Hostname: page-component-cd9895bd7-mkpzs Total loading time: 0 Render date: 2024-12-25T18:48:50.010Z Has data issue: false hasContentIssue false

Holocene hydroclimate and dust activity, as reconstructed from the sediments of Lake Bayanchagan, on the northern margin of the East Asian summer monsoon

Published online by Cambridge University Press:  18 October 2023

Wubiao Li
Affiliation:
Key Laboratory of Cenozoic Geology and Environment, Institute of Geology and Geophysics, Chinese Academy of Sciences, Beijing 100029, China College of Earth and Planetary Sciences, University of Chinese Academy of Sciences, Beijing 100049, China
Wenying Jiang*
Affiliation:
Key Laboratory of Cenozoic Geology and Environment, Institute of Geology and Geophysics, Chinese Academy of Sciences, Beijing 100029, China
Shiling Yang
Affiliation:
Key Laboratory of Cenozoic Geology and Environment, Institute of Geology and Geophysics, Chinese Academy of Sciences, Beijing 100029, China College of Earth and Planetary Sciences, University of Chinese Academy of Sciences, Beijing 100049, China
Jie Lin
Affiliation:
Key Laboratory of Cenozoic Geology and Environment, Institute of Geology and Geophysics, Chinese Academy of Sciences, Beijing 100029, China College of Earth and Planetary Sciences, University of Chinese Academy of Sciences, Beijing 100049, China
Yujie Wang
Affiliation:
Key Laboratory of Cenozoic Geology and Environment, Institute of Geology and Geophysics, Chinese Academy of Sciences, Beijing 100029, China College of Earth and Planetary Sciences, University of Chinese Academy of Sciences, Beijing 100049, China
*
Corresponding author: Wenying Jiang; Email: wjiang@mail.iggcas.ac.cn
Rights & Permissions [Opens in a new window]

Abstract

The sediments of closed-basin lakes on the margin of the East Asian summer monsoon (EASM) are valuable archives of past changes in hydroclimate and dust activity and thus potentially can help us to understand future climate changes. We present high-resolution, well-dated records of the grain size and carbonate mineralogy from Lake Bayanchagan, northern China, spanning the last 11.5 ka. Grain-size endmember (EM) analysis distinguished four EMs, each linked to different sediment transport processes. EM1 (0.4–0.6 μm) and EM3 (14–102 μm) reflect the strength of regional dust activity, whereas EM2 (1.3–31 μm) represents variations in local hydrodynamic conditions related to lake-level changes and EM4 (68–500 μm) is associated with local dust activity. Our results show that a high lake level and weakened dust activity occurred during 10–5.8 ka, as indicated by increased EM2 and decreased EM3, respectively. After 5.8 ka, EM2 decreased as the three other EMs increased, and dolomite appeared in the sediments while calcite decreased—indicating both a decline in lake level and strengthened dust activity. The fluctuations in lake level and dust activity are in good agreement with precipitation variations reconstructed from other records, which are in turn correlated to movement of the EASM rainfall belt, in response to temperature changes.

Type
Research Article
Copyright
Copyright © The Author(s), 2023. Published by Cambridge University Press on behalf of Quaternary Research Center

INTRODUCTION

Northern China is located in the transition between arid and subhumid climatic zones, within the arable–pastoral ecotone. Changes in hydroclimate, mainly controlled by the East Asian summer monsoon (EASM), present significant challenges to the management of freshwater resources and the food security of this region. Thus, the formulation of plans for domestic and agricultural water use and an assessment of the possible impacts of global climate change on the hydroclimate of northern China are urgently needed. Previous research has shown that increased global temperatures may lead to higher temperatures and drought events in northern China (Zhang et al., Reference Zhang, Jeong, Yoon, Kim, Wang, Linderholm, Fang, Wu and Chen2020), which would accelerate the drying of lakes. Evaporation from the lakes is estimated to increase by ~17.7% annually by the end of this century (Wang et al., Reference Wang, Lee, Xiao, Liu, Schultz, Wang, Zhang and Zhao2018). This scenario is consistent with the prediction of Held and Soden (Reference Held and Soden2006) that Earth's dry regions will experience intensifying droughts with ongoing global warming. However, others have argued that future temperature rises of 2–3°C in SE Asia could lead to a northward shift of the EASM rainfall belt and subsequent increased precipitation in northern China (Yang et al., Reference Yang, Ding, Li, Wang, Jiang and Huang2015; Huang et al., Reference Huang, Yang, Haywood, Jiang, Wang, Sun, Tang and Ding2021). Thus, the nature of the hydroclimatic response of northern China to ongoing global warming remains controversial.

The global mean temperature during the mid-Holocene, the most recent major warm period, was 0.7–2°C higher than today (Marcott et al., Reference Marcott, Shakun Jeremy, Clark Peter and Mix Alan2013; Shi et al., Reference Shi, Lu, Guo, Yin, Wu, Xu and Zhang2021), and thus the climate of this interval is a potential analogue for future warming (Renssen et al., Reference Renssen, Seppä, Crosta, Goosse and Roche2012). In northern China, loess deposits were mainly derived from nearby arid and semiarid regions (Liu, Reference Liu1985). The grain-size distribution (GSD) of loess is principally controlled by the source-to-sink distance, that is, generally speaking, the greater the dust transport distance, the finer the grain size for dust deposit (Yang and Ding, Reference Yang and Ding2004, Reference Yang and Ding2008; Ding et al., Reference Ding, Derbyshire, Yang, Sun and Liu2005).Therefore, loess grain size is an effective proxy for reconstructing the source–sink distances and, for this study, desert margin migrations associated with the movement of the EASM rainfall belt (Ding et al., Reference Ding, Derbyshire, Yang, Sun and Liu2005; Yang and Ding, Reference Yang and Ding2008; Li et al., Reference Li, Song, Qiang, Miao and Zeng2019). Chinese loess is mainly composed of loosely cemented silt (Liu, Reference Liu1985), which is vulnerable to erosion, especially during the Holocene (Yang and Ding, Reference Yang and Ding2008; Chen et al., Reference Chen, Qiang, Zhou, Xiao, Chen and Sun2013; Qiang et al., Reference Qiang, Liu, Jin, Song, Huang and Chen2014). Sediments preserved in lakes in downwind, semiarid regions provide a continuous record of regional eolian activity (Qiang et al., Reference Qiang, Liu, Jin, Song, Huang and Chen2014; Chen et al., Reference Chen, Chen, Zhang, Chen, Wang, Gowan and Qiang2020). However, lake sediments represent a mixture of materials from different sources, reworked and sorted by hydrodynamic processes within the lake proper (Håkanson and Jansson, Reference Håkanson and Jansson1983; Talbot and Allen, Reference Talbot, Allen and Reading1996), resulting in polymodal GSDs. These sediments represent challenges to partitioning out the eolian component. A recently developed grain-size endmember (EM) model can help unmix GSD data into the constituent components (Paterson and Heslop Reference Paterson and Heslop2015). This model has been successfully applied in the reconstructions of sediment provenance, depositional regimes/processes, and paleoclimate in the Tibetan Plateau, Central Asia, and East Africa (Meyer et al., Reference Meyer, Davies, Vogt, Kuhlmann and Stuut2013, Reference Meyer, Van Daele, Tanghe, De Batist and Verschuren2020; Dietze et al., Reference Dietze, Maussion and Ahlborn2014; Liu et al., Reference Liu, Vandenberghe, An, Li, Jin, Dong and Sun2016; Zhou et al., Reference Zhou, Wu, Ma and Qiang2019).

Many of the closed-basin lakes on the northern margin of the EASM (Fig. 1) are very sensitive to hydrological changes, because their water input is mainly from monsoonal rainfall, and thus their sediments are valuable archives for determining the paleohydrology and paleoclimate of this region (An et al., Reference An, Porter, Kutzbach, Wu, Wang, Liu, Li and Zhou2000; Li et al., Reference Li, Wang, Zhao, Jin, Wang, Tao and Chen2020). In this study, we analyzed the GSDs and carbonate mineralogy of the sediments of Lake Bayanchagan, with the aim of reconstructing changes in lake level and dust activity during the Holocene, focusing on the hydroclimatic response of northern China to the most recent period of major global warming.

Figure 1. The locations of Lake Bayanchagan and other sites referenced in the text. Also shown are the major deserts of northern China: (a) Tengger Desert, (b) Mu Us Desert, (c) Hobq Desert, (d) Ulan Buh Desert, (e) Otindag Sandy Land, (f) Horqin Sandy Land, and (g) Hulun Buir Sandy Land (modified after Yang and Ding, Reference Yang and Ding2008). The red dashed line indicates the modern summer monsoon boundary (Yang et al., Reference Yang, Dong and Xiao2019), and the arrows indicate the modern trajectory of the East Asian summer monsoon (EASM) (red) and the East Asian winter monsoon (EAWM) (blue).

MATERIALS AND METHODS

Lake Bayanchagan (41.64°N, 115.21°E, 1355 m above sea level) is located in the transition between desert and steppe environments in northern China (Fig. 1). The lake is almost completely dry at present, due to human activity, although small shallow areas of water are maintained by summer rainfall. The clastic sediments in Lake Bayanchagan are mainly derived from eolian deposits and runoff-transported materials from the catchment. The present-day climate is mainly controlled by the East Asian monsoon, which comprises two seasonally alternating atmospheric circulations. In winter, a northwesterly dry, cold air mass from Siberia leads to cold and dry weather, while in summer, a southeasterly air mass transports heat and moisture inland from the low-latitude oceans. The mean annual temperature and the mean temperature in January and July are 3°C, −16°C, and 17°C, respectively. The annual precipitation is ~350 mm, ~70% of which falls in summer (June to September).

A sediment core (BY) was collected from a trench area in the center of Lake Bayanchagan. Details of the sedimentary lithology, results of 14C dating, and the pollen stratigraphy of this core are presented elsewhere (Jiang et al., Reference Jiang, Guo, Sun, Wu, Chu, Yuan, Hatté and Guiot2006). Two dates from Potamogeton seeds in the core were excluded, as some species of this aquatic plant have submerged leaves, and hence subaquatic photosynthesis might introduce a hard-water error into any subsequent 14C date (Törnqvist et al. Reference Törnqvist, De Jong, Oosterbaan and Van Der Borg1992). A sample of the total organic carbon content of the uppermost sediments (0–2 cm depth) had a 14C age of 570 yr (Table 1). This date, older than the actual age, is likely caused by the influx of “old carbon” to the lake from the catchment or by coastal erosion (Olsson, Reference Olsson2009; Hou et al., Reference Hou, D'Andrea and Liu2012). This radiocarbon reservoir age of Lake Bayanchagan is approximately consistent with those of Lakes Hulun (685 yr; Wen et al., Reference Wen, Xiao, Chang, Zhai, Xu, Li, Itoh and Lomtatidze2010), Dali (611 yr; Xiao et al., Reference Xiao, Chang, Si, Qin, Itoh and Lomtatidze2009), and Daihai (360 yr; Peng et al., Reference Peng, Xiao, Nakamura, Liu and Inouchi2005) in the northern margin of the EASM. To establish an age–depth model, we assumed that the proportion of “old carbon” was relatively constant throughout the core. The reservoir age of 570 yr was subtracted from all the original 14C ages, and the resulting ages were then converted to calibrated ages using the IntCal 20 calibration curve (Stuiver et al., Reference Stuiver, Reimer and Reimer2020; Fig. 2).

Table 1. Accelerator mass spectrometry dating results for core BY from Lake Bayanchagan, northern China

b CALIB rev. 8 (Stuiver and Reimer, Reference Stuiver and Reimer1993; http://calib.org)

c GifA: the LSCE-UMR CEA/CNRS 1572 (Gif-sur-Yvette, France) for sample preparations and UMS2004 (Gif-sur-Yvette, France) for physical measurements.

Figure 2. Lithology and median grain-size (Md) data, along with age–depth model data for core BY from Lake Bayanchagan. TOC, total organic carbon.

The GSDs of 90 samples, taken at 2 cm intervals, were measured with a Mastersizer 3000 (Malvern Panalytical, UK). Before the measurements were made, all samples were treated with 30% H2O2 and then with 10% HCl to remove organic matter and carbonate, respectively, after which 10% (NaPO3)6 was added, and the samples were treated with ultrasound for 10 min to promote dispersion. The average GSDs, determined by three repeated measurements for each sample, were used as input data for subsequent calculations. The resulting GSD data set was mathematically decomposed using the AnalySize modeling algorithm developed by Paterson and Heslop (Reference Paterson and Heslop2015). This method aims to establish a physical mixing model that transforms the measured GSDs into a limited number of nonnegative and unimodal grain-size EMs that can be interpreted individually (Meyer et al., Reference Meyer, Van Daele, Tanghe, De Batist and Verschuren2020).

The carbonate mineralogy of 30 samples from the core was analyzed by X-ray diffraction (XRD; RINT2000 Wide-angle goniometer).

RESULTS

GSDs

During 11.5–10 ka (180–142 cm) (Fig. 3a), the median grain size (Md) varied from 203.4 to 5.8 μm. Most of the samples have trimodal GSDs, with a principal mode at 7.8 μm and two secondary modes at 38 and 0.448 μm. Samples from the depths of 180, 178, 160, 158, 152, and 148 cm have multimodal distributions, with the principal mode between 100 and 609 μm. For example, the GSDs of the samples from the depths of 152 and 148 cm show a major peak at ~410 μm and four minor peaks at 0.448, 7.8, 38, and 152 μm (Fig. 3a). The samples at 160 and 158 cm are roughly bimodal, with the principal mode at ~124 μm and secondary modes at 226 and 410 μm. During 10–5.8 ka (142–46 cm) (Fig. 3b), Md varied between 19.1 and 4.2 μm. The samples have relatively consistent bimodal GSDs, with the major peak at 7.8 μm and a minor peak at 38 μm. During 5.8–0 ka (46–0 cm) (Fig. 3c), Md varied from 39.2 to 4.5 μm, and all the samples have trimodal GSDs, in most cases with the main peak at 7.8 μm and two minor peaks at ~38 and 0.448 μm.

Figure 3. Core BY data. (a–c) Grain-size distributions (GSDs). (d) C–M plot: C indicates the coarsest percentile of the GSDs (the value at 99%), and M indicates the median (the value at 50%).

On the C–M plot of grain-size data, where C and M indicate the coarsest percentile (the value at 99%) and the median (the value at 50%) of the GSDs, respectively, three transport mechanisms can be partitioned according to the combination of C and M values, that is, suspension and rolling, uniform suspension, and pelagic suspension (Passega, Reference Passega1964; Fig. 3d). A C–M plot of the grain-size data from core BY reveals three main groupings (Fig. 3d). The sediments from the depth interval of 180–142 cm fall within all three groups, while those from the intervals of 142–46 and 46–0 cm mainly fall within the pelagic suspension and uniform suspension fields, respectively (Fig. 3d).

EM modeling

The goodness-of-fit statistics show an increasingly better fit (higher R 2) to the raw GSD spectra as the number of EMs increases (Fig. 4a). Thus, we chose a model with four EMs, which explains more than 92% of the variance in the GSDs (Fig. 4a). All EMs have unimodal distributions (Fig. 4b). The modeled peaks of these EMs are ~0.448 μm (EM1), ~7.8 μm (EM2), 38 μm (EM3), and 152 μm (EM4), representing the four major modes—at 0.448, 7.8, 38, and 100–410 μm—indicated by the entire GSD data set (Fig. 4b).

Figure 4. (a) Plot of the coefficient of determination (R 2) versus the number of grain-size endmembers (EMs) chosen to model the observed grain-size distributions (GSDs), from 1 to 10. (b) Overlay plot of the GSDs of all samples (n = 90) (gray curves) and the three retained EMs (colored curves). (c) Characteristic GSDs of surface sediments collected in the center (left), transitional zone (middle), and nearshore zone (right) of lakes in northern China (modified from Guo et al., Reference Guo, Wang, Wang, Liu, Ma and Jiang2016). (d) Dominant modes of the GSDs of surface sediment samples from the nearshore zone of lakes (red) (Guo et al., Reference Guo, Wang, Wang, Liu, Ma and Jiang2016; Xu et al., Reference Xu, Wang, Gu, Hao, Wang, Chu, Jiang, Liu and Qin2018), loess sediments (blue) (Yang and Ding, Reference Yang and Ding2004), and the offshore-suspension component in sediments from Lake Dali (green) (Xiao et al., Reference Xiao, Chang, Si, Qin, Itoh and Lomtatidze2009).

During 11.5–10.2 ka, EM1 values fluctuated between 0.3% and 7.1%. During 10.2–5.8 ka, the proportion of EM1 was very low, averaging at 1.66%, except for two short pulses at 7.9 ka and 6.9 ka. The fluctuations of EM1 increased during 5.8–3.3 ka, followed by a decrease after 3.3 ka.

During 11.5–11.3 ka, EM2 increased from 26% to 98%, followed by a rapid decrease to 5% during 11.3–10.8 ka and an increase to ~60% during 10.8–10.0 ka. During 10.0–5.8 ka, the relative dominance of EM1 was relatively high (>79%), while subsequently, during 5.8–0 ka, its values fluctuated with a decreasing trend.

The proportion of EM3 was very low before 5.8 ka, except for two periods during 11.3–9.5 ka and during 8–6.3 ka. After 5.8 ka, its values fluctuated with an increasing trend (mean ~33.6%). The proportion of EM4 fluctuated between 90% and 0% during 11.5–10.8 ka. It was almost absent during 10.8–5 ka and then increased slightly after 5 ka.

Carbonate mineralogy

The XRD results (Fig. 5) show that during 11.5–5.8 ka, calcite dominated the carbonate fraction, with the average content of 47% and the maximum occurring during 10–5.8 ka, during which time dolomite was not detected. During 5.8–4.4 ka, dolomite content increased rapidly to ~30%, at the expense of calcite. During 4.4–1.8 ka, minor fluctuations occurred in both calcite and dolomite content, while after 1.8 ka, dolomite content decreased and calcite content increased.

Figure 5. Records of the proportions of EM1, EM2, EM3, EM4, calcite, dolomite, and carbonate δ18O of core BY. EM, grain-size endmember.

DISCUSSION

Holocene changes in lake level and precipitation on the northern margin of the EASM

Clastic materials from different sources get deposited in the lake and are then reworked and sorted by hydrodynamic processes within the lake itself (Håkanson and Jansson, Reference Håkanson and Jansson1983; Talbot and Allen, Reference Talbot, Allen and Reading1996). Coarse particles tend to be deposited in the nearshore zone, while fine-grained sediments are more common in the deeper waters (Lerman, Reference Lerman1978; Dietze et al., Reference Dietze, Maussion and Ahlborn2014). Investigations of 68 lakes in the marginal zone of the EASM have confirmed this relationship between lake water depth and sediment grain size (Guo et al., Reference Guo, Wang, Wang, Liu, Ma and Jiang2016). As shown in Figure 4c, the sediment grain size gradually decreases from 170–500 μm in the nearshore zone to 17–150 μm in the transitional zone, and finally to 2–70 μm in the lake center (Guo et al., Reference Guo, Wang, Wang, Liu, Ma and Jiang2016).

EM2 represents the relatively fine particle fraction in the Lake Bayanchagan sediments, with a mean grain size of 6.9 μm (90% within the range of 1.3–31 μm) (Fig. 4b). The dominant grain sizes of EM2 are consistent with the offshore-suspension component of sediments in the lake center, as indicated by previous investigations (Xiao et al., Reference Xiao, Chang, Si, Qin, Itoh and Lomtatidze2009; Guo et al., Reference Guo, Wang, Wang, Liu, Ma and Jiang2016; Fig. 4d). Therefore, EM2 dominates the clastic component of the profundal sediments in Lake Bayanchagan, and it is a proxy for past lake-level changes. The record of EM2 in core BY indicates that the level of Lake Bayanchagan gradually increased during 10.8–10.0 ka and reached a high stand during 10–5.8 ka. Lake levels decreased after 5.8 ka (Fig. 5).

The high stand of Lake Bayanchagan during ~10–5.8 ka is supported by the C–M plot for core BY, which illustrates that sediment transport is linked to hydrodynamic conditions (Passega, Reference Passega1964; Bravard et al., Reference Bravard, Goichot and Tronchère2014). As shown in Figure 3d, the GSDs of sediments in the lower part of core BY (180–142 cm, 11.5–10 ka) are distributed within three zones, suggesting that the hydrodynamic conditions fluctuated substantially during this interval. The GSDs of the sediments in the middle part of the core (142–46 cm, 10–5.8 ka) are distributed mainly in the lower left part of the graph, in the pelagic suspension zone, with the C values of most samples <100 μm, indicating weak hydrodynamic conditions related to a high stand of Lake Bayanchagan. The samples from the upper part of the core (46–0 cm, 5.8 ka to the present) are concentrated in the left-central part of the suspension zone, with C values >100 μm, reflecting a relatively strong hydrodynamic environment due to the lowered lake levels.

Precipitation of lacustrine carbonate is primarily determined by the salinity and Mg/Ca ratio of the lake water (Müller et al., Reference Müller, Irion and Förstner1972). As salinity increases, calcite precipitates first, followed by aragonite and dolomite (Shapley et al., Reference Shapley, Ito and Donovan2005). This scenario is consistent with an investigation of modern lakes in northern China, which showed that lake water salinity and Mg/Ca ratios increase with decreasing precipitation. As a result, calcite precipitates first, followed by dolomite, and then finally by gypsum and halite (Gu et al., Reference Gu, Jiang, Wang, Zhang, Yang and Xiong2015). In core BY, the increase in dolomite at the expense of calcite during 5.8–4.6 ka provides depositional evidence for the salinization of the lake (Fig. 5), indicative of decreasing precipitation and increasing aridity at the study area. This finding agrees with the stable oxygen isotopic composition of authigenic carbonate in core BY. The oxygen isotopic composition of carbonate is mainly controlled by the δ18O of the lake water, namely the balance between precipitation and evaporation (Leng and Marshall, Reference Leng and Marshall2004). Increased monsoonal precipitation results in lower water δ18O values, whereas evaporation results in higher values (Leng and Marshall, Reference Leng and Marshall2004; Yang et al., Reference Yang, Ding, Wang, Tang and Gu2012). The carbonate δ18O record of core BY suggests enhanced monsoonal precipitation during 10.1–5.8 ka, followed by a large reduction during 5.8–4.6 ka (Jiang and Liu, Reference Jiang and Liu2007). The similarity between the carbonate δ18O and EM1 records, together with the variations of the calcite and dolomite content (Fig. 5), indicate that fluctuations in the lake level of Lake Bayanchagan over the Holocene were closely linked to changes in monsoonal precipitation.

High lake levels during the Early and Middle Holocene have also been observed in records from other closed-basin lakes on the northern margin of the EASM (Fig. 6). Lake beach ridges and sediment outcrops, which represent past variations in lake-level elevation and extent (Goldsmith et al., Reference Goldsmith, Broecker, Xu, Polissar, deMenocal, Porat, Lan, Cheng, Zhou and An2017), have been investigated for Lakes Dali and Chagan Nur. The results suggest that, between ~11 and ~5.9–5 ka, lake levels were 12–60 m higher than today (Goldsmith et al., Reference Goldsmith, Broecker, Xu, Polissar, deMenocal, Porat, Lan, Cheng, Zhou and An2017; Li et al., Reference Li, Wang, Zhao, Jin, Wang, Tao and Chen2020; Fig. 6). A recent study of Lake Gonghai, based on the aquatic origin of branched glycerol dialkyl glycerol tetraethers (brGDGTs), indicated high lake levels during 9.5–5 ka (Cao et al., Reference Cao, Rao, Shi, Lian and Jia2021; Fig. 6). Thus, the concordance of these studies suggests that, within the limits of the available chronologies, high lake levels on the northern margin of the EASM occurred consistently during ~10–5 ka. Furthermore, precipitation reconstructions based on pollen assemblages and biomarkers in lake sediments also show a consistent relationship with lake-level changes (Jiang et al., Reference Jiang, Guo, Sun, Wu, Chu, Yuan, Hatté and Guiot2006; Chen et al., Reference Chen, Xu and Chen2015; Cao et al. Reference Cao, Rao, Shi, Lian and Jia2021; Fig. 6).

Figure 6. Comparisons of paleoenvironmental records from the northern margin of the EASM and global annual temperature. (a and b) Precipitation reconstructed from pollen data from Lake Bayanchagan (Jiang et al., Reference Jiang, Guo, Sun, Wu, Chu, Yuan, Hatté and Guiot2006) and Lake Gonghai (Chen et al., Reference Chen, Xu and Chen2015). (c–f) Lake-level records from Lake Dali (Goldsmith et al., Reference Goldsmith, Broecker, Xu, Polissar, deMenocal, Porat, Lan, Cheng, Zhou and An2017), Lake Chagan Nur (Li et al., Reference Li, Wang, Zhao, Jin, Wang, Tao and Chen2020), and Lake Gonghai based on branched glycerol dialkyl glycerol tetraether (brGDGT) data (Cao et al., Reference Cao, Rao, Shi, Lian and Jia2021), and Lake Bayanchagan (this study). (g and h) Pollen-based temperature reconstruction from Lake Bayanchagan (Jiang et al., Reference Jiang, Guo, Sun, Wu, Chu, Yuan, Hatté and Guiot2006) and reconstructed global annual temperature (Marcott et al., Reference Marcott, Shakun Jeremy, Clark Peter and Mix Alan2013). EM2, grain-size endmember 2; TANN, mean annual temperature.

Holocene dust activity on the northern margin of the EASM

EM1 is consistent with the peak at ~0.4 μm of the GSDs for loess deposits in the Chinese Loess Plateau (Yang and Ding, Reference Yang and Ding2004; Fig. 4d). Generally, the very fine component may adhere to the surfaces of large grains, forming aggregates that can be transported by saltation or rolling (Pye, Reference Pye1995; Derbyshire et al., Reference Derbyshire, Meng and Kemp1998; Qiang et al., Reference Qiang, Lang and Wang2010). The fine material may be disaggregated after being deposited in the lake or being treated with ultrasound before grain-size measurements.

EM3 represents the relatively coarse fraction of the Lake Bayanchagan sediments. Its broad peak at ~38 μm (90% within the range of 14–102 μm) (Fig. 4b) is very similar to the dominant mode of coarse loess in the northern part of the Loess Plateau (Sun et al., Reference Sun, Su, Bloemendal and Lu2008; Yang and Ding, Reference Yang and Ding2008; Fig. 4d). The consistent variations in EM3 and EM1 suggest that these two portions are transported by wind and can be interpreted as indicators of variations in regional dust sources.

EM4 reflects the coarsest fraction of the Lake Bayanchagan sediments. Its peak at 152 μm (90% within the range of 68–500 μm) (Fig. 4b) is similar to the dominant mode of the nearshore sediments (Guo et al., Reference Guo, Wang, Wang, Liu, Ma and Jiang2016; Xu et al., Reference Xu, Wang, Gu, Hao, Wang, Chu, Jiang, Liu and Qin2018; Fig. 4d). Lake Bayanchagan is located within the southern margin of the Otindag Sandy Land (Fig. 1); therefore, EM4 is most likely sourced from local dunes.

The paleoenvironmental record of EM1, EM3, and EM4 within core BY demonstrates that dust activity in the region fluctuated during the 11.5–10 ka interval, while the low values of these three EMs indicate low dust activity during the 10–5.8 ka interval. EM3 increased by ~33% during 5.8–3.8 ka, indicating increased dust activity, which subsequently remained at an overall high level, despite several intervals of low dust activity (Fig. 5).

Dust storm activity is a function of the environmental conditions within the dust source region, including precipitation amount, vegetation cover, and wind strength (Clemens, Reference Clemens1998; Carolin et al., Reference Carolin, Walker and Day2019). The major deserts in northern China include the Mu Us Desert, Hobq Desert, Horqin Sandy Land, and Hulunbuir Sandy Land (Fig. 1). All of these deserts are important global dust sources (Dong et al., Reference Dong, Wang and Li1998; Zhang et al., Reference Zhang, Shen, Li, Jia, Li and Wang2018). Paleoclimatic records indicate that monsoonal precipitation began to increase in the Early Holocene (~11–10 ka) and reached a maximum during ~9–6 ka (Jiang et al., Reference Jiang, Guo, Sun, Wu, Chu, Yuan, Hatté and Guiot2006; Chen et al., Reference Chen, Xu and Chen2015; Li et al., Reference Li, Wang, Zhao, Jin, Wang, Tao and Chen2020). Both the vegetation cover and plant diversity gradually increased with this increasing precipitation. During ~11–10 ka, steppe vegetation prevailed, dominated by Artemisia, Chenopodiaceae, Poaceae, and Ephedra. During 9–6 ka, there was an increase in deciduous broadleaved trees (Betula, Ulmus, Quercus), which were the most diverse plant group throughout the Holocene, together with Pinus (Xiao et al., Reference Xiao, Xu, Nakamura, Yang, Liang and Inouchi2004; Jiang et al., Reference Jiang, Guo, Sun, Wu, Chu, Yuan, Hatté and Guiot2006; Xu et al., Reference Xu, Xiao, Li, Tian and Nakagawa2010; Wen et al., Reference Wen, Xiao, Chang, Zhai, Xu, Li, Itoh and Lomtatidze2010, Reference Wen, Xiao, Fan, Zhang and Yamagata2017; Chen et al., Reference Chen, Xu and Chen2015). An increase in the vegetation cover reduces the surface wind strength and increases the soil stability. All these factors, including the increased precipitation and vegetation cover and the decreasing wind strength, led to a large reduction in dust emissions. Therefore, the low dust activity during 10–5.8 ka was likely a response to the humid climate on the northern margin of the EASM. The increased dust activity after 5.8 ka was then related to large-scale drought conditions and the associated vegetation degradation caused by the decrease in monsoonal precipitation.

The stratigraphy in deserts is characterized by the alternation of eolian sand layers and paleosols. These alternating sequences cover an area of ~105 km2 in the deserts located to the east of the Helan Mountains (Zhang et al., Reference Zhang, Shen, Li, Jia, Li and Wang2018; Fig. 1). Eolian sand layers represent periods of dune-field expansion and/or dune buildup and are associated with enhanced dust activity, whereas paleosol layers indicate dune stabilization, weakened dust activity, and increased vegetation cover (Lu et al., Reference Lu, Mason and Stevens2011; Xu et al., Reference Xu, Wang, Gu, Hao, Wang, Chu, Jiang, Liu and Qin2018). Therefore, the eolian sand–paleosol sequences are an archive of changes in the intensity and frequency of paleo-eolian sand activity. A recent study showed that paleosol development in the deserts of northern China started at ~11 ka and that the proportion of vegetation-stabilized dunes gradually increased until ~6 ka (Xu et al., Reference Xu, Mason, Xu, Yi, Bathiany, Yizhaq, Zhou, Cheng, Holmgren and Lu2020), indicating a trend of decreasing dust activity during 11–6 ka. After ~6–5 ka, the reduction of the proportion of vegetation-stabilized dunes, as well as less frequent and thinner paleosols, indicate dune reactivation (Yang et al., Reference Yang, Scuderi and Paillou2011; Lu et al., Reference Lu, Yi and Xu2013; Xu et al. Reference Xu, Mason, Xu, Yi, Bathiany, Yizhaq, Zhou, Cheng, Holmgren and Lu2020), which is consistent with our inference of intensified dust emissions.

Holocene lake high stands on the northern margin of the EASM region

Our study has illustrated that the high stand of Lake Bayanchagan corresponded to the interval of high monsoon precipitation and low dust activity during the ~10–5.8 ka interval, in accord with other paleoclimatic records from the northern margin of the EASM (Goldsmith et al., Reference Goldsmith, Broecker, Xu, Polissar, deMenocal, Porat, Lan, Cheng, Zhou and An2017; Xu et al., Reference Xu, Wang, Gu, Hao, Wang, Chu, Jiang, Liu and Qin2018; Li et al., Reference Li, Wang, Zhao, Jin, Wang, Tao and Chen2020). The temperature in northern China during this interval increased by ~2–4°C (Jiang et al., Reference Jiang, Guo, Sun, Wu, Chu, Yuan, Hatté and Guiot2006; Zhang et al., Reference Zhang, Wu, Cheng, Geng, Li, Sun, Yu, Lu and Guo2022; Fig. 6), suggesting that, during ~10–6 ka, high precipitation occurred synchronously with high temperatures across northern China. Geological records and climate simulations show that the displacement of the EASM rain belt is associated with the migration of the Intertropical Convergence Zone (ITCZ), which moved northward in response to pronounced Northern Hemisphere warming during the mid-Holocene (Yang et al. Reference Yang, Ding, Li, Wang, Jiang and Huang2015, Reference Yang, Dong and Xiao2019; Huang et al., Reference Huang, Yang, Haywood, Jiang, Wang, Sun, Tang and Ding2021; Sun et al., Reference Sun, Yang, Xiao, Wang, Huang, Zhang, Yang, Jiang and Ding2022). This led to the northward shift of the monsoonal rain belt, causing a widespread increase in precipitation, which in turn resulted in lake high stands on the northern margin of the EASM. As global warming continues, the northern margin of the EASM is projected to become wetter, and dust storm activity will be weakened (Yang et al. Reference Yang, Ding, Li, Wang, Jiang and Huang2015; Huang et al., Reference Huang, Yang, Haywood, Jiang, Wang, Sun, Tang and Ding2021).

CONCLUSIONS

We used a high-resolution grain-size record, along with carbonate mineralogy, from sediments of Lake Bayanchagan on the northern margin of the EASM to reconstruct changes in lake level and dust activity over the past 11.5 ka. The results show that the level of Lake Bayanchagan was relatively low during 11.5–10.8 ka, and that then it gained water during ~10.8–10 ka. The high stand of Lake Bayanchagan and low level of dust activity occurred during ~10–5.8 ka. After 5.8 ka, the lake level decreased, corresponding to increased dust activity. The strong similarity between the carbonate δ18O and grain-size records of Lake Bayanchagan, together with the variations of sedimentary calcite and dolomite contents, indicate that the lake-level fluctuations of Lake Bayanchagan during the Holocene were driven by changes in monsoonal precipitation. A regional comparison suggests that lake-level high stands and high precipitation values occurred synchronously on the northern margin of the EASM during ~10 to ~6 ka, corresponding to the Holocene thermal maximum. At this time, the ITCZ had moved northward in response to this significant climatic warming, driving a northwestward shift of the EASM rain belt and enhanced monsoonal rainfall. After 5.8 ka, the ITCZ had migrated southward due to the decreasing temperatures, leading to a southeastward shift of the EASM rain belt and decreased monsoonal precipitation. This climatic change was associated with extensive drought conditions, falling lake levels, and enhanced dust activity.

Acknowledgments

We thank Nicholas Lancaster, Randall Schaetzl, Inka Meyer, and Zhiwei Xu for their constructive comments, which greatly improved the article. This study was supported by the National Natural Science Foundation of China (41931181 and 41725010), the National Key Research & Development Program of China (2020YFA0607703), the Strategic Priority Research Program of Chinese Academy of Sciences (CAS) (XDB26000000 and XDB31000000), and the Key Research Program of the Institute of Geology & Geophysics, CAS (IGGCAS-201905).

References

REFERENCES

An, Z., Porter, S.C., Kutzbach, J.E., Wu, X., Wang, S., Liu, ,., Li, X., Zhou, W., 2000. Asynchronous Holocene optimum of the East Asian monsoon. Quaternary Science Reviews 19, 743762.10.1016/S0277-3791(99)00031-1CrossRefGoogle Scholar
Bravard, J., Goichot, M., Tronchère, H., 2014. An assessment of sediment-transport processes in the Lower Mekong River based on deposit grain sizes, the CM technique and flow-energy data. Geomorphology 207, 174189.10.1016/j.geomorph.2013.11.004CrossRefGoogle Scholar
Cao, J., Rao, Z., Shi, F., Lian, E., Jia, G., 2021. Lake-level records support a mid-Holocene maximum precipitation in northern China. Science China Earth Sciences 64, 21612171.10.1007/s11430-020-9833-3CrossRefGoogle Scholar
Carolin, S., Walker, R., Day, C., 2019. Precise timing of abrupt increase in dust activity in the Middle East coincident with 4.2 ka social change. Proceedings of the National Academy of Sciences USA 116, 6772.10.1073/pnas.1808103115CrossRefGoogle ScholarPubMed
Chen, F., Chen, S., Zhang, X., Chen, J., Wang, X., Gowan, E. J., Qiang, M., et al., 2020. Asian dust-storm activity dominated by Chinese dynasty changes since 2000 BP. Nature Communications 11, 992.10.1038/s41467-020-14765-4CrossRefGoogle ScholarPubMed
Chen, F., Qiang, M., Zhou, A., Xiao, S., Chen, J., Sun, D., 2013. A 2000-year dust storm record from Lake Sugan in the dust source area of arid China. Journal of Geophysical Research: Atmospheres 118, 21492160.10.1002/jgrd.50140CrossRefGoogle Scholar
Chen, F., Xu, Q., Chen, J., 2015. East Asian summer monsoon precipitation variability since the last deglaciation. Scientific Reports 5, 11186.10.1038/srep11186CrossRefGoogle ScholarPubMed
Clemens, S., 1998. Dust response to seasonal atmospheric forcing: Proxy evaluation and calibration. Paleoceanography 13, 471490.10.1029/98PA02131CrossRefGoogle Scholar
Derbyshire, E., Meng, X., Kemp, R.A., 1998. Provenance, transport and characteristics of modern aeolian dust in western Gansu Province, China, and interpretation of the Quaternary loess record. Journal of Arid Environments 39, 497516.10.1006/jare.1997.0369CrossRefGoogle Scholar
Dietze, E., Maussion, F., Ahlborn, M., 2014. Sediment transport processes across the Tibetan Plateau inferred from robust grain-size end members in lake sediments. Climate of the Past 10, 91106.10.5194/cp-10-91-2014CrossRefGoogle Scholar
Ding, Z.L., Derbyshire, E., Yang, S.L., Sun, J.M., Liu, T.S., 2005. Stepwise expansion of desert environment across northern China in the past 3.5 Ma and implications for monsoon evolution. Earth and Planetary Science Letters 237, 4555.10.1016/j.epsl.2005.06.036CrossRefGoogle Scholar
Dong, G., Wang, G., Li, X., 1998. Palaeomonsoon vicissitudes in eastern desert region of China since last interglacial period. [In Chinese with English abstract.] Science China Earth Sciences 41, 215224.10.1007/BF02932443CrossRefGoogle Scholar
Goldsmith, Y., Broecker, W.S., Xu, H., Polissar, P.J., deMenocal, P.B., Porat, N., Lan, J., Cheng, P., Zhou, W., An, Z., 2017. Northward extent of East Asian monsoon covaries with intensity on orbital and millennial timescales. Proceedings of the National Academy of Sciences USA 114, 18171821.10.1073/pnas.1616708114CrossRefGoogle ScholarPubMed
Gu, N., Jiang, W., Wang, L., Zhang, E., Yang, S., Xiong, S., 2015. Rainfall thresholds for the precipitation of carbonate and evaporite minerals in modern lakes in northern China. Geophysical Research Letters 42, 58955901.10.1002/2015GL064340CrossRefGoogle Scholar
Guo, X., Wang, W., Wang, G., Liu, L., Ma, Y., Jiang, H.E., 2016. Within-lake distributions of grain-size components and environmental implications based on the survey of lake surface sediment of Chinese monsoon marginal area. [In Chinese with English abstract.] Geographical Research 35, 677691.Google Scholar
Håkanson, L., Jansson, M., 1983. Principles of Lake Sedimentology. Springer, Berlin.10.1007/978-3-642-69274-1CrossRefGoogle Scholar
Held, I.M., Soden, B.J., 2006. Robust responses of the hydrological cycle to global warming. Journal of Climate 19, 56865699.10.1175/JCLI3990.1CrossRefGoogle Scholar
Hou, J., D'Andrea, W.J., Liu, Z., 2012. The influence of 14C reservoir age on interpretation of paleolimnological records from the Tibetan Plateau. Quaternary Science Reviews 48, 6779.10.1016/j.quascirev.2012.06.008CrossRefGoogle Scholar
Huang, X., Yang, S., Haywood, A., Jiang, D., Wang, Y., Sun, M., Tang, Z., Ding, Z., 2021. Warming-induced northwestward migration of the Asian summer monsoon in the geological past: evidence from climate simulations and geological reconstructions. Journal of Geophysical Research: Atmospheres 126, e2021JD035190.10.1029/2021JD035190CrossRefGoogle Scholar
Jiang, W., Guo, Z., Sun, X., Wu, H., Chu, G., Yuan, B., Hatté, C., Guiot, J., 2006. Reconstruction of climate and vegetation changes of Lake Bayanchagan (Inner Mongolia): Holocene variability of the East Asian monsoon. Quaternary Research 65, 411420.10.1016/j.yqres.2005.10.007CrossRefGoogle Scholar
Jiang, W., Liu, T., 2007. Timing and spatial distribution of mid-Holocene drying over northern China: response to a south-eastward retreat of the East Asian monsoon. Journal of Geophysical Research: Atmospheres 112, D24111.10.1029/2007JD009050CrossRefGoogle Scholar
Leng, M., Marshall, J., 2004. Palaeoclimate interpretation of stable isotope data from lake sediment archives. Quaternary Science Reviews 23, 811831.10.1016/j.quascirev.2003.06.012CrossRefGoogle Scholar
Lerman, A., 1978. Lakes: Chemistry, Geology, Physics. Springer-Verlag, New York.10.1007/978-1-4757-1152-3CrossRefGoogle Scholar
Li, G., Wang, Z., Zhao, W., Jin, M., Wang, X., Tao, S., Chen, C., et al., 2020. Quantitative precipitation reconstructions from Chagan Nur revealed lag response of East Asian summer monsoon precipitation to summer insolation during the Holocene in arid northern China. Quaternary Science Reviews 239, 106365.10.1016/j.quascirev.2020.106365CrossRefGoogle Scholar
Li, Y., Song, Y., Qiang, M., Miao, Y., Zeng, M., 2019. Atmospheric dust variations in the Ili Basin, northwest China, during the last glacial period as revealed by a high mountain loess-paleosol sequence. Journal of Geophysical Research: Atmospheres 124, 84498466.10.1029/2019JD030470CrossRefGoogle Scholar
Liu, T.S., 1985. Loess and the Environment. China Ocean Press, Beijing.Google Scholar
Liu, X., Vandenberghe, J., An, Z., Li, Y., Jin, Z., Dong, J., Sun, Y., 2016. Grain size of Lake Qinghai sediments: implications for riverine input and Holocene monsoon variability. Palaeogeography, Palaeoclimatology, Palaeoecology 449, 4151.10.1016/j.palaeo.2016.02.005CrossRefGoogle Scholar
Lu, H., Mason, J., Stevens, T., 2011. Response of surface processes to climatic change in the dunefields and Loess Plateau of North China during the late Quaternary. Earth Surface Processes and Landforms 36, 15901603.10.1002/esp.2168CrossRefGoogle Scholar
Lu, H., Yi, S., Xu, Z., 2013. Chinese deserts and sand fields in last glacial maximum and Holocene optimum. Chinese Science Bulletin 58, 27752783.10.1007/s11434-013-5919-7CrossRefGoogle Scholar
Marcott, A., Shakun Jeremy, D., Clark Peter, U., Mix Alan, C., 2013. A reconstruction of regional and global temperature for the past 11,300 years. Science 339, 11981201.10.1126/science.1228026CrossRefGoogle ScholarPubMed
Meyer, I., Davies, G.R., Vogt, C., Kuhlmann, H., Stuut, J.-B.W., 2013. Changing rainfall patterns in NW Africa since the Younger Dryas. Aeolian Ressearch 10, 111123.10.1016/j.aeolia.2013.03.003CrossRefGoogle Scholar
Meyer, I., Van Daele, M., Tanghe, N., De Batist, M., Verschuren, D., 2020. Reconstructing East African monsoon variability from grain-size distributions: end-member modeling and source attribution of diatom-rich sediments from Lake Chala. Quaternary Science Reviews 247, 106574.10.1016/j.quascirev.2020.106574CrossRefGoogle Scholar
Müller, G., Irion, G., Förstner, U., 1972. Formation and diagenesis of inorganic Ca-Mg carbonates in the lacustrine environment. Naturwissenschaften 59, 158164.10.1007/BF00637354CrossRefGoogle Scholar
Olsson, I.U., 2009. Radiocarbon dating history: early days, questions, and problems. Radiocarbon 51, 143.10.1017/S0033822200033695CrossRefGoogle Scholar
Passega, R., 1964. Grain size representation by CM patterns as a geological tool. Journal of Sedimentary Petrology 34, 830847.10.1306/74D711A4-2B21-11D7-8648000102C1865DCrossRefGoogle Scholar
Paterson, G.A., Heslop, D., 2015. New methods for unmixing sediment grain size data. Geochemistry, Geophysics, Geosystems 16, 44944506.10.1002/2015GC006070CrossRefGoogle Scholar
Peng, Y., Xiao, J., Nakamura, T., Liu, B., Inouchi, Y. 2005. Holocene East Asian monsoonal precipitation pattern revealed by grain-size distribution of core sediments of Daihai Lake in Inner Mongolia of north-central China. Earth and Planetary Science Letters 233, 467479.10.1016/j.epsl.2005.02.022CrossRefGoogle Scholar
Pye, K., 1995. The nature, origin and accumulation of loess. Quaternary Science Reviews 14, 653667.10.1016/0277-3791(95)00047-XCrossRefGoogle Scholar
Qiang, M., Lang, L., Wang, Z., 2010. Do fine-grained components of loess indicate westerlies: Insights from observations of dust storm deposits at Lenghu (Qaidam Basin, China). Journal of Arid Environments 74, 12321239.10.1016/j.jaridenv.2010.06.002CrossRefGoogle Scholar
Qiang, M., Liu, Y., Jin, Y., Song, L., Huang, X., Chen, F., 2014. Holocene record of eolian activity from Genggahai Lake, northeastern Qinghai-Tibetan Plateau, China. Geophysical Research Letters 41, 589595.10.1002/2013GL058806CrossRefGoogle Scholar
Renssen, H., Seppä, H., Crosta, X., Goosse, H., Roche, D.M., 2012. Global characterization of the Holocene Thermal Maximum. Quaternary Science Reviews 48, 719.10.1016/j.quascirev.2012.05.022CrossRefGoogle Scholar
Shapley, M.D., Ito, E., Donovan, J.J., 2005. Authigenic calcium carbonate flux in groundwater-controlled lakes: implications for lacustrine paleoclimate records. Geochimica et Cosmochimica Acta 69, 25172533.10.1016/j.gca.2004.12.001CrossRefGoogle Scholar
Shi, F., Lu, H., Guo, Z., Yin, Q., Wu, H., Xu, C., Zhang, E., et al., 2021. The position of the current warm period in the context of the past 22,000 years of summer climate in China. Geophysical Research Letters 48, e2020GL091940.10.1029/2020GL091940CrossRefGoogle Scholar
Sun, D., Su, R., Bloemendal, J., Lu, H., 2008. Grain-size and accumulation rate records from Late Cenozoic aeolian sequences in northern China: implications for variations in the East Asian winter monsoon and westerly atmospheric circulation. Palaeogeography, Palaeoclimatology, Palaeoecology 264, 3953.10.1016/j.palaeo.2008.03.011CrossRefGoogle Scholar
Sun, M., Yang, S., Xiao, J., Wang, Y., Huang, X., Zhang, S., Yang, X., Jiang, W., Ding, Z., 2022. BrGDGTs-based temperature and hydrological reconstruction from fluvio-lacustrine sediments in the monsoonal North China Plain since 31 kyr BP. Quaternary Science Reviews 277, 107268.10.1016/j.quascirev.2021.107268CrossRefGoogle Scholar
Stuiver, M., Reimer, P.J., 1993. Extended 14C data base and revised CALIB 3.0 14C age calibration program. Radiocarbon 35, 215230.10.1017/S0033822200013904CrossRefGoogle Scholar
Stuiver, M., Reimer, P.J. Reimer, R.W., 2020. CALIB 8.2. http://calib.org.Google Scholar
Talbot, M.R., Allen, P.A., 1996, Lakes. In: Reading, H.G. (Ed.), Sedimentary Environments: Processes, Facies and Stratigraphy. Blackwell Science, Oxford, pp. 536.Google Scholar
Törnqvist, T.E., De Jong, A.F.M., Oosterbaan, W.A., Van Der Borg, K., 1992. Accurate dating of organic deposits by AMS 14C measurement of macrofossils. Radiocarbon 34, 566577.10.1017/S0033822200063840CrossRefGoogle Scholar
Wang, W., Lee, X., Xiao, W., Liu, S., Schultz, N., Wang, Y., Zhang, M., Zhao, L., 2018. Global lake evaporation accelerated by changes in surface energy allocation in a warmer climate. Nature Geoscience 11, 410414.10.1038/s41561-018-0114-8CrossRefGoogle Scholar
Wen, R., Xiao, J., Chang, Z., Zhai, D., Xu, Q., Li, Y., Itoh, S., Lomtatidze, Z., 2010. Holocene climate changes in the mid-high-latitude-monsoon margin reflected by the pollen record from Hulun Lake, northeastern Inner Mongolia. Quaternary Research 73, 293303.10.1016/j.yqres.2009.10.006CrossRefGoogle Scholar
Wen, R., Xiao, J., Fan, J., Zhang, S., Yamagata, H., 2017. Pollen evidence for a mid-Holocene East Asian summer monsoon maximum in northern China. Quaternary Science Reviews 176, 2935.10.1016/j.quascirev.2017.10.008CrossRefGoogle Scholar
Xiao, J., Chang, Z., Si, B., Qin, X., Itoh, S., Lomtatidze, Z., 2009. Partitioning of the grain-size components of Dali Lake core sediments: evidence for lake-level changes during the Holocene. Journal of Paleolimnology 42, 249260.10.1007/s10933-008-9274-7CrossRefGoogle Scholar
Xiao, J., Xu, Q., Nakamura, T., Yang, X., Liang, W., Inouchi, Y., 2004. Holocene vegetation variation in the Daihai Lake region of north-central China: a direct indication of the Asian monsoon climatic history. Quaternary Science Reviews 23, 16691679.10.1016/j.quascirev.2004.01.005CrossRefGoogle Scholar
Xu, B., Wang, L., Gu, Z., Hao, Q., Wang, H., Chu, G., Jiang, D., Liu, Q., Qin, X., 2018. Decoupling of climatic drying and Asian dust export during the Holocene. Journal of Geophysical Research: Atmospheres 123, 915928.10.1002/2017JD027483CrossRefGoogle Scholar
Xu, Q., Xiao, J., Li, Y., Tian, F., Nakagawa, T., 2010. Pollen-based quantitative reconstruction of Holocene climate changes in the Daihai Lake area, Inner Mongolia, China. Journal of Climate 23, 28562868.10.1175/2009JCLI3155.1CrossRefGoogle Scholar
Xu, Z., Mason, J.A., Xu, C., Yi, S., Bathiany, S., Yizhaq, H., Zhou, Y., Cheng, J., Holmgren, M., Lu, H., 2020. Critical transitions in Chinese dunes during the past 12,000 years. Science Advances 6, eaay8020.10.1126/sciadv.aay8020CrossRefGoogle ScholarPubMed
Yang, S., Ding, Z., 2004. Comparison of particle size characteristics of the Tertiary “red clay” and Pleistocene loess in the Chinese Loess Plateau: implications for origin and sources of the “red clay.” Sedimentology 51, 7793.10.1046/j.1365-3091.2003.00612.xCrossRefGoogle Scholar
Yang, S., Ding, Z., 2008. Advance-retreat history of the East-Asian summer monsoon rainfall belt over northern China during the last two glacial-interglacial cycles. Earth and Planetary Science Letters 274, 499510.10.1016/j.epsl.2008.08.001CrossRefGoogle Scholar
Yang, S., Ding, Z., Li, Y., Wang, X., Jiang, W., Huang, X., 2015. Warming-induced northwestward migration of the East Asian monsoon rain belt from the Last Glacial Maximum to the mid-Holocene. Proceedings of the National Academy of Sciences USA 112, 1317813183.10.1073/pnas.1504688112CrossRefGoogle Scholar
Yang, S., Ding, Z., Wang, X., Tang, Z., Gu, Z., 2012. Negative δ18O-δ13C relationship of pedogenic carbonate from northern China indicates a strong response of C3/C4 biomass to the seasonlity of Asian monsoon precipitation. Palaeogeography, Palaeoclimatology, Palaeoecology 317/318, 3240.10.1016/j.palaeo.2011.12.007CrossRefGoogle Scholar
Yang, S., Dong, X., Xiao, J., 2019. The East Asian monsoon since the last glacial maximum: evidence from geological records in northern China. Science China Earth Sciences 62, 11811192.10.1007/s11430-018-9254-8CrossRefGoogle Scholar
Yang, X., Scuderi, L., Paillou, P., 2011. Quaternary environmental changes in the drylands of China—a critical review. Quaternary Science Reviews 30, 32193233.10.1016/j.quascirev.2011.08.009CrossRefGoogle Scholar
Zhang, C., Shen, Y., Li, Q., Jia, W., Li, J., Wang, X., 2018. Sediment grain-size characteristics and relevant correlations to the aeolian environment in China's eastern desert region. Science of the Total Environment 627, 586599.10.1016/j.scitotenv.2018.01.270CrossRefGoogle Scholar
Zhang, P., Jeong, J.-H., Yoon, J.-H., Kim, H., Wang, S.Y.S., Linderholm, H.W., Fang, K., Wu, X., Chen, D., 2020. Abrupt shift to hotter and drier climate over inner East Asia beyond the tipping point. Science 370, 10951099.10.1126/science.abb3368CrossRefGoogle ScholarPubMed
Zhang, W., Wu, H., Cheng, J., Geng, J., Li, Q., Sun, Y., Yu, Y., Lu, H., Guo, Z., 2022. Holocene seasonal temperature evolution and spatial variability over the Northern Hemisphere landmass. Nature Communications 13: 5334.10.1038/s41467-022-33107-0CrossRefGoogle ScholarPubMed
Zhou, J., Wu, J., Ma, L., Qiang, M., 2019. Late Quaternary lake-level and climate changes in arid central Asia inferred from sediments of Ebinur Lake, Xinjiang, northwestern China. Quaternary Research 92, 416429.10.1017/qua.2019.27CrossRefGoogle Scholar
Figure 0

Figure 1. The locations of Lake Bayanchagan and other sites referenced in the text. Also shown are the major deserts of northern China: (a) Tengger Desert, (b) Mu Us Desert, (c) Hobq Desert, (d) Ulan Buh Desert, (e) Otindag Sandy Land, (f) Horqin Sandy Land, and (g) Hulun Buir Sandy Land (modified after Yang and Ding, 2008). The red dashed line indicates the modern summer monsoon boundary (Yang et al., 2019), and the arrows indicate the modern trajectory of the East Asian summer monsoon (EASM) (red) and the East Asian winter monsoon (EAWM) (blue).

Figure 1

Table 1. Accelerator mass spectrometry dating results for core BY from Lake Bayanchagan, northern China

Figure 2

Figure 2. Lithology and median grain-size (Md) data, along with age–depth model data for core BY from Lake Bayanchagan. TOC, total organic carbon.

Figure 3

Figure 3. Core BY data. (a–c) Grain-size distributions (GSDs). (d) C–M plot: C indicates the coarsest percentile of the GSDs (the value at 99%), and M indicates the median (the value at 50%).

Figure 4

Figure 4. (a) Plot of the coefficient of determination (R2) versus the number of grain-size endmembers (EMs) chosen to model the observed grain-size distributions (GSDs), from 1 to 10. (b) Overlay plot of the GSDs of all samples (n = 90) (gray curves) and the three retained EMs (colored curves). (c) Characteristic GSDs of surface sediments collected in the center (left), transitional zone (middle), and nearshore zone (right) of lakes in northern China (modified from Guo et al., 2016). (d) Dominant modes of the GSDs of surface sediment samples from the nearshore zone of lakes (red) (Guo et al., 2016; Xu et al., 2018), loess sediments (blue) (Yang and Ding, 2004), and the offshore-suspension component in sediments from Lake Dali (green) (Xiao et al., 2009).

Figure 5

Figure 5. Records of the proportions of EM1, EM2, EM3, EM4, calcite, dolomite, and carbonate δ18O of core BY. EM, grain-size endmember.

Figure 6

Figure 6. Comparisons of paleoenvironmental records from the northern margin of the EASM and global annual temperature. (a and b) Precipitation reconstructed from pollen data from Lake Bayanchagan (Jiang et al., 2006) and Lake Gonghai (Chen et al., 2015). (c–f) Lake-level records from Lake Dali (Goldsmith et al., 2017), Lake Chagan Nur (Li et al., 2020), and Lake Gonghai based on branched glycerol dialkyl glycerol tetraether (brGDGT) data (Cao et al., 2021), and Lake Bayanchagan (this study). (g and h) Pollen-based temperature reconstruction from Lake Bayanchagan (Jiang et al., 2006) and reconstructed global annual temperature (Marcott et al., 2013). EM2, grain-size endmember 2; TANN, mean annual temperature.