quat. Sci. Rev. 180, 240–259 (2018).

    ADS  Article  Google Scholar 

  64. 64.

    Roskosch, J. et al. Luminescence dating of ice-marginal deposits in northern Germany: Evidence for repeated glaciations during the Middle Pleistocene (MIS 12 to MIS 6). Boreas 44, 103–126 (2015).

    Article  Google Scholar 

  65. 65.

    Van Huissteden, K., Vandenberghe, J., Gibbard, P.L., Lewin, J. Periglacial Fluvial Sediments and Forms. In The Encyclopedia of Quaternary Science (ed. Elias S.A) 2600 (Elsevier, 2013).

  66. 66.

    Roebroeks, W. The human colonisation ofEurope: where are we? J. Quat. Sci. 21, 425–435 (2006).

    Article  Google Scholar 

  67. 67.

    Roebroeks, W. & van Kolfschoten, T. The earliest occupation of Europe. Proceedings of the European Science Foundation workshop at Tautavel (France), 1993. (University of Leiden, 1995).

  68. 68.

    Mania, D., Toepfer, V. & Vlček, E. Bilzingsleben I. Homo erectus - seine Kultur und Umwelt. (Deutscher Verlag der Wissenschaften, 1980).

  69. 69.

    Mai, D. H. et al. Bilzingsleben II. Homo erectus - seine Kultur und seine Umwelt. (Deutscher Verlag der Wissenschaften, 1983).

  70. 70.

    Weber, T. Die Steinartefakte des Homo erectus von Bilzingsleben. In Bilzingsleben III (eds Weber, T. & Mania, D.) 65–231 (Veröffentlichungen des Landesmuseums für Vorgeschichte in Halle 39, 1986).

  71. 71.

    Mallick, R. & Frank, N. A new technique for precise uranium-series dating of travertine micro-samples. Geochim. Cosmochim. Acta 66, 4261–4272 (2002).

    ADS  CAS  Article  Google Scholar 

  72. 72.

    Mallick, R., Frank, N., Mangini, A. & A., W. G. Präzise Th/U-Datierung archäologisch relevanter Travertinfundstellen Thüringens. In Frühe Menschen in Mitteleuropa - Chronologie, Kultur, Umwelt (eds Wagner, G. A. & Mania, D.)77–90 (2001).

  73. 73.

    Vlček, E., Mania, D. & Mania, U. Der fossile Mensch von Bilzingsleben. Bilzingsleben VI. (Beier & Beran, 2002).

  74. 74.

    Brasser, M. Die Megafauna von Bilzingsleben. (Landesamt für Denkmalpflege und Archäologie Sachsen-Anhalt, Landesmuseum für Vorgeschichte, 2017).

  75. 75.

    Thieme, H. Die Schoeninger Speere: Mensch und Jagd vor 400 000 Jahren. (Theiss, 2007).

  76. 76.

    Conard, N. J. et al. Excavations at Schöningen and paradigm shifts in human evolution. J. Hum. Evol. 89, 1–17 (2015).

    Article  PubMed  Google Scholar 

  77. 77.

    Serangeli, J., Böhner, U., Van Kolfschoten, T. & Conard, N. J. Overview and new results from large-scale excavations in Schöningen. J. Hum. Evol. 89, 27–45 (2015).

    Article  PubMed  Google Scholar 

  78. 78.

    Sierralta, M., Frechen, M. & Urban, B. 230Th/U dating results from opencast mine Schöningen. In Die chronologische Einordnung der paläolithischen Fundstellen von Schöningen The chronological setting of the Palaeolithic sites of Schöningen (ed. Behre, K.-E.) 143–154 (Verlag des Römisch-Germanischen Zentralmuseums, 2012).

  79. 79.

    Urban, B., Sierralta, M. & Frechen, M. New evidence for vegetation development and timing of Upper Middle Pleistocene interglacials in Northern Germany and tentative correlations. Quat. Int. 241, 125–142 (2011).

    Article  Google Scholar 

  80. 80.

    Schoch, W. H., Bigga, G., Böhner, U., Richter, P. & Terberger, T. New insights on the wooden weapons from the Paleolithic site of Schöningen. J. Hum. Evol. 89, 214–225 (2015).

    Article  PubMed  Google Scholar 

  81. 81.

    Serangeli, J. & Conard, N. J. The behavioral and cultural stratigraphic contexts of the lithic assemblages from Schöningen. J. Hum. Evol. 89, 287–297 (2015).

    Article  PubMed  Google Scholar 

  82. 82.

    Schüler, T. ESR dating of a new Palaeolithic find layer of the travertine site of Weimar-Ehringsdorf (Central Germany). Terra Nostra 2, 233–235 (2003).

    Google Scholar 

  83. 83.

    Behm-Blancke, G. Altsteinzeitliche Rastplätze im Travertingebiet von Taubach, Weimar, Ehringsdorf. Alt. Thuring. 4 (1960).

  84. 84.

    Schäfer, D. Grundzüge der technologischen Entwicklung und Klassifikation vor-jungpaläolithischer Steinartefakte in Mitteleuropa Grundzüge der technologischen Entwicklung und Klassifikation vor-jungpaläolithischer Steinartefakte in Mitteleuropa Principles of technolog. Bericht RGK 74, 49–194 (1993).

    Google Scholar 

  85. 85.

    Schäfer, D. Weimar-Ehringsdorf: Diskussionsstand zur geochronologischen und archäologischen Einordnung sowie aktuelle Aufschlußsituation. Quartär 41/42, 19–43 (1991).

    Google Scholar 

  86. 86.

    Vlček, E. Fossile Menschenfunde von Weimar-Ehringsdorf. (1993).

  87. 87.

    Hublin, J. J. The origin of Neandertals. Proc. Natl. Acad. Sci. 106, 16022–16027 (2009).

    ADS  CAS  Article  PubMed  PubMed Central  Google Scholar 

  88. 88.

    Jacob-Friesen, K. H. Paläolitische Funde aus Leipzigs Umgebung. Prähistorische Zeitschrift 3, 116–122 (1911).

    Google Scholar 

  89. 89.

    Miallier, D., Sanzelle, S, Frain, J. The use of flotation technique to seperate quartz from feldspar. Anc. TL 1 (1983).

  90. 90.

    Prescott, J. R. & Hutton, J. T. Cosmic ray contributions to dose rates for luminescence and ESR dating: Large depths and long-term time variations. Radiat. Meas. 23, 497–500 (1994).

    CAS  Article  Google Scholar 

  91. 91.

    Huntley, D. J. & Baril, M. R. The K content of the K-feldspars being measured in optical dating or thermoluminescence dating. Anc. TL 15, 11–13 (1997).

    Google Scholar 

  92. 92.

    Kreutzer, S., Schmidt, C., Dewitt, R. & Fuchs, M. The a-value of polymineral fine grain samples measured with the post-IR IRSL protocol. Radiat. Meas. 69, 18–29 (2014).

    CAS  Article  Google Scholar 

  93. 93.

    Guérin, G., Mercier, N. & Adamiec, G. Dose-rate conversion factors: update. Anc. TL29, 5–8 (2011).

  94. 94.

    Galbraith, R. F., Roberts, R. G., Laslett, G. M., Yoshida, H. & Olley, J. M. Optical dating of single and multiple grains of quartz from Jinmium Rock Shelter, northern Australia: Part I, Experimental design and statistical models. Archaeometry 41, 339–364 (1999).

    Article  Google Scholar 

  95. 95.

    Huntley, D. J. & Lamothe, M. Ubiquity of anomalous fading in K-feldspars and the measurement and correction for it in optical dating. Can. J. Earth Sci. 38, 1093–1106 (2001).

    ADS  CAS  Article  Google Scholar 

  96. 96.

    Eissmann, L. Reduced to the Maximum: Mitteleuropäisches Quartär im Spiegel hochverdichteter geologischer Schnitte. Mauritania 19, 1–16 (2004).

    Google Scholar 

  97. 97.

    Hoffmann, K. & Eissmann, L. Glaziäres Labyrinth. Pfadsuche in einer Grundmoränenplatte des skandinavischen Vereisungsgürtels in Mitteleuropa (Tagebau Espenhain, südlich Leipzig). Mauritania 19, 17–59 (2004).

    Google Scholar 

  98. 98.

    Siegert, L. & Weissermel.L. Das Diluvium zwischen Halle a. S. und Weißenfels (1911).

  99. 99.

    Eissmann, L. Quaternary geology of eastern Germany (Saxony, Saxon–Anhalt, South Brandenburg, Thuringia), type area of the Elsterian and Saalian Stages in Europe. Quat. Sci. Rev. 21, 1275–1346 (2002).

    ADS  Article  Google Scholar 

  100. 100.

    Lüthi, D. et al. High-resolution carbon dioxide concentration record 650,000–800,000 years before present. Nature 453, 379–382 (2008).

    ADS  Article  PubMed  Google Scholar 

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This study is dedicated to Matthias Krbetschek (1956–2012). Matthias significantly contributed to a better understanding on Quaternary stratigraphy, optical dating and palaeoenvironmental research. Some of his ongoing projects could never be finished by himself and we are very grateful, that we had the opportunity to continue his chronological work at the important site Markkeeberg. Herby we also want to thank Detlev Degering (VKTA Dresden) and Ingrid Stein (Freiberg University) for providing us the dose rate data from Markkleeberg and the K-feldspars for luminescence dating respectively. We are very thankful to Frank Junge for supporting us with information on the stratigraphy especially for the sites Rehbach and Markkleeberg. We are also grateful to Steffi Hesse and Katharina Schilling for luminescence sample preparation. Furthermore, we would like to thank the “Mitteldeutsche Baustoffe GmbH”, which gave as access to their ongoing gravel pits Rehbach and Schladebach. We thank also the Landesamt für Archäologie Sachsen and the Landesamt für Denkmalpflege und Archäologie Sachsen-Anhalt–Landesmuseum für Vorgeschichte (Halle/Saale) for supporting our study. Thanks as well to Will Archer for helpful comments on the manuscript. The research was funded by the Max Planck Society.

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T.L. and M.W. wrote the main manuscript text. T.L. collected the luminescence samples and performed the dating. M.W. conducted the artefact surveys at the sites. T.L. prepared the Figures 1,2 and 4. M.W. analyzed and drew the artefacts and prepared Figure 3.

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Correspondence to Tobias Lauer or Marcel Weiss.

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Lauer, T., Weiss, M. Timing of the Saalian- and Elsterian glacial cycles and the implications for Middle – Pleistocene hominin presence in central Europe. Sci Rep 8, 5111 (2018).

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