Hostname: page-component-848d4c4894-r5zm4 Total loading time: 0 Render date: 2024-06-26T02:22:56.424Z Has data issue: false hasContentIssue false
  • English
  • Français

ASSESSING LOCK-IN DEPTH AND ESTABLISHING A LATE HOLOCENE PALEOMAGNETIC SECULAR VARIATION RECORD FROM THE MONGOLIAN ALTAI

Published online by Cambridge University Press:  15 May 2023

Marcel Bliedtner Open the ORCID record for Marcel Bliedtner [Opens in a new window] ,
Torsten Haberzettl ,
Norbert Nowaczyk ,
Enkhtuya Bazarradnaa ,
Roland Zech  and
Paul Strobel
Marcel Bliedtner*
Affiliation:
Institute of Geography, Friedrich Schiller University Jena, 07743 Jena, Germany
Torsten Haberzettl
Affiliation:
Physical Geography, Institute for Geography and Geology, University of Greifswald, 17489 Greifswald, Germany
Norbert Nowaczyk
Affiliation:
Helmholtz Centre Potsdam GFZ, Section Climate Dynamics and Landscape Evolution, 14473 Potsdam, Germany
Enkhtuya Bazarradnaa
Affiliation:
Institute of Plant and Agricultural Sciences, Mongolian University of Life Sciences, 45047 Darkhan, Mongolia
Roland Zech
Affiliation:
Institute of Geography, Friedrich Schiller University Jena, 07743 Jena, Germany
Paul Strobel
Affiliation:
Institute of Geography, Friedrich Schiller University Jena, 07743 Jena, Germany
*
*Corresponding author. Email: marcel.bliedtner@uni-jena.de
Rights & Permissions [Opens in a new window]

Abstract

Although paleomagnetic secular variations (PSV) often corroborate radiocarbon (14C)-based lacustrine sediment chronologies, this is not the case at the high-altitude site Khar Nuur in the Mongolian Altai Mountains. Our results show that the inclination pattern resembles those from a regional reference record from Shireet Naiman Nuur and global geomagnetic field models very well, but with a constant offset of 730 ± 90 yr. Possible reservoir effects from terrestrial pre-aging and hardwater effects can be excluded as the cause of the ∼730-yr offset because the different dated compounds correspond very well to each other, and modern reservoir effects are negligible. Instead, the constant ∼730-yr offset in the PSV pattern is likely the result of a constant lock-in depth of 26 ± 2 cm below the sediment-water interface at Khar Nuur. This assumption is supported by comparison of paleoclimatological proxies from Shireet Naiman Nuur, where similarities are obvious for the 14C-based chronology of Khar Nuur without a ∼730-yr adjustment. Therefore, the previously published 14C-based chronology of Khar Nuur provides a reliable age control. Accepting the lock-in depth of 26 ± 2 cm, the good consistency in inclination between Khar Nuur and global geomagnetic field models highlights the reliability of the latter even in a paleomagnetically understudied area.

Keywords

lake sedimentspaleoenvironmental changespaleomagnetic secular variationsradiocarbon datingsemi-arid Mongolia
Type
Conference Paper
Information
Radiocarbon , First View , pp. 1 - 12
Check for updates
Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted re-use, distribution and reproduction, provided the original article is properly cited.
Copyright
© The Author(s), 2023. Published by Cambridge University Press for the Arizona Board of Regents on behalf of the University of Arizona

INTRODUCTION

Precise age control is an important precondition for robust paleoenvironmental reconstructions from lacustrine sediments. However, in semi-arid regions such as Mongolia, chronological control of the existing paleoenvironmental lacustrine records is often imprecise because most chronologies rely on few 14C-dates, almost exclusively made on bulk organic material (e.g., Sun et al. Reference Sun, Feng, Ran and Zhang2013; Unkelbach et al. Reference Unkelbach, Kashima, Enters, Dulamsuren, Punsalpaamuu and Behling2019; Rudaya et al. Reference Rudaya, Nazarova, Frolova, Palagushkina, Soenov, Cao, Syrykh, Grekov, Otgonbayar and Bayarkhuu2021). Unfortunately, bulk organic carbon often needs to be dated in semi-arid regions due to the absence of terrestrial macrofossils in lake sediments. Compared to terrestrial macrofossils, which are assumed to be rapidly deposited in lakes (Hajdas et al. Reference Hajdas, Bonani and Goślar1995), bulk organic carbon can be “pre-aged” because organic material accumulates in the catchment over hundreds to thousands of years. Consequently, bulk organic carbon is possibly too old when finally ending up in the lake, overestimating its “true” deposition age (Haberzettl et al. Reference Haberzettl, St-Onge, Behling and Kirleis2013; Wündsch et al. Reference Wündsch, Biagioni, Behling, Reinwarth, Franz, Bierbaß, Daut, Mäusbacher and Haberzettl2014; Gierga et al. Reference Gierga, Hajdas, van Raden, Gilli, Wacker, Sturm, Bernasconi and Smittenberg2016; Douglas et al. Reference Douglas, Pagani, Eglinton, Brenner, Curtis, Breckenridge and Johnston2018; Haas et al. Reference Haas, Baumann, Castella, Haghipour, Reusch, Strasser, Eglinton and Dubois2019). Moreover, lake sediments comprise organic material from terrestrial and aquatic sources and the radiocarbon (14C)-signal from aquatic contributions can additionally be affected by the so-called “hardwater effect” due to incorporation of carbonate from old calcareous bedrock and/or re-dissolved carbon from in-lake carbonate precipitation (Reinwarth et al. Reference Reinwarth, Franz, Baade, Haberzettl, Kasper, Daut, Helmschrot, Kirsten, Quick, Meadows and Mäusbacher2013). Therefore, the reliability of paleoenvironmental reconstructions can be largely limited due to chronological uncertainties of the potentially reservoir affected 14C-signal.

In this context, paleomagnetic secular variation (PSV) stratigraphy is a valuable chronostratigraphic tool to evaluate and potentially refine 14C-based chronologies (Barletta et al. Reference Barletta, St-Onge, Channell and Rochon2010; Ólafsdóttir et al. Reference Ólafsdóttir, Geirsdóttir, Miller, Stoner and Channell2013; Haberzettl et al. Reference Haberzettl, Henkel, Kasper, Ahlborn, Su, Wang, Appel, St-Onge, Stoner, Daut, Zhu and Mäusbacher2015, Reference Haberzettl, Kirsten, Kasper, Franz, Reinwarth, Baade, Daut, Meadows, Su and Mäusbacher2019, Reference Haberzettl, Kasper, Stoner, Rahobisoa and Daut2021; Bliedtner et al. Reference Bliedtner, Strobel, Struck, Salazar, Szidat, Nowaczyk, Bazarradnaa, Lloren, Dubois, Haberzettl and Zech2022). PSV changes are ideally suited to study shortterm changes especially throughout the Holocene. The principle behind PSV in lacustrine sediments is that magnetic particles align themselves with the surrounding geomagnetic field during deposition and preserve their direction when locked-in during ongoing deposition (Merrill and McFadden Reference Merrill, McFadden, Gubbins and Herrero-Bervera2007; Roberts and Turner Reference Roberts and Turner2013). The recorded pattern of inclination and declination can therefore serve as valuable chronostratigraphic indicators. For the semi-arid regions of Mongolia, we recently proposed a dual chronological approach in the high-altitude Shireet Naiman Nuur (Nuur = lake) sediments (46°31'55.04"N, 101°49'16.23"E; Khangai Mountains, central Mongolia), where we (1) established a high-resolution 14C-chronology for the past 7.4 cal. ka BP by dating terrestrial macrofossils and (2) corroborated the 14C-based chronology by a newly obtained PSV record from the lake (Bliedtner et al. Reference Bliedtner, Strobel, Struck, Salazar, Szidat, Nowaczyk, Bazarradnaa, Lloren, Dubois, Haberzettl and Zech2022). The PSV record from Shireet Naiman Nuur very well confirms our 14C-based chronology and provides a valuable regional master record for using PSV stratigraphy in semi-arid Mongolia to evaluate and potentially refine 14C-chronologies when compared to our record. Therefore, if successful, the combination of 14C-dating and corroboration by PSV data is a valuable chronological approach to establish more reliable chronologies in semi-arid regions, especially regarding the large age uncertainties of bulk organic carbon dating often has in such regions.

Here we present a newly obtained PSV record from the high-altitude Khar Nuur in the Mongolian Altai Mountains. As in this case PSV data do not corroborate the existing good age control published by Bliedtner et al. (Reference Bliedtner, Struck, Strobel, Salazar, Szidat, Bazarradnaa, Llore, Dubois and Zech2021), we aim to detect causes for age offsets and establish a reliable continuous inclination and declination record for the last 4.2 cal. ka BP from the lake.

MATERIAL AND METHODS

Study Area

Khar Nuur is of para-glacial origin and situated at high-altitude (2486 m a.s.l.) in the Mongolian Altai (48°37'22.9"N, 88°56'42.5"E; Figure 1). The lake was previously described in detail by Strobel et al. (Reference Strobel, Struck, Zech and Bliedtner2021, Reference Strobel, Struck, Bazarradnaa, Zech, Zech and Bliedtner2022). The endorheic Khar Nuur basin was formed during the Last Glacial Maximum by glacial advances from the Tsengel Khairkhan Massif, leaving prominent moraine lobes in the main valley (Walther et al. Reference Walther, Dashtseren, Kamp, Temujin, Meixner, Pan and Gansukh2017). The lake has a small hydrological catchment (44.8 km2) with quite steep slopes, which are mostly composed of friable black clay shales and granitic moraine deposits. Due to the continental position of Khar Nuur, mean annual temperatures and precipitation are low with −2.4 ± 0.7°C and 145 ± 35 mm, respectively (station Tolbo sum; period 2009–2019; DWD Climate Data Center 2020). Moreover, the lake is ice-covered for 8–9 months per year (2016–2019; Planet Team 2017).

Figure 1 Overview of semi-arid Mongolia located in central Asia. The investigated site at Khar Nuur (KN) in the Mongolian Altai Mountains is indicated by the yellow star and the regional comparison record from Shireet Naiman Nuur (SNN) (Bliedtner et al. Reference Bliedtner, Strobel, Struck, Salazar, Szidat, Nowaczyk, Bazarradnaa, Lloren, Dubois, Haberzettl and Zech2022) in the Mongolian Khangai Mountains is indicated by the white star. (Please see online version for color figures.)

Chronostratigraphy of the Khar Nuur Sediments

The investigated lake sediments of Khar Nuur and its chronostratigraphy were previously described in detail by Bliedtner et al. (Reference Bliedtner, Struck, Strobel, Salazar, Szidat, Bazarradnaa, Llore, Dubois and Zech2021). The 141-cm-long sediment core from Khar Nuur consists of well laminated silty sediments, which are characterized by alternating phases of increased lake primary productivity in the brown and blackish dark sediments and reduced productivity in the bluish-gray sediments (Figure 2). The chronology is based on 14C-datings of 12 bulk organic carbon samples, 8 aquatic macrofossil samples and 1 ostracod sample. Additionally, we accounted for possible terrestrial reservoir and hardwater effects by 14C-dating a surface sediment bulk organic carbon sample and one modern water plant at the coring location. 14C-analyses were carried out at the Laboratory for the Analysis of Radiocarbon with AMS (LARA AMS) of the University of Bern, Switzerland (Szidat Reference Szidat, Salazar, Vogel, Battaglia, Wacker, Synal and Türler2014) using a MIni CArbon DAting System (MICADAS) AMS coupled online to an Elementar Analyzer (Ruff et al. Reference Ruff, Fahrni, Gäggeler, Hajdas, Suter, Synal, Szidat and Wacker2010; Wacker et al. Reference Wacker, Bonani, Friedrich, Hajdas, Kromer, Němec, Ruff, Suter, Synal and Vockenhuber2010). Results were reported as fraction modern (F14C) and corrected for cross and constant contamination after the contamination drift model of Salazar et al. (Reference Salazar, Zhang, Agrios and Szidat2015). Resulting 14C-ages were calibrated with the IntCal20 calibration curve (Reimer et al. Reference Reimer, Austin, Bard, Bayliss, Blackwell and Bronk Ramsey2020) using OxCal (Bronk Ramsey Reference Bronk Ramsey2009), except the surface sediment bulk organic carbon and modern water plant 14C-age, which were calibrated with the bomb 13 NH1 calibration curve (Hua et al. Reference Hua, Barbetti and Rakowski2013) likewise using OxCal.

Figure 2 Chronostratigraphy of the Khar Nuur sediments previously published by Bliedtner et al. (Reference Bliedtner, Struck, Strobel, Salazar, Szidat, Bazarradnaa, Llore, Dubois and Zech2021). Inclination, declination, maximum angular deviation (MAD), median destructive field (MDF) and natural remanent magnetization (NRM) of the Khar Nuur sediments.

All 14C results can be found in the Supplementary Table S1. 14C-dating of the surface sediment gave a slight terrestrial pre-aging with a mean 14C-age of 129 ± 85 cal. BP (age range: −7 to 279 cal. BP [95.4%]). However, no hardwater effect was presently indicated by modern 14C-ages of the modern water plant (Strobel et al. Reference Strobel, Struck, Zech and Bliedtner2021; Bliedtner et al. Reference Bliedtner, Strobel, Struck, Salazar, Szidat, Nowaczyk, Bazarradnaa, Lloren, Dubois, Haberzettl and Zech2022). Based on the 14C-ages, a chronology was established for the Khar Nuur sediments by Bayesian age-depth modeling using the Bacon 2.3.4 package in R (Blaauw and Christen Reference Blaauw and Christen2011). During Bayesian age-depth modeling, the slight terrestrial pre-aging indicated by the surface sediment bulk organic carbon sample was subtracted from all conventional bulk organic carbon 14C-ages. Bayesian age-depth modeling gave a modeled basal median age of 4.2 +0.4/−0.3 cal. ka BP with all aquatic macrofossil 14C-ages being in stratigraphic position, likely indicating the timing of sediment deposition (Figure 2). Terrestrial pre-aging corrected bulk organic carbon 14C-ages very well correspond to the aquatic macrofossil 14C-ages, except for four ages at 90, 40, 30, and 20 cm sediment depth, which were pre-aged and overestimated their timing of deposition. Those samples contain an erosive signal from aged terrestrial organic carbon in the catchment soils and we therefore excluded them from Bayesian age-depth modeling (Figure 2).

Paleomagnetic Measurements

Natural remanent magnetization (NRM) was continuously measured at 1-cm intervals on a u-channel from the Khar Nuur sediment core with a 2G Enterprise DC-4K liquid helium-free magnetometer at the GFZ Potsdam. NRM was measured using stepwise (11 steps) alternating field (AF) demagnetization with peak AFs of 0, 5, 10, 15, 20, 30, 40, 50, 65, 80, and 100 mT. Inclination and declination of the characteristic remanent magnetization and maximum angular deviation (MAD) were derived from principal component analyses (Kirschvink Reference Kirschvink1980). The median destructive field (MDF) was also calculated. We have to note that declination data are relative and centered to 0 because the azimuth could not be controlled during coring. Because of the width of the response function of the SQUID sensors (∼7.8 cm), some smoothing occurs in the data. In order to eliminate edge effects, the upper and lowermost 5 cm are plotted in gray.

RESULTS

NRM intensities range from 0.6 to 17.6 mA m–1 in the Khar Nuur sediments and MDF values from 28.5 to only 51.7 mT at the very top of the sediment core (Figure 2), indicating a low coercivity mineral such as magnetite as carrier of the natural remanent magnetization. Well preservation and stable single-component magnetization of the sediments is indicated by low MAD values (Stoner and St-Onge Reference Stoner and St-Onge2007) below 5.6°. Orthogonal vector plots confirm stable single-component magnetizations, which trend to the origin during AF treatments (see Supplementary Figure SI 1). Distinct changes are shown by the declination and inclination pattern throughout the sediment core. Declination has a wide relative range from −53 to 23° and stretches over 76°. Inclination ranges from −3.3 to 62.6°, however, especially inclination seem to be offset in the uppermost part of the sediment core due to disturbed sediment and we therefore plotted the PSV pattern as a dotted gray line there. By excluding the potentially reworked uppermost part of the sediment core, inclination narrows and ranges from 40.6 to 62.6° (Figure 2). Compared to the expected inclination derived from the geocentric axial dipole model (GAD = 66.22°), inclination in the Khar Nuur sediments is flattened and did not intersect with the expected one for the latitude of this site. This has repeatedly been noticed in lake sediments and attributed to postdepositional compaction processes or compaction during coring (Tauxe et al. Reference Tauxe, Kodama and Kent2008; Henkel et al. Reference Henkel, Haberzettl, St-Onge, Wang, Ahlborn, Daut, Zhu and Mäusbacher2016).

DISCUSSION

Distinct changes in inclination during the past 4.2 cal. ka BP in the Khar Nuur sediments are similar to the regional reference record from Shireet Naiman Nuur (Bliedtner et al. Reference Bliedtner, Strobel, Struck, Salazar, Szidat, Nowaczyk, Bazarradnaa, Lloren, Dubois, Haberzettl and Zech2022) and various outputs of spherical harmonic geomagnetic field models (see Supplementary Figure SI 2 for comparison with different models, exemplarily shown here is the HFM.OL1.A1 model by Constable et al. [Reference Constable, Korte and Panovska2016]; Figure 3A). Despite the similarities in inclination, the Khar Nuur inclination pattern appears to have a temporal offset of 730 ± 90 yr. An adjusted Khar Nuur chronology of ∼730 yr, i.e., where we subtracted ∼730 yr from the original 14C-chronology, corresponds very well to the Shireet Naiman Nuur reference record and geomagnetic field model, now also temporally resembling their pattern (Figure 3A). Declination also shows no similarities to the regional reference and model pattern without an adjustment of the Khar Nuur 14C-chronology for ∼730 yr (Figure 3B). However, also with an adjustment, similarities are not obvious. Less similarities between declination records have also been reported from lakes from the Tibetan Plateau (Haberzettl et al. Reference Haberzettl, Henkel, Kasper, Ahlborn, Su, Wang, Appel, St-Onge, Stoner, Daut, Zhu and Mäusbacher2015). Moreover, it has often been reported that unwanted and unknown core rotation could largely affect the declination pattern (Nilsson et al. Reference Nilsson, Suttie and Hill2018), which might explain the observed differences in the Khar Nuur sediment core. However, if the large shift in declination at 50 cm sediment depth stretching over ∼50° is attributed to core rotation and hence neglected, some similarities in small scale variations can be observed between Khar Nuur and the HFM.OL1.A1 model. Unfortunately, these small-scale declination changes are missing in the Shireet Naiman Nuur sediments which might be explained by the lower sedimentation rates of the Shireet Naiman Nuur sediments (Ohlendorf et al. Reference Ohlendorf, Fey, Massaferro, Haberzettl, Laprida, Lücke, Maidana, Mayr, Oehlerich and Ramón Mercau2014).

Figure 3 Comparison of (A) inclination and (B) declination pattern of the Khar Nuur sediments with the regional reference sediments from Shireet Naiman Nuur (Bliedtner et al. Reference Bliedtner, Strobel, Struck, Salazar, Szidat, Nowaczyk, Bazarradnaa, Lloren, Dubois, Haberzettl and Zech2022) and the spherical harmonic geomagnetic field model HFM.OL1.A1 (Constable et al. Reference Constable, Korte and Panovska2016).

The ∼730-yr offset in inclination at Khar Nuur could be explained by remaining reservoir effects in the bulk organic carbon and aquatic macrofossil 14C-ages, potentially biasing the 14C-based chronology. However, we have good indications that reservoir effects, i.e., from terrestrial pre-aging and hardwater effects, are negligible in the Khar Nuur sediments. While we corrected the bulk organic carbon 14C-ages for a slight terrestrial pre-aging using a surface sediment sample from the coring location with a 14C-age of 129 ± 85 cal. BP (age range: −7 to 279 cal. BP [95.4%]), no hardwater effects were found by modern 14C-ages of a modern water plant at the coring location (Bliedtner et al. Reference Bliedtner, Struck, Strobel, Salazar, Szidat, Bazarradnaa, Llore, Dubois and Zech2021; Strobel et al. Reference Strobel, Struck, Zech and Bliedtner2021). Although reservoir effects are not recently present in the surface sediments of Khar Nuur, they can still variably occur through time. However, the very good agreement of the bulk organic carbon and aquatic macrofossil 14C-ages questions variable reservoir effects, especially since the bulk organic carbon 14C-ages, corrected for terrestrial pre-aging, should include hardwater effects to a lesser degree than the aquatic macrofossils and would therefore be younger. Moreover, the bulk organic carbon and aquatic macrofossil 14C-age at 10 cm sediment depth gave younger modeled 14C-ages (0.6 ± 0.3 and 0.6 +0.3/-0.2 cal. ka BP) than the observed offset of ∼730 yr in inclination (Bliedtner et al. Reference Bliedtner, Struck, Strobel, Salazar, Szidat, Bazarradnaa, Llore, Dubois and Zech2021), further providing evidence for non-existing reservoir effects. Ultimately, a constant reservoir effect of ∼730 yr over time, especially a constant hardwater effect, is rather unlikely for the Khar Nuur sediments. In the carbonate-free Khar Nuur catchment only the incorporation of bicarbonate (HCO3 ) could provide old carbonate for potential hardwater effects (Strobel et al. Reference Strobel, Struck, Zech and Bliedtner2021). However, distinct lake primary productivity changes occur in the Khar Nuur sediments, which are related to changes in growing season temperature and the duration of ice cover (Bliedtner et al. Reference Bliedtner, Struck, Strobel, Salazar, Szidat, Bazarradnaa, Llore, Dubois and Zech2021). Especially changes in the duration of ice coverage would result in a variable hardwater effect due to increased/reduced exchange with atmospheric 14CO2 and the reduced/increased incorporation of H14CO3 (i.e., old carbon), respectively. Since the ∼730-yr offset in inclination is constant throughout the Khar Nuur sediments, a bias from remaining variable reservoir effects, and especially from hard water effects, is therefore very unlikely as this would have caused unpredictable offsets between the individual inclination highs and lows in the compared records after the adjustment of ∼730 yr. Therefore, the 14C-based chronology provides a robust age control.

A more likely explanation for the observed age offset of ∼730 yr at Khar Nuur might be that magnetic particles become finally locked-in several centimeters below the sediment-water interface, which is the so-called “lock-in depth” (Roberts and Winklhofer Reference Roberts and Winklhofer2004; Mellström et al. Reference Mellström, Nilsson, Stanton, Muscheler, Snowball and Suttie2015). It has been proposed that magnetic particles can re-align to the geomagnetic field after deposition during dewatering and compaction, incorporating a post-depositional remanent magnetization (pDRM) signal which can lead to a delay and smoothing of the recorded geomagnetic signal (Roberts and Winklhofer Reference Roberts and Winklhofer2004; Nilsson et al. Reference Nilsson, Suttie and Hill2018). Although the underlying physical processes are poorly understood, pDRM is thought to mostly depend on water content, grain size, magnetic concentration, sedimentation rate and/or bioturbation (Tauxe et al. Reference Tauxe, Steindorf and Harris2006; Roberts et al. Reference Roberts, Tauxe and Heslop2013; Zhao et al. Reference Zhao, Egli, Gilder and Müller2016; Valet et al. Reference Valet, Tanty and Carlut2017). Evidence for lock-in depths in lacustrine environments is mostly from varved sediments so far, but lock-in depths up to several decimeters below the sediment-water-interface were repeatedly reported, leading to centennial to millennial delays of the geomagnetic signal (e.g., Stockhausen Reference Stockhausen1998; Snowball et al. Reference Snowball, Mellström, Ahlstrand, Haltia, Nilsson, Ning, Muscheler and Brauer2013; Mellström et al. Reference Mellström, Nilsson, Stanton, Muscheler, Snowball and Suttie2015; Scheidt et al. Reference Scheidt, Lenz, Egli, Brill, Klug, Fabian, Lenz, Gromig, Rethemeyer, Wagner, Federov and Melles2022). Considering the relatively constant sedimentation rate at Khar Nuur (Figure 2), a lock-in depth of 26 ± 2 cm would very likely explain the constant 730 ± 90 year offset in PSV.

To finally confirm that the observed age offset of 730 ± 90 yr in PSV at Khar Nuur is indeed attributed to a lock-in depth of 26 ± 2 cm and not to potential reservoir effects, we compare paleoclimatological proxies from the Khar Nuur sediments with those from the well-dated Shireet Naiman Nuur sediments (Bliedtner et al. Reference Bliedtner, Strobel, Struck, Salazar, Szidat, Nowaczyk, Bazarradnaa, Lloren, Dubois, Haberzettl and Zech2022; see Figure 1 for location). Log ratio of calcium and titanium (log Ca/Ti) and center log ratios of Ti (Ticlr) are therefore plotted on both the 14C-based chronology and a ∼730-yr adjusted chronology of Khar Nuur (Figure 4). Although the sample resolution slightly differs between Khar Nuur and Shireet Naiman Nuur, both lakes are ideal for direct comparison since they are located at high-altitudes (∼2400 m a.s.l.) and have comparable environmental settings and therefore very likely respond to identical forcing mechanisms. Changes in log (Ca/Ti) are interpreted as changes in lake primary productivity controlled by growing season temperatures in both lakes, whereas Ticlr indicates terrigenous minerogenic input (Bliedtner et al. Reference Bliedtner, Struck, Strobel, Salazar, Szidat, Bazarradnaa, Llore, Dubois and Zech2021; Bliedtner et al. Reference Bliedtner, Strobel, Struck, Salazar, Szidat, Nowaczyk, Bazarradnaa, Lloren, Dubois, Haberzettl and Zech2022). Although similarities can be found between the paleoclimatological proxies of Shireet Naiman Nuur and paleoclimatological proxies from Khar Nuur plotted on both, the 14C-based and ∼730 year adjusted chronology of Khar Nuur, a better fit is obvious between Shireet Naiman Nuur and the 14C-based chronology of Khar Nuur (Figure 4). Despite some differences in the magnitude, distinct changes in lake primary productivity and terrigenous input occur at ∼4.1, ∼3, and ∼1.8 cal. ka BP. Between those distinct changes, productivity and terrigenous input follow similar characteristic trends (Figure 4). It is notable that slight temporal offsets in the order of 10–100 yr exist between Shireet Naiman Nuur and the 14C-based chronology of Khar Nuur, but those offsets are well within the 2σ uncertainty of the chronologies of both records (Figure 4). Moreover, differences in the sedimentological proxies during the last ∼1.5 cal. ka BP could exist due to increased sediment erosion and relocation in the Khar Nuur catchment, potentially climatically and/or anthropogenically induced. This is also supported by the pre-aged bulk organic carbon 14C-ages in the sediments from ∼45 to 20 cm of the core, overestimating their true burial age due to longer residence times in the catchment soils which were hence removed from age-depth-modeling as extensively discussed by Bliedtner et al. (Reference Bliedtner, Struck, Strobel, Salazar, Szidat, Bazarradnaa, Llore, Dubois and Zech2021) (Figure 2).

Figure 4 Comparison of the sedimentological proxies log (Ca/Ti) and center log-ratio Ti (Ticlr) from Khar Nuur and Shireet Naiman Nuur (Bliedtner et al. Reference Bliedtner, Strobel, Struck, Salazar, Szidat, Nowaczyk, Bazarradnaa, Lloren, Dubois, Haberzettl and Zech2022). Sedimentological proxies from Khar Nuur are shown both on the 14C-based chronology and the adjusted chronology for ∼730 yr (transparent curve). Please note that the black lines of the inorganic elements at Khar Nuur refers to a 2-point running and the black lines for the inorganic elements at Shireet Naiman Nuur refers to a 5-point running mean to create a comparable data resolution of 1 cm. Reddish (bluish) bars indicate periods of higher (lower) growing season temperature at Khar Nuur and Shireet Naiman Nuur. The timespan from 1.5 cal. ka BP until present is separated by the dashed black line since climatically and/or anthropogenically induced sediment erosion and relocation took place in the Khar Nuur catchment during this time.

Because of the very consistent trend of log (Ca/Ti) in the Khar Nuur and Shireet Naiman Nuur sediments, some paleoclimate interpretations can finally be made. Changes in log (Ca/Ti) have previously been interpreted in terms of changes in lake primary productivity primarily determined by growing season temperatures in those high-altitude lakes (Bliedtner et al. Reference Bliedtner, Struck, Strobel, Salazar, Szidat, Bazarradnaa, Llore, Dubois and Zech2021, Reference Bliedtner, Strobel, Struck, Salazar, Szidat, Nowaczyk, Bazarradnaa, Lloren, Dubois, Haberzettl and Zech2022). This is because air temperature strongly controls the duration of ice-cover and the growing season of aquatic producers at high altitudes (Willemse and Törnqvist Reference Willemse and Törnqvist1999; Mischke et al. Reference Mischke, Rajabov, Mustaeva, Zhang, Herzschuh, Boomer, Brown, Andersen, Myrbo, Ito and Schudack2010). Higher growing season temperatures are indicated in both lakes from ∼4.2–4.0, 3.2–2.8 and 2.2–1.9 cal. ka BP (highlighted by reddish bars in Figure 4). In contrast, lower growing season temperatures occur from ∼4.0–3.2, 2.8–2.2, and 1.9–1.6 cal. ka BP (highlighted by bluish bars in Figure 4). Based on our well dated records from Khar Nuur and Shireet Naiman Nuur, a similar regional temperature evolution is suggested by the very good agreement of log (Ca/Ti) for the Altai Mountains (i.e., western Mongolia) and the Khangai Mountains (i.e., central Mongolia). Our results are further supported by previous regional studies, e.g., Bayan Nuur (Yang et al. Reference Yang, Ran and Sun2020) and Telmen Nuur (Struck et al. Reference Struck, Bliedtner, Strobel, Taylor, Biskop, Plessen, Klaes, Bittner, Jamsranjav and Salazar2022), who suggested total solar irradiance (TSI) as a main driver for temperature dynamics during the Late Holocene in the region, i.e., colder conditions during minima in TSI and warmer conditions during maxima in TSI.

CONCLUSIONS

Inclination pattern from Khar Nuur closely resembles those from the regional reference record from Shireet Naiman Nuur and the geomagnetic field models, however, with a constant offset of 730 ± 90 yr. We can exclude that the constant ∼730-yr offset is caused by reservoir effects from terrestrial pre-aging and hardwater effects because bulk organic carbon and aquatic macrofossil 14C-ages very well agree with each other, almost no modern reservoir effect was indicated by surficial sediment dating and dating a modern water plant, and the uppermost 14C-datings at 10-cm sediment depth gave younger ages than the offset of ∼730 yr in inclination. Instead, an almost constant lock-in depth of 26 ± 2 cm below the sediment-water-interface very well explains the observed constant 730 ± 90 yr offset in the PSV pattern at Khar Nuur. This is further supported by comparison of paleoclimatological proxies from Khar Nuur with Shireet Naiman Nuur, both high-altitude lakes with comparable environmental settings, where obvious similarities in log (Ca/Ti) and Ticlr exist between Shireet Naiman Nuur and the 14C-based chronology of Khar Nuur.

We emphasize the importance of the potential lock-in of magnetic particles several centimeters below the sediment-water-interface for future studies since the lock-in depth can complicate the estimation of potential reservoir effects and finally challenge the refinement of 14C-based chronologies. Nevertheless, PSV will give an additional chronological indicator, and our combined approach will largely help to improve and potentially refine chronologies in semi-arid regions.

SUPPLEMENTARY MATERIAL

To view supplementary material for this article, please visit https://doi.org/10.1017/RDC.2023.38

ACKNOWLEDGMENTS

We would like to thank the Ernst Abbe Stiftung for financial support of the field trip to Mongolia and sediment retrieval. We further thank our logistic partners in Mongolia for their support during fieldwork. We thank two reviewers for their valuable and helpful comments on this paper.

AUTHOR CONTRIBUTIONS

Marcel Bliedtner: conceptualization, formal analysis, investigation, writing—original draft, writing—review and editing; Torsten Haberzettl: conceptualization, investigation, writing—review and editing; Norbert Nowaczyk: investigation, writing—review and editing; Enkhtuya Bazarradnaa: writing—review and editing; Roland Zech: writing—review and editing; Paul Strobel: conceptualization, investigation, writing—review and editing.

Footnotes

Selected Papers from the 24th Radiocarbon and 10th Radiocarbon & Archaeology International Conferences, Zurich, Switzerland, 11–16 Sept. 2022

References

REFERENCES

Barletta, F, St-Onge, G, Channell, J, Rochon, A. 2010. Dating of Holocene western Canadian Arctic sediments by matching paleomagnetic secular variation to a geomagnetic field model. Quaternary Science Reviews 29(17–18):23152324. doi: 10.1016/j.quascirev.2010.05.035 CrossRefGoogle Scholar
Blaauw, M, Christen, JA. 2011. Flexible paleoclimate age-depth models using an autoregressive gamma process. Bayesian Analyses 6(3):457474. doi: 10.1214/11-BA618 CrossRefGoogle Scholar
Bliedtner, M, Strobel, P, Struck, J, Salazar, G, Szidat, S, Nowaczyk, N, Bazarradnaa, E, Lloren, R, Dubois, N, Haberzettl, T, Zech, R. 2022. Holocene temperature variations in semi-arid central Mongolia—a chronological and sedimentological perspective from a 7400-year lake sediment record from the Khangai Mountains. Frontiers in Earth Science 10. doi: 10.3389/feart.2022.910782 CrossRefGoogle Scholar
Bliedtner, M, Struck, J, Strobel, P, Salazar, G, Szidat, S, Bazarradnaa, E, Llore, R, Dubois, N, Zech, R. 2021. Late Holocene climate changes in the Altai region based on a first high-resolution biomarker isotope record from Lake Khar Nuur. Geophysical Research Letters 48(20). doi: 10.1029/2021GL094299 CrossRefGoogle Scholar
Bronk Ramsey, C. 2009. Bayesian analysis of radiocarbon dates. Radiocarbon 51:337360. doi: 10.1017/S0033822200033865 CrossRefGoogle Scholar
Constable, C, Korte, M, Panovska, S. 2016. Persistent high paleosecular variation activity in southern hemisphere for at least 10 000 years. Earth and Planetary Science Letters 453: 7886. doi: 10.1016/j.epsl.2016.08.015 CrossRefGoogle Scholar
Douglas, PMJ, Pagani, M, Eglinton, TI, Brenner, M, Curtis, JH, Breckenridge, A, Johnston, K. 2018. A long-term decrease in the persistence of soil carbon caused by ancient Maya land use. Nature Geoscience 5:81. doi: 10.1038/s41561-018-0192-7 Google Scholar
Gierga, M, Hajdas, I, van Raden, UJ, Gilli, A, Wacker, L, Sturm, M, Bernasconi, SM, Smittenberg, RH. 2016. Long-stored soil carbon released by prehistoric land use: evidence from compoundspecific radiocarbon analysis on Soppensee lake sediments. Quaternary Science Reviews 144:123131. doi: 10.1016/j.quascirev.2016.05.011 CrossRefGoogle Scholar
Haas, M, Baumann, F, Castella, D, Haghipour, N, Reusch, A, Strasser, M, Eglinton, TI, Dubois, N. 2019. Roman-driven cultural eutrophication of Lake Murten, Switzerland. Earth and Planetary Science Letters 505:110117. doi: 10.1016/j.epsl.2018.10.027 CrossRefGoogle Scholar
Haberzettl, T, Henkel, K, Kasper, T, Ahlborn, M, Su, Y, Wang, J, Appel, E, St-Onge, G, Stoner, J, Daut, G, Zhu, L, Mäusbacher, R. 2015. Independently dated paleomagnetic secular variation records from the Tibetan Plateau. Earth and Planetary Science Letters 416:98108. doi: 10.1016/j.epsl.2015.02.007 CrossRefGoogle Scholar
Haberzettl, T, Kasper, T, Stoner, JS, Rahobisoa, JJ, Daut, G. 2021. Extending and refining the paleomagnetic secular variation database for south-eastern Africa (Madagascar) to 2500 cal BP. Earth and Planetary Science Letters 565: 116931. doi: 10.1016/j.epsl.2021.116931 CrossRefGoogle Scholar
Haberzettl, T, Kirsten, KL, Kasper, T, Franz, S, Reinwarth, B, Baade, J, Daut, G, Meadows, ME, Su, Y, Mäusbacher, R. 2019. Using 210Pb-data and paleomagnetic secular variations to date anthropogenic impact on a lake system in the Western Cape, South Africa. Quaternary Geochronology 51:5363. doi: 10.1016/j.quageo.2018.12.004 CrossRefGoogle Scholar
Haberzettl, T, St-Onge, G, Behling, H, Kirleis, W. 2013. Evaluating Late Holocene radiocarbon-based chronologies by matching palaeomagnetic secular variations to geomagnetic field models: an example from Lake Kalimpaa (Sulawesi, Indonesia). Geological Society, London, Special Publications 373(1):245259. doi: 10.1144/SP373.10 CrossRefGoogle Scholar
Hajdas, I, Bonani, G, Goślar, T. 1995. Radiocarbon dating the Holocene in the Gościąż Lake floating varve chronology. Radiocarbon 37(1):7174. doi: 10.1017/S0033822200014806 CrossRefGoogle Scholar
Henkel, K, Haberzettl, T, St-Onge, G, Wang, J, Ahlborn, M, Daut, G, Zhu, L, Mäusbacher, R. 2016. High-resolution paleomagnetic and sedimentological investigations on the Tibetan Plateau for the past 16 ka cal B.P.—the Tangra Yumco record. Geochemistry, Geophysics, Geosystems 17(3):774790. doi: 10.1002/2015GC006023 CrossRefGoogle Scholar
Hua, Q, Barbetti, M, Rakowski, AZ. 2013. Atmospheric radiocarbon for the period 1950–2010. Radiocarbon 55(4):20592072. doi: 10.2458/azu_js_rc.v55i2.16177 CrossRefGoogle Scholar
Kirschvink, JL. 1980. The least-squares line and plane and the analysis of palaeomagnetic data. Geophysical Journal International 62(3):699718. doi: 10.1111/j.1365-246X.1980.tb02601.x CrossRefGoogle Scholar
Mellström, A, Nilsson, A, Stanton, T, Muscheler, R, Snowball, I, Suttie, N. 2015. Post-depositional remanent magnetization lock-in depth in precisely dated varved sediments assessed by archaeomagnetic field models. Earth and Planetary Science Letters 410:186196. doi: 10.1016/j.epsl.2014.11.016 CrossRefGoogle Scholar
Merrill, RT, McFadden, PL. 2007. Paleomagnetism. In: Gubbins, D, Herrero-Bervera, E, editors. Encyclopedia of geomagnetism and pleomagnetism. Dordrecht: Springer Netherlands. p. 776780.CrossRefGoogle Scholar
Mischke, S, Rajabov, I, Mustaeva, N, Zhang, C, Herzschuh, U, Boomer, I, Brown, ET, Andersen, N, Myrbo, A, Ito, E, Schudack, ME. 2010. Modern hydrology and late Holocene history of Lake Karakul, eastern Pamirs (Tajikistan): a reconnaissance study. Palaeogeography, Palaeoclimatology, Palaeoecology 289(1–4):1024. doi: 10.1016/j.palaeo.2010.02.004 CrossRefGoogle Scholar
Nilsson, A, Suttie, N, Hill, MJ. 2018. Short-term magnetic field variations from the post-depositional remanence of lake sediments. Frontiers in Earth Science 6. doi: 10.3389/feart.2018.00039 CrossRefGoogle Scholar
Ohlendorf, C, Fey, M, Massaferro, J, Haberzettl, T, Laprida, C, Lücke, A, Maidana, N, Mayr, C, Oehlerich, M, Ramón Mercau, J, et al. 2014. Late Holocene hydrology inferred from lacustrine sediments of Laguna Cháltel (southeastern Argentina). Palaeogeography, Palaeoclimatology, Palaeoecology 411:229248. doi: 10.1016/j.palaeo.2014.06.030.CrossRefGoogle Scholar
Ólafsdóttir, S, Geirsdóttir, Á, Miller, GH, Stoner, JS, Channell, JE. 2013. Synchronizing Holocene lacustrine and marine sediment records using paleomagnetic secular variation. Geology 41(5):535538. doi: 10.1130/G33946.1 CrossRefGoogle Scholar
Reimer, PJ, Austin, WEN, Bard, E, Bayliss, A, Blackwell, PG, Bronk Ramsey, C, et al. 2020. The IntCal20 Northern Hemisphere radiocarbon age calibration curve (0–55 cal kBP). Radiocarbon 62:725757. doi: 10.1017/RDC.2020.41 CrossRefGoogle Scholar
Reinwarth, B, Franz, S, Baade, J, Haberzettl, T, Kasper, T, Daut, G, Helmschrot, J, Kirsten, KL, Quick, LJ, Meadows, ME, Mäusbacher, R. 2013. A 700-year record on the effects of climate and human impact on the southern cape coast inferred from lake sediments of Eilandvlei, Wilderness embayment, South Africa. Geografiska Annaler: Series A, Physical Geography 95(4):345360. doi: 10.1111/geoa.12015 CrossRefGoogle Scholar
Roberts, AP, Tauxe, L, Heslop, D. 2013. Magnetic paleointensity stratigraphy and high-resolution Quaternary geochronology: successes and future challenges. Quaternary Science Reviews 61:116. doi: 10.1016/j.quascirev.2012.10.036 CrossRefGoogle Scholar
Roberts, AP, Turner, G.M. 2013. Geomagnetic excursions and secular variations. In: Encyclopedia of Quaternary Science. Elsevier. p. 705720.CrossRefGoogle Scholar
Roberts, AP, Winklhofer, M. 2004. Why are geomagnetic excursions not always recorded in sediments? Constraints from post-depositional remanent magnetization lock-in modelling. Earth and Planetary Science Letters 227(3–4):345359. doi: 10.1016/j.epsl.2004.07.040 CrossRefGoogle Scholar
Ruff, M, Fahrni, S, Gäggeler, HW, Hajdas, I, Suter, M, Synal, H-A, Szidat, S, Wacker, L. 2010. On-line radiocarbon measurements of small samples using Elemental Analyzer and MICADAS gas ion source. Radiocarbon 52:16451656. doi: 10.1017/S003382220005637X CrossRefGoogle Scholar
Rudaya, N, Nazarova, L, Frolova, L, Palagushkina, O, Soenov, V, Cao, X, Syrykh, L, Grekov, I, Otgonbayar, D, Bayarkhuu, B. 2021. The link between climate change and biodiversity of lacustrine inhabitants and terrestrial plant communities of the Uvs Nuur Basin (Mongolia) during the last three millennia. Holocene 31(9):14431458. doi: 10.1177/09596836211019093.CrossRefGoogle Scholar
Salazar, G, Zhang, YL, Agrios, K, Szidat, S. 2015. Development of a method for fast and automatic radiocarbon measurement of aerosol samples by online coupling of an Elemental Analyzer with a MICADAS AMS. Nuclear Instruments and Methods in Physics Research B 361:163167. doi: 10.1016/j.nimb.2015.03.051 CrossRefGoogle Scholar
Scheidt, S, Lenz, M, Egli, R, Brill, D, Klug, M, Fabian, K, Lenz, MM, Gromig, R, Rethemeyer, J, Wagner, B, Federov, G, Melles, M. 2022. A 62 kyr geomagnetic palaeointensity record from the Taymyr Peninsula, Russian Arctic. Geochronology 4(1):87107. doi: 10.5194/gchron-4-87-2022 CrossRefGoogle Scholar
Snowball, I, Mellström, A, Ahlstrand, E, Haltia, E, Nilsson, A, Ning, W, Muscheler, R, Brauer, A. 2013. An estimate of post-depositional remanent magnetization lock-in depth in organic rich varved lake sediments. Global and Planetary Change 110:264277. doi: 10.1016/j.gloplacha.2013.10.005# CrossRefGoogle Scholar
Stockhausen, H. 1998. Geomagnetic palaeosecular variation (0–13 000 yr BP) as recorded in sediments from three maar lakes from the West Eifel (Germany). Geophysical Journal International 135(3):898910. doi: 10.1046/j.1365-246X.1998.00664.x CrossRefGoogle Scholar
Stoner, JS, St-Onge, G. 2007. Chapter three magnetic stratigraphy in paleoceanography: reversals, excursions, paleointensity, and secular variation. Developments in Marine Geology 1:99138.CrossRefGoogle Scholar
Strobel, P, Struck, J, Bazarradnaa, E, Zech, M, Zech, R, Bliedtner, M. 2022. Precipitation and lake water evaporation recorded by terrestrial and aquatic n-alkane δ 2 H isotopes in Lake Khar Nuur, Mongolia. Geochemistry, Geophysics, Geosystems 23(2). doi: 10.1029/2021GC010234 CrossRefGoogle Scholar
Strobel, P, Struck, J, Zech, R, Bliedtner, M. 2021. The spatial distribution of sedimentary compounds and their environmental implications in surface sediments of Lake Khar Nuur (Mongolian Altai). Earth Surface Processes Landforms 46(3):611625. doi: 10.1002/esp.5049 CrossRefGoogle Scholar
Struck, J, Bliedtner, M, Strobel, P, Taylor, W, Biskop, S, Plessen, B, Klaes, B, Bittner, L, Jamsranjav, B, Salazar, G, et al. 2022. Central Mongolian lake sediments reveal new insights on climate change and equestrian empires in the Eastern Steppes. Scientific Reports 12(1). doi: 10.1038/s41598-02206659-w CrossRefGoogle ScholarPubMed
Sun, A, Feng, Z, Ran, M, Zhang, C. 2013. Pollen-recorded bioclimatic variations of the last ∼22,600 years retrieved from Achit Nuur core in the western Mongolian Plateau. Quaternary International 311:3643. doi: 10.1016/j.quaint.2013.07.002 CrossRefGoogle Scholar
Szidat, S, Salazar, GA, Vogel, E, Battaglia, M, Wacker, L, Synal, H-A, Türler, A. 2014. 14C analysis and sample preparation at the new Bern Laboratory for the Analysis of Radiocarbon with AMS (LARA). Radiocarbon 56:561566. doi: 10.2458/56.17457 CrossRefGoogle Scholar
Tauxe, L, Steindorf, JL, Harris, A. 2006. Depositional remanent magnetization: toward an improved theoretical and experimental foundation. Earth and Planetary Science Letters 244(3–4):515529. doi: 10.1016/j.epsl.2006.02.003 CrossRefGoogle Scholar
Tauxe, L, Kodama, KP, Kent, DV. 2008. Testing corrections for paleomagnetic inclination error in sedimentary rocks: a comparative approach. Physics of the Earth and Planetary Interiors 169:152165. doi: 10.1016/j.pepi.2008.05.006 CrossRefGoogle Scholar
Unkelbach, J, Kashima, K, Enters, D, Dulamsuren, C, Punsalpaamuu, G, Behling, H. 2019. Late Holocene (Meghalayan) palaeoenvironmental evolution inferred from multi-proxy-studies of lacustrine sediments from the Dayan Nuur region of Mongolia. Palaeogeography, Palaeoclimatology, Palaeoecology 530:114. doi: 10.1016/j.palaeo.2019.05.021 CrossRefGoogle Scholar
Valet, J-P, Tanty, C, Carlut, J. 2017. Detrital magnetization of laboratory-redeposited sediments. Geophysical Journal International 210(1):3441. doi: 10.1093/gji/ggx139 CrossRefGoogle Scholar
Wacker, L, Bonani, G, Friedrich, M, Hajdas, I, Kromer, B, Němec, M, Ruff, M, Suter, M, Synal, H-A, Vockenhuber, C. 2010. MICADAS: routine and high-precision radiocarbon dating. Radiocarbon 52:252262. doi: 10.1017/S0033822200045288 CrossRefGoogle Scholar
Walther, M, Dashtseren, A, Kamp, U, Temujin, K, Meixner, F, Pan, CG, Gansukh, Y. 2017. Glaciers, Permafrost and Lake Levels at the Tsengel Khairkhan Massif, Mongolian Altai, during the Late Pleistocene and Holocene. Geosciences 7(3):73. doi: 10.3390/geosciences7030073 CrossRefGoogle Scholar
Willemse, NW, Törnqvist, TE. 1999. Holocene century-scale temperature variability from west Greenland lake records. Geology 27(7):580584. doi: 10.1130/0091-7613(1999)027<0580:hcstvf>2.3.co;2 2.3.CO;2>CrossRefGoogle Scholar
Wündsch, M, Biagioni, S, Behling, H, Reinwarth, B, Franz, S, Bierbaß, P, Daut, G, Mäusbacher, R, Haberzettl, T. 2014. ENSO and monsoon variability during the past 1.5 kyr as reflected in sediments from Lake Kalimpaa, Central Sulawesi (Indonesia). Holocene 24(12):17431756. doi: 10.1177/0959683614551217 CrossRefGoogle Scholar
Yang, Y, Ran, M, Sun, A. 2020. Pollen-recorded bioclimatic variations of the last ∼2000 years retrieved from Bayan Nuur in the western Mongolian Plateau. Boreas 49(2):350362. doi: 10.1111/bor.12423 CrossRefGoogle Scholar
Zhao, X, Egli, R, Gilder, SA, Müller, S. 2016. Microbially assisted recording of the Earth’s magnetic 422 field in sediment. Nature Communications 7:10673. doi: 10.1038/ncomms10673 CrossRefGoogle Scholar
Figure 0

Figure 1 Overview of semi-arid Mongolia located in central Asia. The investigated site at Khar Nuur (KN) in the Mongolian Altai Mountains is indicated by the yellow star and the regional comparison record from Shireet Naiman Nuur (SNN) (Bliedtner et al. 2022) in the Mongolian Khangai Mountains is indicated by the white star. (Please see online version for color figures.)

Figure 1

Figure 2 Chronostratigraphy of the Khar Nuur sediments previously published by Bliedtner et al. (2021). Inclination, declination, maximum angular deviation (MAD), median destructive field (MDF) and natural remanent magnetization (NRM) of the Khar Nuur sediments.

Figure 2

Figure 3 Comparison of (A) inclination and (B) declination pattern of the Khar Nuur sediments with the regional reference sediments from Shireet Naiman Nuur (Bliedtner et al. 2022) and the spherical harmonic geomagnetic field model HFM.OL1.A1 (Constable et al. 2016).

Figure 3

Figure 4 Comparison of the sedimentological proxies log (Ca/Ti) and center log-ratio Ti (Ticlr) from Khar Nuur and Shireet Naiman Nuur (Bliedtner et al. 2022). Sedimentological proxies from Khar Nuur are shown both on the 14C-based chronology and the adjusted chronology for ∼730 yr (transparent curve). Please note that the black lines of the inorganic elements at Khar Nuur refers to a 2-point running and the black lines for the inorganic elements at Shireet Naiman Nuur refers to a 5-point running mean to create a comparable data resolution of 1 cm. Reddish (bluish) bars indicate periods of higher (lower) growing season temperature at Khar Nuur and Shireet Naiman Nuur. The timespan from 1.5 cal. ka BP until present is separated by the dashed black line since climatically and/or anthropogenically induced sediment erosion and relocation took place in the Khar Nuur catchment during this time.

Supplementary material: PDF

Bliedtner et al. supplementary material

Bliedtner et al. supplementary material 1

Download Bliedtner et al. supplementary material(PDF)
PDF 280 KB
Supplementary material: File

Bliedtner et al. supplementary material

Bliedtner et al. supplementary material 2

Download Bliedtner et al. supplementary material(File)
File 5.7 KB