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Implications of the loess record for Holocene climate and human settlement in Heye Catchment, Jiuzhaigou, eastern Tibetan Plateau, Sichuan, China

Published online by Cambridge University Press:  07 October 2022

Amanda H. Schmidt*
Affiliation:
Department of Geosciences, Oberlin College, Oberlin, Ohio 44074, USA
Brian D. Collins
Affiliation:
Department of Earth and Space Sciences, University of Washington, Seattle, Washington 98195, USA
Amanda Keen-Zebert
Affiliation:
Division of Earth and Ecosystem Sciences, Desert Research Institute, 2215 Raggio Parkway, Reno, Nevada 89512, USA
Jade d'Alpoim Guedes
Affiliation:
Scripps Institution of Oceanography, Department of Anthropology, University of California San Diego, La Jolla, California 92034, USA
Anke Hein
Affiliation:
School of Archaeology, University of Oxford, Oxford OX1 3TG, UK
Andrew Womack
Affiliation:
Department of Asian Studies, Furman University, 3300 Poinsett Highway, Greenville, South Carolina 29613, USA
Casey McGuire
Affiliation:
Department of Geosciences, Oberlin College, Oberlin, Ohio 44074, USA
James Feathers
Affiliation:
Department of Anthropology, University of Washington, Seattle, Washington 98195, USA
Lyman Persico
Affiliation:
Geology and Environmental Science, Whitman College, Walla Walla, Washington 99362, USA
Dominic Fiallo
Affiliation:
Department of Geosciences, Oberlin College, Oberlin, Ohio 44074, USA
Ya Tang
Affiliation:
Department of Environment, College of Architecture and Environment, Sichuan University, Chengdu, Sichuan 610065, China
Bruce Simonson
Affiliation:
Department of Geosciences, Oberlin College, Oberlin, Ohio 44074, USA
*
*Corresponding author at: Department of Geosciences, Oberlin College, Oberlin, Ohio 44074. E-mail address: [email protected].
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Abstract

We examine the Holocene loess record in the Heye Catchment on the margins of the Tibetan Plateau (TP) and China Loess Plateau (CLP) to determine: the region to which the Heye Catchment climate is more similar; temporal change in wind strength; and modification of the loess record by mass wasting and human activity. Luminescence and radiocarbon dating demonstrate loess deposited in two periods: >11–8.6 ka and <5.1 ka. The 8.6–5.1 ka depositional hiatus, which coincides with the Mid-Holocene Climatic Optimum, is more similar to the loess deposition cessation in the TP than to the loess deposition deceleration in the CLP. Grain-size analysis suggests the Heye loess is a mixture of at least three different grain-size distributions and that it may derive from multiple sources. A greater proportion of coarse sediments in the older loess may indicate stronger winds compared with the more recent depositional period. Gravel incorporated into younger loess most likely comes from bedrock exposed in slump scarps. Human occupation of the catchment, for which the earliest evidence is 3.4 ka, postdates the onset of slumping; thus the slumps may have created a livable environment for humans.

Type
Research Article
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 (https://creativecommons.org/licenses/by/4.0/), which permits unrestricted re-use, distribution, and reproduction in any medium, provided the original work is properly cited.
Copyright
Copyright © University of Washington. Published by Cambridge University Press, 2022

INTRODUCTION

Situated on the margins of both the Tibetan Plateau (TP) and the China Loess Plateau (CLP), Holocene loess deposits in Jiuzhaigou, northern Sichuan (Fig. 1), provide an opportunity to add to the understanding of the spatial variation in Holocene climate and loess provenance in western China. In addition, the region's oldest archaeological site (d'Alpoim Guedes et al., Reference d'Alpoim Guedes, Lu, Hein and Schmidt2015) is in Jiuzhaigou loess deposits on hillslopes subject to landsliding and co-seismic faulting. Previous investigations of loess in Jiuzhaigou (Wen et al., Reference Wen, Tang, Huang and Gongbo2014, Reference Wen, Chen, Feng and Huang2017) left unanswered questions about the depositional history and provenance of the loess and also the role of hillslope processes and seismic activity in modifying the loess and hillslope topography. Thus, in addition to enhancing understanding of Holocene climate and loess provenance in western China, analysis of the Jiuzhaigou loess record can also provide insight into causal connections between climate, loess deposition, hillslope deformation by landslides and co-seismic faulting, and human inhabitance.

Figure 1. Context map showing (A) location of study area in Asia with area of B outlined; (B) location of Jiuzhaigou and approximate boundaries of other loess regions in China with topography; (C) location of Heye within Jiuzhaigou; and (D) location of study site with specific terraces, longitudinal profiles, approximate boundaries of slump features identified in the field, location of Fig. 3A (marked with a star), and other important features identified. Contours are derived from GDEM data (LP DAAC, 2001).

Analysis of the age of loess and loess–paleosol sequences in the CLP and TP has been widely used to examine regional paleoclimate (e.g., Derbyshire, Reference Derbyshire1982; An et al., Reference An, Kukla, Porter and Xiao1991; Lehmkuhl et al., Reference Lehmkuhl, Klinge, Rees-Jones and Rhodes2000, Reference Lehmkuhl, Schulte, Zhao, Hulle, Protze and Stauch2014; Porter, Reference Porter2001; Lehmkuhl and Owen, Reference Lehmkuhl and Owen2005; Sun et al., Reference Sun, Li, Muhs and Li2007; Pullen et al., Reference Pullen, Kapp, McCallister, Chang, Gehrels, Garzione, Heermance and Ding2011; Stauch et al., Reference Stauch, IJmker, Pötsch, Zhao, Hilgers, Diekmann, Dietze, Hartmann, Opitz and Wünnemann2012), because loess generally deposits during cool and dry periods, whereas paleosols generally form on loess deposits during intervening wet and warm periods (Porter, Reference Porter2001). The grain size of loess may also provide information on wind speed (e.g., An et al., Reference An, Kukla, Porter and Xiao1991; Xiao et al., Reference Xiao, Porter, An, Kumai and Yoshikawa1995; Jiang and Ding, Reference Jiang and Ding2010), aridity and frequency of storms (An et al., Reference An, Kukla, Porter and Xiao1991), loess sources and paleowind directions (Sun et al., Reference Sun, Bloemendal, Rea, An, Vandenberghe, Lu, Su and Liu2004; Prins et al., Reference Prins, Zheng, Beets, Troelstra, Bacon, Kamerling, Wester, Konert, Huang and Ke2009; Yang et al., Reference Yang, Fang, Shi, Lehmkuhl, Song, Han and Han2010a), and the relative importance of low-altitude and high-altitude eolian transport of loess (Sun et al., Reference Sun, Bloemendal, Rea, An, Vandenberghe, Lu, Su and Liu2004; Nottebaum et al., Reference Nottebaum, Stauch, Hartmann, Zhang and Lehmkuhl2015). While loess–paleosol sequences up to 400 m thick in the CLP provide valuable paleoclimate data for at least the last 2.4 Ma (Porter, Reference Porter2001), there has been less study of either Holocene loess in China (Maher et al., Reference Maher, Hu, Roberts and Wintle2003; Kuster et al., Reference Kuster, Hetzel, Krbetschek and Tao2006) or loess in China outside the CLP (Yang et al., Reference Yang, Fang, Shi, Lehmkuhl, Song, Han and Han2010a, Reference Yang, Fang, Yan, Shi, Song and Han2010b; Lehmkuhl et al., Reference Lehmkuhl, Schulte, Zhao, Hulle, Protze and Stauch2014).

In western China, Holocene loess deposits and their associated soils, which span the TP, western Xinjiang Province, the CLP, and south to the Sichuan basin, and climate proxies from cave formations and lake and bog cores generally record a cool and dry climate in the Early and Late Holocene, with an intervening warmer and wetter period during the Mid-Holocene Climatic Optimum (MHCO; Maher et al., Reference Maher, Hu, Roberts and Wintle2003; Kuster et al., Reference Kuster, Hetzel, Krbetschek and Tao2006; Nottebaum et al., Reference Nottebaum, Stauch, Hartmann, Zhang and Lehmkuhl2015), but the loess record also shows within-region variation in the depositional response to climate (An et al., Reference An, Porter, Kutzbach, Wu, Wang, Liu, Li and Zhou2000). For example, in the CLP, loess deposited continuously in both cool, dry periods and warm, wet periods, but deposition slowed and soil formation increased during wetter and warmer conditions (Huang et al., Reference Huang, Pang, Chen and Zhang2003). In other locations, loess accumulated sporadically: in some places, loess accumulated only during cool and dry periods, while in other places, loess accumulated in wet and warm periods, when increased vegetation enhanced the efficacy of dust trapping, with a hiatus in deposition during cool and dry periods (Lehmkuhl et al., Reference Lehmkuhl, Klinge, Rees-Jones and Rhodes2000, Reference Lehmkuhl, Schulte, Zhao, Hulle, Protze and Stauch2014; Kuster et al., Reference Kuster, Hetzel, Krbetschek and Tao2006; Sun et al., Reference Sun, Li, Muhs and Li2007).

Loess tends to become finer the farther it travels, and thus fines downwind (Liu and Ding, Reference Liu and Ding1998; Nugteren and Vandenberghe, Reference Nugteren and Vandenberghe2004; Yang et al., Reference Yang, Fang, Shi, Lehmkuhl, Song, Han and Han2010a). West-to-east fining of loess on the CLP (An et al., Reference An, Kukla, Porter and Xiao1991; Porter, Reference Porter2001) implies a source from the west; various studies suggest a source or mix of sources in the northern TP, the Qaidam basin, the Gobi Desert, and/or the Taklamakan Desert (Derbyshire et al., Reference Derbyshire, Meng and Kemp1998; Sun et al., Reference Sun, Lu and An2000; Maher et al., Reference Maher, Mutch and Cunningham2009; Stevens et al., Reference Stevens, Palk, Carter, Lu and Clift2010; Wu et al., Reference Wu, Zhang, Zhang, Tian and Yao2010; Pullen et al., Reference Pullen, Kapp, McCallister, Chang, Gehrels, Garzione, Heermance and Ding2011), and some argue that loess sources are different during glacial and interglacial times, with deserts dominating during interglacial periods and the TP and Qaidam basin dominating during glacial periods (Pullen et al., Reference Pullen, Kapp, McCallister, Chang, Gehrels, Garzione, Heermance and Ding2011; Fig. 2). Similarly, downwind fining has been used to determine that the loess in the Sichuan basin of northern Sichuan comes from the eastern TP rather than the CLP (Yang et al., Reference Yang, Fang, Shi, Lehmkuhl, Song, Han and Han2010a; Wen et al., Reference Wen, Tang, Huang and Gongbo2014). Jiuzhaigou is located on the margins of the CLP, TP, and Sichuan basin, and prior studies suggest that the loess is sourced from the eastern TP (e.g., Wen et al., Reference Wen, Tang, Huang and Gongbo2014). However, it is unknown if loess source or wind speed changed during the period of loess deposition.

Figure 2. Distribution of grain-size data from Jiuzhaigou (marked on map with bold name; data from Wen et al. [2014]) and previous studies on loess grain size in the region (Lei, Reference Lei1998; Wang et al., Reference Wang, Li and Xiang2003; Sheng, Reference Sheng2010; Yang et al., Reference Yang, Fang, Shi, Lehmkuhl, Song, Han and Han2010a; Stauch et al., Reference Stauch, IJmker, Pötsch, Zhao, Hilgers, Diekmann, Dietze, Hartmann, Opitz and Wünnemann2012; Lehmkuhl et al., Reference Lehmkuhl, Schulte, Zhao, Hulle, Protze and Stauch2014); size of point indicates reported mean grain size. Background elevation is from World Wildlife Fund (2008).

As early as 1977, scientists identified three dominant modes of airborne dust and interpreted these modes as having different transportation mechanisms and source materials (Patterson and Gillette, Reference Patterson and Gillette1977). Although descriptive statistics such as mean, standard deviation, and skewness (Folk, Reference Folk1980) can be calculated for multimodal samples, these statistical metrics are not particularly meaningful for mixed materials (Dietze et al., Reference Dietze, Hartmann, Diekmann, Ijmker, Lehmkuhl, Opitz, Stauch, Wünnemann and Borchers2012). Prior work determining components of mixed grain-size samples relies on end-member modeling analysis (e.g., Dietze et al., Reference Dietze, Hartmann, Diekmann, Ijmker, Lehmkuhl, Opitz, Stauch, Wünnemann and Borchers2012) or single-specimen unmixing (Sun et al., Reference Sun, Bloemendal, Rea, An, Vandenberghe, Lu, Su and Liu2004; Qin et al., Reference Qin, Cai and Liu2005; Xiao et al., Reference Xiao, Chang, Si, Qin, Itoh and Lomtatidze2009, Reference Xiao, Fan, Zhou, Zhai, Wen and Qin2013; Pye, Reference Pye2015), typically using either Weibull (Sun et al., Reference Sun, Bloemendal, Rea, An, Vandenberghe, Lu, Su and Liu2004) or lognormal (Qin et al., Reference Qin, Cai and Liu2005; Xiao et al., Reference Xiao, Chang, Si, Qin, Itoh and Lomtatidze2009; Pye, Reference Pye2015) distributions in the modeling. For multimodal samples, different peaks are attributed to different dust sources (Vandenberghe, Reference Vandenberghe2013). Most studies identify at least two fractions: a coarser fraction interpreted to be from the local area and transported up to a few kilometers during dust storms and a finer fraction interpreted to be non–dust storm dust sourced from locations more than a few kilometers away (Patterson and Gillette, Reference Patterson and Gillette1977; Sun et al., Reference Sun, Bloemendal, Rea, An, Vandenberghe, Lu, Su and Liu2004; Vandenberghe, Reference Vandenberghe2013; Pye, Reference Pye2015). Some studies identify multiple intermediate modes that are interpreted as either a mixture of other modes or additional transport distances (Vandenberghe, Reference Vandenberghe2013). Occasionally submicron-sized dust is observed, and this is interpreted as either anthropogenic particles, weathering materials, or long-range transported dust (Patterson and Gillette, Reference Patterson and Gillette1977; Zhang et al., Reference Zhang, An, Chen, Zhang, Arimoto and Ray1994). CLP loess has two modes that are interpreted as non–dust storm dust transported long distances on the high westerly winds and more locally sourced material that is coarser and transported during dust storms (Sun et al., Reference Sun, Shaw, An, Cheng and Yue1998, Reference Sun, Bloemendal, Rea, An, Vandenberghe, Lu, Su and Liu2004). The northeastern TP loess has two to three modes that are fine sandy, coarse silt, and medium silt in size (Vriend and Prins, Reference Vriend and Prins2005; Nottebaum et al., Reference Nottebaum, Stauch, Hartmann, Zhang and Lehmkuhl2015), and the ratio of the medium silt to coarse silt modes may indicate the relative strength of local winds as opposed to high westerlies transporting finer particle sizes (Nottebaum et al., Reference Nottebaum, Lehmkuhl, Stauch, Hartmann, Wünnemann, Schimpf and Lu2014). The grain size of loess in Jiuzhaigou has not been analyzed in this way, and thus the potential for different contributions from different locations beyond the eastern TP source area previously identified (Wen et al., Reference Wen, Tang, Huang and Gongbo2014) has not been explored, possibly because accessible software to do these calculations only recently became available (Liu et al., Reference Liu, Liu and Sun2021).

The loess record can also contribute to an understanding of the Holocene history of human inhabitance of western China. For example, the timing of loess deposition, and implied climatic fluctuations, can correspond to changes to human habitation in loess regions of western China (An et al., Reference An, Tang, Barton and Chen2005; d'Alpoim Guedes et al., Reference d'Alpoim Guedes, Lu, Hein and Schmidt2015; Wen et al., Reference Wen, Chen, Feng and Huang2017), because agriculturalists can preferentially inhabit areas of loess soils (Henck et al., Reference Henck, Taylor, Lu, Li, Yang, Grub and Breslow2010; Schmidt et al., Reference Schmidt, Li and Tang2017). However, the widespread landslide hazards reported in loess regions (Dijkstra et al., Reference Dijkstra, Rogers, Smalley, Derbyshire, Li and Meng1994; Derbyshire, Reference Derbyshire2001; Wen et al., Reference Wen, Wang, Wang, Zhang, Wu and Wang2005; Zhang and Wang, Reference Zhang and Wang2007; Schmidt et al., Reference Schmidt, Li and Tang2017) also compromise safety (Schmidt et al., Reference Schmidt, Li and Tang2017). Conversely, human inhabitance can modify the loess record; for example, farming can inflate the rate of loess deposition (Roberts et al., Reference Roberts, Wintle, Maher and Hu2001), farming is associated with soil loss in loess areas (Lowdermilk, Reference Lowdermilk1924), and land uses could also potentially destablize loess-mantled slopes (Lacroix et al., Reference Lacroix, Dehecq and Taipe2020).

Here we analyze the loess record in Heye Catchment, Jiuzhaigou, Sichuan, to add to the understanding of how loess deposition varies temporally within western China in response to regional Holocene climate; determine the provenance of loess deposited in the Jiuzhaigou area; understand the mechanisms through which the loess record may have been altered during or following deposition; and better understand Holocene relations between loess and human inhabitance in northwestern Sichuan Province.

STUDY SITE

Our study site is located in Heye Catchment, Jiuzhaigou National Nature Reserve (33°13′N, 103°55′E), a World Heritage Site in the Minshan Mountains (Fig. 1). Mean annual temperature is 6°C and mean annual precipitation is 650 mm, with the majority of precipitation falling during the summer monsoon (Qiao et al., Reference Qiao, Du, Lugli, Ren, Xiao, Chen and Tang2016). The elevation of the Heye Catchment ranges from 2200 m at its outlet to the main Jiuzhaigou valley to 4000 m on the catchment's southern boundary.

The catchment is primarily formed in limestone and dolomite with lesser amounts of phyllite and slate and is locally mantled by up to 10 m of loess (Guo et al., Reference Guo, Yang, Cao, Chen, Song, Zhang, Lu, Cai, An and Jiang2006). The region is tectonically active and was subject to shaking from both the 2008 Wenchuan earthquake and the 2017 Jiuzhaigou earthquake (Sun et al., Reference Sun, Yue, Shen, Fang, Zhan and Sun2018). The Heye and Longkang Faults are near, or cross through, Heye Catchment, but contradictory locations on available, published maps and/or the small scale of those maps (Zhang and Xu, Reference Zhang and Xu1993; Guo et al., Reference Guo, Yang, Cao, Chen, Song, Zhang, Lu, Cai, An and Jiang2006; Burchfiel and Chen, Reference Burchfiel and Chen2012) leaves their precise locations uncertain. The timing of previous movement on the faults is unknown (Zhang and Xu, Reference Zhang and Xu1993). Spatially extensive slump earthflows on east-, south-, and west-facing loess-covered slopes are characterized by terraces with 1- to 10-m-tall risers (Figs. 1 and 2, Supplementary Figs. S1–S10). One of these slump features, on which most of our observations are concentrated, consists of a series of slump blocks having near-horizontal surfaces, or terrace treads, and near-vertical failure planes, or terrace risers; has an area of 10.5 hectares; is covered in loess up to 10 m thick; and may have been destabilized by the Heye Fault (Zhang and Xu, Reference Zhang and Xu1993).

Deformed phyllite and slate are exposed at the base of some of these terrace risers. The exposed bedrock is overlain by either the older of two distinct loess units or by the younger of the two loess units. A red horizon caps the older loess in most exposures. The older loess sometimes includes mollusks, but not charcoal. At one exposure (HY49), measured levels of soil carbon and nitrogen in the red layer are similar to levels in the modern soil, indicating the red layer is likely a paleosol (Henck et al., Reference Henck, Taylor, Lu, Li, Yang, Grub and Breslow2010). Because this stratigraphy is similar throughout the Heye Catchment, and the red layers have the same appearance as the paleosol at HY49, we interpret red layers elsewhere in the catchment to be paleosols. A paleosol is visible in most, but not all, terrace scarps.

A younger loess overlies the paleosol or in some locations directly overlies the exposed bedrock. The younger loess consists of a silty matrix supporting angular, lithic clasts ranging in size from 2 mm particles to 1 m blocks. The paleosol and gravelly loess in some exposures contain archaeological artifacts, usually charcoal, and do not contain mollusks. In one terrace riser exposure (HY49), the paleosol is topped by loess instead of gravelly loess; this is the only location where the paleosol is covered by loess without gravel. All terrace risers contain outcrops of younger loess (typically gravelly loess), and more than half (~60%) contain older loess.

Geologic hazards in Jiuzhaigou, and in Heye Catchment in particular, have been studied due to high levels of tourism and possible risk to visitors. Debris flows in the reserve, which reportedly have increased in frequency in recent years due to human activity (Zhang, Reference Zhang2019), are common. Slope stabilization structures for diverting flows away from tourist areas have been used to mitigate hazards, as in national parks elsewhere in China (Cui et al., Reference Cui, Liu, Tang and Chen2003, Reference Cui, Chen, Liu and Tang2007). In our study area, Heye Catchment, debris-flow hazard management has focused on dams and channels to divert flows away from the relatively large village near the mouth of the valley (Cui et al., Reference Cui, Liu, Tang and Chen2003). In addition to debris flows, the slump earthflow (Fig. 3A) could be a major hazard in the valley if it were to become more active. Some mass-wasting, including slump earthflows and debris flows, may be related to earthquakes in the region (Zhang and Xu, Reference Zhang and Xu1993), an interpretation supported by increases in landslide frequency after both the 2008 Wenchuan and 2017 Jiuzhaigou earthquakes (Han et al., Reference Han, Cheng, An, Fang, Jiang, Chen, Wu, Liu, Xu and Liu2018; Xie et al., Reference Xie, Zheng, Yao, Fang, Zhang, Liu, Wang, Shan, Zhang and Ren2018). Despite the fault running through or near Heye Catchment and long-recognized debris-flow hazards, a GIS-based landslide susceptibility analysis of Jiuzhaigou completed after the 2017 earthquake found that Heye Catchment is at low risk for landslides due to relatively low slope steepness as calculated using remotely sensed digital topographic data (Yi et al., Reference Yi, Zhang, Zhang, Xu, Deng and Li2019, Reference Yi, Zhang, Zhang, Jia and Zhang2020).

Figure 3. Photos of the study valley. (A) View looking north across Heye Catchment showing the series of slump block terraces (tens to hundreds of meters across, up to ~10 m tall). Location given on Fig. 1D with a star. Longitudinal profile line corresponds to transect in Fig. 5. (B) Close-up of the road to the upper parts of the valley. The road was completed in 2008 and was already unpassable in 2011. (C) Deformed bedrock topped by loess exposed in a road cut. (D) Zoom in of box in C showing deformed bedrock. (E) Loess–paleosol–loess sequence at HY49 (location shown in A). (F) Loess–paleosol–gravelly loess sequence that is typical of scarps in Heye Catchment. (G) Deformed bedrock, breccia, loess, and gravelly loess sequence from T2. (H) Loess, stone structure, and gravelly loess sequence shown from T7. (I) Stone structure and a charcoal-rich layer in addition to loess and gravelly loess (T7, to the left of photo in H). Scarp locations for E–I given in Figs. 1 and 6. Sketches of terrace risers are available in Supplementary Figs. S1–S10.

Terraces formed by slumping in the Heye Catchment contain the only known archaeological sites in Jiuzhaigou and the oldest site in the region, Ashaonao (d'Alpoim Guedes et al., Reference d'Alpoim Guedes, Lu, Hein and Schmidt2015). Archaeological evidence from Ashaonao indicates that people occupied the region as early as 3.4 ka (d'Alpoim Guedes et al., Reference d'Alpoim Guedes, Lu, Hein and Schmidt2015). Artifacts are concentrated in the paleosol and slightly above the paleosol in gravelly loess but are not found in the loess underlying the paleosol (Henck et al., Reference Henck, Taylor, Lu, Li, Yang, Grub and Breslow2010; Urgenson et al., Reference Urgenson, Schmidt, Combs, Harrell, Hinckley, Yang, Ma, Li, Lu and MacIver2014; d'Alpoim Guedes et al., Reference d'Alpoim Guedes, Lu, Hein and Schmidt2015; Figs. 3 and 4).

Figure 4. Catalogue ID 07JZGASN_37d. Fragments of a single ceramic vessel from T5. One of these fragments (unknown) is one of the dated sherds.

Previous studies leave open several questions about the loess. There is uncertainty about when the younger loess deposited, whether and how it may have been modified syn- or postdeposition, and what role landsliding and human occupation may have played in any modification. Prior work on the younger, gravelly loess used radiocarbon dates of bulk charcoal, grain-size analyses of the loess (i.e., excluding the coarse lithic component), and rare earth element analysis at the Ashaonao archaeological site to determine that the loess is likely derived from fine-grained glaciofluvial deposits in eastern Tibet during the Late Holocene and was deposited continuously over the last ~5000 years (Wen et al., Reference Wen, Tang, Huang and Gongbo2014, Reference Wen, Chen, Feng and Huang2017), but considers neither the older loess nor the source of gravel in the younger loess. Henck et al. (Reference Henck, Taylor, Lu, Li, Yang, Grub and Breslow2010) interpret the older loess below the paleosol as primary loess deposition, which they date to the late Pleistocene/Early Holocene (11.1 ± 0.7 and 18 ± 1.4 ka), and younger gravelly loess above the paleosol as material remobilized by Late Holocene landslides, with the gravel as having been incorporated during landsliding. Thus, three questions remain about the Heye Catchment loess: (1) What is the source of gravel in the younger loess? (2) Is the younger loess remobilized or primary deposition? (3) When were the two loesses deposited, and what inferences about Holocene climate can they support? Answers would provide insight to Holocene climate in the Jiuzhaigou region; how human habitation may have influenced the character of loess deposits; and how the loess, and the possible role of landsliding in modifying the loess, may have influenced human inhabitance.

METHODS

We conducted fieldwork in the summers of 2007, 2008, 2010, 2011, and 2016. In summer 2008, an archaeological team excavated the Ashaonao archaeological site (Lu et al., Reference Lu, Henck, Taylor and Li2010; Urgenson et al., Reference Urgenson, Schmidt, Combs, Harrell, Hinckley, Yang, Ma, Li, Lu and MacIver2014; Harrell et al., Reference Harrell, Yang, Viraldo, Hagmann, Hinckley and Schmidt2017). In summer 2016, stratigraphy and detailed sections were drawn for seven terrace faces. In summer 2011, we described stratigraphy of 50 terrace scarps and collected charcoal samples for radiocarbon dating and sediment samples for grain-size analysis, thin sections, and optically stimulated luminescence (OSL) dating from 19 of those scarps. Twelve sampled scarps had loess exposed under a paleosol or gravelly loess; eight of these have <1.5 m of exposed loess. The remaining four scarps have between 3.5 and 5 m of exposed loess below a paleosol. While we collected samples from the entire section of the younger loess, we confined our geochronology sampling to the upper 2.8 m of the older loess and grain-size sampling to the upper 3.5 m of the older loess, which is locally up to 5 m thick. The one OSL sample collected deeper than 2.8 m in the older loess was damaged during shipment from China.

We used petrographic analysis to characterize mineralogy of the older loess and the younger, gravelly loess. We embedded in epoxy the sediment from seven samples from terraces HY49 and HY50 collected in the field in 2011, made thin sections from the epoxy-embedded sediment, and analyzed the polished thin sections using a petrographic microscope. To determine percentages of quartz, calcite, and mica, we point counted at least 475 grains from each sample and identified the grains as quartz, calcite, mica, or other.

We used radiocarbon dating of organic material and luminescence dating of sherds and sediments to determine the timing of loess deposition. Charcoal, grain, wood, or bone samples for radiocarbon dating (n = 32) were taken in 2011 and 2016 from anthropogenic layers, paleosols, and the younger loess unit and were analyzed at the University of California Irvine Keck Carbon Cycle Accelerator Mass Spectrometry Laboratory (2011 samples) (Southon and Santos, Reference Southon and Santos2004, Reference Southon and Santos2007; Southon et al., Reference Southon, Santos, Druffel-Rodriguez, Druffel, Trumbore, Xu, Griffin, Ali and Mazon2004) and at the Oxford Radiocarbon Accelerator Unit (2016 samples) (Ramsey et al., Reference Ramsey, Higham and Leach2004; Brock et al., Reference Brock, Higham, Ditchfield and Ramsey2010). After pretreatment with weak HCl, carbon dioxide was extracted and then graphitized on an iron catalyst. We used AMS to measure the graphitized carbon dioxide for 14C/12C ratios. In addition to new radiocarbon ages, we include analysis of 27 previously published radiocarbon ages (Henck et al., Reference Henck, Taylor, Lu, Li, Yang, Grub and Breslow2010; d'Alpoim Guedes et al., Reference d'Alpoim Guedes, Lu, Hein and Schmidt2015; Wen et al., Reference Wen, Chen, Feng and Huang2017). We calibrated new and previously published radiocarbon ages to calendar years with CALIB v. 8.2 using the IntCal20 data set (Reimer et al., Reference Reimer, Austin, Bard, Bayliss, Blackwell, Bronk Ramsey and Butzin2020; Stuiver et al., Reference Stuiver, Reimer and Reimer2022). To facilitate comparison with luminescence ages, we report the probability weighted mean age in thousands of years (ka) before 1950 rather than a calendar date; error bars for these dates span the range reported by OxCal.

Sherds were collected in 2007 and bagged in the field along with small samples of surrounding sediment for radiation measurements. Sediment was sampled in 2011 in metal pipes, the ends of which were then stuffed with paper and sealed with dark tape. We dated sherds using thermoluminescence, infrared stimulated luminescence, and OSL at the University of Washington Luminescence Lab (see Fig. 4 for a photo of a representative sherd sample). We dated sediments using OSL on 4 mm aliquots of 63–90 μm quartz at the Desert Research Institute Luminescence Lab in Nevada using a modified single-aliquot regenerative dose approach (Murray and Wintle, Reference Murray and Wintle2000; see text in Supplementary Material and Supplementary Tables S1–S8 for more details). We also include previously reported luminescence ages for sediments in the Heye Catchment (Henck et al., Reference Henck, Taylor, Lu, Li, Yang, Grub and Breslow2010; Feathers et al., Reference Feathers, Casson, Henck and Chithambo2012). The ages reported by Henck et al. (Reference Henck, Taylor, Lu, Li, Yang, Grub and Breslow2010) were revised in Feathers et al. (Reference Feathers, Casson, Henck and Chithambo2012). The latter paper used fine grains (1–8 μm) for measurement and tried to isolate the quartz signal both by chemical treatment and by application of pulsing methods. Both methods produced similar ages. For this paper, we used the ages from the chemical treatment, because that is the same procedure used by the Desert Research Institute (except on larger grain sizes) for the new ages we report. However, it would not make a significant difference if we used the pulsed ages. The chemical treatment was not applied to three samples from Feathers et al. (Reference Feathers, Casson, Henck and Chithambo2012), so we report the pulsed ages for these. To facilitate comparison with radiocarbon data, all OSL ages are reported in thousands of years (ka) before 1950.

To determine the grain-size distributions of the loess and gravelly loess in Heye Catchment, we collected 50 samples of sediment from 17 terraces, 35 samples of loess below the paleosol and 15 of gravelly loess above the paleosol. After pretreating sediment with hydrogen peroxide to remove organics, we used a Mastersizer laser diffractometer at Whitman College, Walla Walla, Washington, USA, to quantify the grain-size distribution of the <2 mm fraction of samples.

Because all samples had multiple distinct modes, we used QGrain (Liu et al., Reference Liu, Liu and Sun2021)—software that implements the methods described in Sun et al. (Reference Sun, Bloemendal, Rea, An, Vandenberghe, Lu, Su and Liu2004)—to separate grain-size distributions of mixed samples into component parts. QGrain implements a single-specimen unmixing (SSU) model that reports the mean, standard deviation, and fraction of the sample for a defined number of unimodal parametrically distributed component sources. This allows us to determine similarities and differences among samples without having to propose and measure grain-size distributions of possible source regions (Sun et al., Reference Sun, Bloemendal, Rea, An, Vandenberghe, Lu, Su and Liu2004). Thus, while we are unable to identify specific source locations using the SSU model, we are able to determine whether different samples are mixtures of material from the same or different sources. QGrain allows the user to choose between normal and Weibull curve fits and to determine the number of components in the mixture. Prior work on CLP loess grain sizes suggests that Weibull distributions may be more appropriate for loess areas, because modern wind speeds have a Weibull distribution (Sun et al., Reference Sun, Bloemendal, Rea, An, Vandenberghe, Lu, Su and Liu2004). However, all samples had good, statistically significant fits with normal distributions, and thus we used normal distributions rather than Weibull, which requires more parameters to be fit and therefore has the potential to overfit the data.

RESULTS

Mineralogy and petrography

In thin section, loess samples from both the older and younger loess units are composed of individual grains that grade from rounded to subangular. The younger, gravelly loess also contains aggregates of loess particles, lithics, and needle-fiber calcite (Fig. 5C). The older loess samples only contain individual rounded particles and no soil aggregates (Fig. 5D). The composition of older loess is >60% quartz, 8–15% mica, 8–13% calcite, and up to 24% other minerals. The composition of younger gravelly loess is ~50% quartz, ~20% metamorphic lithics, 7–10% mica (muscovite and biotite), 5–13% calcite, and up to 18% other minerals. Pedogenic aggregates are common in the younger, gravelly loess samples taken from all depths of the terrace scarps. Both lithics and aggregates are coarser than grains of primary minerals. Lithics consist of angular fragments of metamorphic rock that have lithologies consistent with having been derived from the bedrock exposed in road cuts and landslide scarps in the Heye Catchment. Younger gravelly loess from samples taken in or slightly above the paleosols have fragments of needle-fiber calcite, a distinctive texture composed of porous masses of acicular calcite crystals in subparallel orientations. In thin sections made of a sample of the paleosol (HY-C), needle-fiber calcite is found in voids that appear to be macropores formed by roots (Fig. 5A and B).

Figure 5. Transmitted-light thin-section micrographs of samples from Heye Catchment: (A and B) taken between crossed polarizers; (C and D) in plane-polarized light. (A) Intact section of the paleosol showing the needle-fiber calcite (labeled NFC). (B) Intact section of the paleosol showing needle fiber calcite (NFC) filling a macropore. (C) HY50 sample above the paleosol showing the lithics (RF) and aggregates (Agg.), which are coarser than quartz grains. (D) HY50 older loess sample below the paleosol.

Geochronology

Radiocarbon and luminescence ages of sediment and pottery sherds, including those from previous studies of Heye loess and terraces (Henck et al., Reference Henck, Taylor, Lu, Li, Yang, Grub and Breslow2010; Feathers et al., Reference Feathers, Casson, Henck and Chithambo2012; d'Alpoim Guedes et al., Reference d'Alpoim Guedes, Lu, Hein and Schmidt2015; Wen et al., Reference Wen, Chen, Feng and Huang2017), fall into two distinct age groups: those from the younger loess are younger than 5.1 ka, and those from the older loess are older than 8 ka (Figs. 6 and 7, Supplementary Fig. S11, Supplementary Tables S9–S12). The paleosol, stratigraphically located between the older and younger loess, yielded dates that fall within the age ranges of both the older and younger loess units, reflecting that the paleosols consist of older loess parent material and younger organics, sediments, and artifacts incorporated over the period of paleosol formation. Thus, we group ages from the paleosol separately from those from the two loess units. The single anomalously old age of paleosol material is likely the age of the older loess parent material, while the younger ages are likely the age of charcoal and sediments incorporated into the older loess during the hiatus in loess deposition.

Figure 6. Overview of stratigraphy, sample locations, and geochronology. (A) Longitudinal profile across the main study area with terraces labeled. HY7 is uphill of HY34, but profile is not available. T1 and T2 are not captured in the longitudinal profile, but approximate location is noted. (B) Stratigraphy of terraces and locations of samples shown. Selected dates are provided (in ka). Details on all data included are in Supplementary Tables S9 and S10. The Ashaonao excavation was at T6. Location of terraces is in Fig. 1.

Figure 7. All ages as a function of depth below stratigraphic surface (i.e., terrace top for gravelly loess and either terrace top or paleosol for loess, depending on stratigraphy of the terrace). 2σ error bars are shown; some are smaller than the symbols used and not visible. Dates with ages >5.1 ka and samples taken from the paleosol were not used in the correlation analysis for date as a function of depth. Data shown includes previously published OSL and 14C data for terraces in Heye Catchment (Henck et al., Reference Henck, Taylor, Lu, Li, Yang, Grub and Breslow2010; Feathers et al., Reference Feathers, Casson, Henck and Chithambo2012; Wen et al., Reference Wen, Tang, Huang and Gongbo2014, Reference Wen, Chen, Feng and Huang2017; d'Alpoim Guedes et al., Reference d'Alpoim Guedes, Lu, Hein and Schmidt2015). Details of all ages shown are in Supplementary Tables S9–S12. **p < 0.01.

Ages of material sampled from young loess linearly increase with depth below the current terrace surface (Fig. 7) and indicate a deposition rate of 0.39 ± 0.05 m/ka. Four sherd dates fall within this trend, implying that the sherds were buried relatively quickly after the pottery was fired. In contrast to the younger loess, the large uncertainties of OSL ages of the older loess preclude defining an age–depth relationship; five samples have statistically indistinguishable ages from 11.1 to 8.58 ka (Fig. 7); the error-weighted mean deposition age of the older loess (excluding the outlier paleosol sample) is 9.6 ± 1.6 ka. The 11–8.6 ka age range for a 2.8 m section of loess could suggest relatively rapid loess deposition, but we cannot determine this with the data available. Because our older loess ages extend to no more than 2.8 m below the surface on deposits up to 5 m thick, we may only have ages for the most recent ~50% of the period of loess deposition and cannot determine the date for onset of loess deposition.

Grain size

Analysis of grain-size data indicates there are multiple components of the Heye loess but that the number of components and relative dominance differs between the younger loess, the upper part of the older loess, and the lower part of the older loess (Figs. 8 and 9, Supplementary Fig. S12, Supplementary Tables S13–S15). The coarse (33–49 μm), medium (6.4–10.5 μm), and fine (0.58–0.71 μm) components are the first, second, and third most dominant components of the younger loess, upper part of the older loess, and lower part of the older loess. However, the lower older loess has more coarse material and less medium and fine material than the upper older loess and younger loess. The younger loess and the upper older loess additionally have a very coarse (316–405 μm) component, and the younger loess also has a very fine (0.038–0.042 μm) component. The mean grain size and fraction of the sample contained in each component are consistent with depth for each of the stratigraphic units (younger loess, upper older loess, and lower older loess). However, the grain size and fraction of sample for a given component differ in the lower older loess compared with the younger loess and upper older loess (Fig. 9).

Figure 8. Example of a grain-size distribution for one sample, the three components, and the sum of the components as determined from QGrain. Each component is a lognormal distribution with the reported mean and standard deviation. Because the distributions are lognormal, the standard deviation is not symmetric in linear space. The mixture of the three lognormal distributions in the proportions noted on the figure sum to best approximate the measured distribution of this sample. Similar curves are available for all grain-size distributions analyzed in Supplementary Fig. S12.

Figure 9. Variations in peak grain sizes and fractions of samples. (A) Mean peak size as a function of depth below the stratigraphic boundary for all samples. Shape size indicates fraction of the sample contained in each peak. (B–F) Box plots with overlying jitters showing variability in fraction of sample contained in each peak. Samples are grouped by stratigraphic unit (lower loess, upper loess in the top 30 cm, and gravelly loess). An asterisk (*) above a box plot indicates that distribution of fraction of sediment contained in the peak for the stratigraphic unit shown in the box plot is statistically significantly (p < 0.05) from the unit with the same color as the star for the peak shown. (G–K) mean grain size for each peak shown as a box plot with overlying jitters for each stratigraphic unit. An asterisk (*) at bottom as described for B–F. Center line is the median for box plots. Box boundaries extend to 25th and 75th percentiles. Whiskers are 1.5 times the interquartile range and outliers (not shown) are beyond that range.

DISCUSSION

We characterized the petrography and grain size for an older and a younger Holocene loess from Heye Catchment, Jiuzhaigou, and used radiocarbon to age charcoal and luminescence to age loess and sherds. In this section, we use the timing of deposition to make inferences about the regional Holocene climate, use grain-size data to infer paleowind conditions, and propose an explanation for the gravel component of the younger loess unit in Heye Catchment. Finally, we explore the environmental–social linkages suggested by the timing of loess deposition, landsliding, and human settlement in the Heye Catchment.

Timing of loess deposition and regional climate implications

Prior studies restricted their attention to the younger of the two loess units (Wen et al., Reference Wen, Tang, Huang and Gongbo2014) or provided a provisional estimate for the depositional period for an older loess (Henck et al., Reference Henck, Taylor, Lu, Li, Yang, Grub and Breslow2010; Wen et al., Reference Wen, Chen, Feng and Huang2017); dates in this study indicate that loess in Heye Catchment deposited in two distinct periods in the Holocene, >11–8.6 ka and 5.1–0.3 ka (Fig. 7), with a break in deposition and commensurate soil formation that corresponds to the MHCO. Because our samples of the older loess unit were restricted to the upper 2.8 m, we cannot define the onset of deposition. Prior studies also left unresolved whether, or how, the younger loess had been subject to syn- or postdepositional modification (Henck et al., Reference Henck, Taylor, Lu, Li, Yang, Grub and Breslow2010); the linear age–depth relationship derived from the younger loess across 11 terraces in the study area suggests the younger loess represents primary loess deposition that started ~5 ka. This conclusion is also supported by an exposure of young loess, above the paleosol, that does not contain gravel (HY49). Thin-section analysis of angular rock fragments contained within the loess show that these rocks have lithologies consistent with the local bedrock; later, we propose a mechanism by which these rock fragments could have been added to the depositing loess rather than being incorporated into remobilized loess.

The older loess (>11–8.6 ka) below the paleosol was deposited during a regional cool and dry period when loess was being deposited elsewhere in western China at least as early as 12 ka (Porter, Reference Porter2001). Closer to Heye, pollen data from the Zoige area, 150 km northwest of Heye Catchment, indicate that the area alternated between woodland and grassland catchment between 10.3 and 7.3 ka (Zhao et al., Reference Zhao, Yu and Zhao2011), suggesting intermittently colder conditions. In addition, several sites in the eastern TP record cool periods around 10 to 9.5 ka (Mischke and Zhang, Reference Mischke and Zhang2010; Wang et al., Reference Wang, Hong, Lin, Hong, Zhu, Wang and Xu2010) and a temporal minimum in moisture on the TP around 9 ka (Ran and Feng, Reference Ran and Feng2013) that corresponds to increased fire frequency (Sun et al., Reference Sun, Zhang, Shen, Chen and Liu2016; Zhao et al., Reference Zhao, Zhao and Qin2017). Thus, loess in the Heye Catchment from >11–8.6 ka deposited during a regionally cool and dry period, as in the TP and the CLP. The timing of the cool and dry period on the CLP is no earlier than 12 ka, suggesting that we capture most of the period of Early Holocene deposition with the samples we measured.

There is a hiatus in the loess record in the Heye Catchment from 8.6–5.1 ka, more similar to the loess record in the TP, where loess deposition stops, than in the CLP, where loess deposition continues, albeit at a slower rate, through this period. The hiatus in loess deposition in the Heye Catchment corresponds to the MHCO, a warm period marked in western China by a slowing or hiatus in loess deposition; increased rates of soil formation, depending on the location (An et al., Reference An, Kukla, Porter and Xiao1991; Porter, Reference Porter2001); higher lake levels (Zhou et al., Reference Zhou, Chen, Pan, Cao, Li and Derbyshire1991); and reduced fire frequency (Sun et al., Reference Sun, Shaw, An, Cheng and Yue1998; Huang et al., Reference Huang, Pang, Chen, Su, Han, Cao, Zhao and Tan2006). There is regional variability in MHCO timing, with the onset of the MHCO in western China and the TP occurring between 10 and 7.5 ka and the end occurring between 5 and 4 ka (An et al., Reference An, Porter, Kutzbach, Wu, Wang, Liu, Li and Zhou2000, Reference An, Feng and Barton2006; Lehmkuhl et al., Reference Lehmkuhl, Klinge, Rees-Jones and Rhodes2000; Feng et al., Reference Feng, An and Wang2006; Wu et al., Reference Wu, Andreas, Bernd, Li and Wang2007; Zhu et al., Reference Zhu, Zhen, Wang, Lü, Xie, Kitagawa and Possnert2009; Schütt et al., Reference Schütt, Berking, Frechen, Frenzel, Schwalb and Wrozyna2010; Bird et al., Reference Bird, Polisar, Lei, Thompson, Yao, Finney, Bain, Pompeani and Steinman2014). It is unclear whether the variability is systematic or due to different responses recorded in different climate proxies. Meta-analyses of regional data suggest that the MHCO is associated with an expansion of the Indian summer monsoon (An et al., Reference An, Feng and Barton2006). The gradual expansion of the range of the Indian summer monsoon could well explain variations in timing of the MHCO around the region. Although the onset of the MHCO seems to vary somewhat, all of these core data suggest that the warm and wet period ended after 5 ka.

Closer to our study area, pollen and charcoal data from cores in two peat bogs 150 km northwest of Jiuzhaigou on the eastern edge of the TP indicate a warm and wet period from 10.8–5.7 ka (Hong et al., Reference Hong, Hong, Lin, Zhu, Shibata, Hirota, Uchida, Leng, Jiang and Xu2003; An et al., Reference An, Feng and Barton2006; Zhao et al., Reference Zhao, Yu and Zhao2011). These data suggest that the warm and wet period started as much as 2 ka earlier on the eastern TP than in Jiuzhaigou, but as with the regional data, it is possible that different climate proxies have different response times to the changing climate. Overall, the period of paleosol formation associated with a hiatus in loess deposition that we identify as dating from 8.6–5.1 ka suggest that climate conditions in the Heye Catchment may have been similar to those of the TP.

Resumption of loess deposition in the Heye Catchment corresponds to a post-MHCO cooling and drying regionally (An et al., Reference An, Porter, Kutzbach, Wu, Wang, Liu, Li and Zhou2000; Feng et al., Reference Feng, An and Wang2006) and locally (Hong et al., Reference Hong, Hong, Lin, Zhu, Shibata, Hirota, Uchida, Leng, Jiang and Xu2003; An et al., Reference An, Feng and Barton2006; Zhao et al., Reference Zhao, Yu and Zhao2011; Wen et al., Reference Wen, Chen, Feng and Huang2017); loess deposition in western China increased in 6–3 ka (Lehmkuhl et al., Reference Lehmkuhl, Klinge, Rees-Jones and Rhodes2000, Reference Lehmkuhl, Schulte, Zhao, Hulle, Protze and Stauch2014; Porter, Reference Porter2001; Huang et al., Reference Huang, Pang and Huang2002; Maher et al., Reference Maher, Hu, Roberts and Wintle2003; An et al., Reference An, Feng and Barton2006; Stauch et al., Reference Stauch, IJmker, Pötsch, Zhao, Hilgers, Diekmann, Dietze, Hartmann, Opitz and Wünnemann2012). On the eastern TP, multiproxy analyses of lake and peat cores corroborate cooling and drying after 6–3.7 ka (Zhang and Mischke, Reference Zhang and Mischke2009; Zhao et al., Reference Zhao, Yu and Zhao2011; Chen et al., Reference Chen, Zheng, Huang, Zheng, Zhang, Zhang and Huang2014), with a slight warming after 3.7 ka (Zhang and Mischke, Reference Zhang and Mischke2009), which we cannot evaluate in our data, because we have only two dates in younger loess that are older than 3.7 ka. Closer to Jiuzhaigou, cores of peat bogs to the west indicate a cool and dry climate after 5 ka (An et al., Reference An, Feng and Barton2006). Overall, the climatic evidence in the region suggests that cool and dry conditions prevailed after 5 ka, when the younger Jiuzhaigou loess was deposited.

The deposition rate of the younger loess in Heye Catchment (0.39 ± 0.05 m/ka) may be inflated by human activity, a phenomenon documented elsewhere in China, because agriculture and land clearing increase erosion on uphill slopes and thus mobilize material deposited on loess deposits (Roberts et al., Reference Roberts, Wintle, Maher and Hu2001). Because archaeological evidence suggests farmers arrived in Heye Catchment relatively soon after the younger loess started to accumulate (d'Alpoim Guedes et al., Reference d'Alpoim Guedes, Lu, Hein and Schmidt2015), it is possible that farming accelerated loess deposition by redistributing material, including loess as well as locally derived sand and gravel, that sloughed from terrace scarps.

Paleowind conditions and loess sources

Although grain-size analyses identify three to five unique components of loess, we interpret three distinct sources and associated transport mechanisms for this material. The coarse fraction, which is present in all samples, has a mean grain size (44 ± 4 μm) that corresponds to grain sizes previously described as locally sourced material transported tens of kilometers (20–65 μm) during discontinuous events such as dust storms (Patterson and Gillette, Reference Patterson and Gillette1977; Sun et al., Reference Sun, Bloemendal, Rea, An, Vandenberghe, Lu, Su and Liu2004; Vandenberghe, Reference Vandenberghe2013).The larger proportion of this sized material in lower older loess implies that surface winds were stronger during the Early Holocene when the lower older loess was deposited. The high westerly winds seem to have transported sediment through the entire period of loess deposition. High westerly winds likely transported the fine and medium (< ~10 μm) material, as has been inferred from similar data elsewhere in China (Sun et al., Reference Sun, Bloemendal, Rea, An, Vandenberghe, Lu, Su and Liu2004). Finally, the very coarse fraction is too coarse to be transported by wind, even during discontinuous events (Patterson and Gillette, Reference Patterson and Gillette1977; Sun et al., Reference Sun, Bloemendal, Rea, An, Vandenberghe, Lu, Su and Liu2004; Vandenberghe, Reference Vandenberghe2013). Thus, we conclude that this fraction is sourced from local bedrock during the same events that incorporated gravel into the younger loess.

Where did the gravel come from?

The existence of slump-block topography during deposition of the younger loess provides a mechanism for the incorporation into the younger loess of gravel and smaller lithics. Bedrock fragments mobilized by ravel and other modes of failure of the bedrock exposed at the base of some slump-block scarps would have fallen onto the relatively horizontal surfaces of slump blocks. As the loess accumulated, these locally derived lithics would then have been incorporated into the loess through bioturbation, pedogenesis, and farming (Fig. 10). As far as we know, a gravelly, lithic-rich loess such as this has not been documented elsewhere.

Figure 10. Conceptual model of how and when gravel became incorporated into loess in Heye Catchment.

In Heye Catchment, deep-seated slumping produces failure planes through both loess and bedrock. This manner of slumping has apparently not been documented in other loess areas (see review by Li and Mo, Reference Li and Mo2019). Loess elsewhere in China experiences a range of landslide types that are attributed to both natural (Dijkstra et al., Reference Dijkstra, Rogers, Smalley, Derbyshire, Li and Meng1994; Wen et al., Reference Wen, Wang, Wang, Zhang, Wu and Wang2005; Zhang and Wang, Reference Zhang and Wang2007) and anthropogenic causes (Henck et al., Reference Henck, Taylor, Lu, Li, Yang, Grub and Breslow2010; Li and Mo, Reference Li and Mo2019). However, rotational slides previously documented in Chinese loess typically only involve the loess deposit itself, while documented landslides that also involve underlying bedrock are typically fast and have a long run-out (see review by Li and Mo, Reference Li and Mo2019).

That gravel is found incorporated into the paleosol at most exposures and paleosols formed during the period of nondeposition in Heye (8.6–5.1 ka) that corresponds with the MHCO indicates the slumping likely started during the MHCO. The MHCO's warmer and wetter climate (An et al., Reference An, Feng and Barton2006) would have promoted slumping, including involvement of the weak bedrock underlying the Early Holocene loess. However, it is also possible that the development of slumping was driven by activity of local faults and by the weighting of the slope by the younger Holocene loess. Slumping that exposes bedrock is the only source of local gravel to incorporate into the loess, and thus the only explanation we have for gravel in the younger loess. Similarly, the absence of gravel in the older loess provides a limiting date of approximately 9 ka for the onset of slumping. Field evidence of active ground deformation indicates the slump feature is active; whether its activity has been continuous or episodic is unknown, but persistent activity over long time periods is characteristic of slump earthflow around the world (Bovis and Jones, Reference Bovis and Jones1992; Mackey et al., Reference Mackey, Roering and McKean2009; Rutter and Green, Reference Rutter and Green2011; Coe, Reference Coe2012; Handwerger et al., Reference Handwerger, Roering and Schmidt2013).

Implications for the history of human inhabitance

The earliest evidence for occupation of the Ashaonao site dates to 3.4 ka (d'Alpoim Guedes et al., Reference d'Alpoim Guedes, Lu, Hein and Schmidt2015), while slumping likely started earlier than 4.1 ka based on the presence of gravel in loess of that age. The occupants of the Ashaonao site arrived after the slump terraces formed and during the subsequent deposition of the younger loess; the oldest date of occupation post-dates the oldest dates of gravelly loess. This raises the possibility that the occupants of the Ashaonao site settled there because of the topography created by the slumping as well as the preference for farming on loess soils (Henck et al., Reference Henck, Taylor, Lu, Li, Yang, Grub and Breslow2010; Schmidt et al., Reference Schmidt, Li and Tang2017). The documented use of wheat and barley at the Ashaonao site (d'Alpoim Guedes et al., Reference d'Alpoim Guedes, Lu, Hein and Schmidt2015) provides further evidence of the site having been viewed as a favorable location for agriculture. The upper older loess is closer in grain-size distribution to the younger loess than the lower older loess. However, both the large gap of time between the older and younger loess deposits and the statistically identical ages of the older loess make it unlikely that there was a smooth transition in climate from the time of the lower and upper older loess. Thus, it seems unlikely that the upper older loess was deposited under different environmental conditions than the lower older loess. However, agricultural activity mixes soils, and thus it is possible that tilling for agriculture mixed younger loess into the upper 30 cm of the upper older loess. Abandonment of the site by ~2 ka (d'Alpoim Guedes et al., Reference d'Alpoim Guedes, Lu, Hein and Schmidt2015) has not been explained; however, a reactivation of slump failure planes provides a possible explanation.

CONCLUSIONS

Loess in Heye Catchment deposited during cool and dry climate from >11 to 8.6 ka, was interrupted during the warmer and wetter MHCO (~8.6–4.1 ka), and resumed in the cooler and drier Late Holocene (<4.1 ka). The loess is a mixture of material of three to five grain-size distributions. The fine and medium distributions (<~10 μm) likely derive from transport by high westerly winds, the coarse distribution (~45 μm) may be windblown material sourced from the eastern TP, and the very coarse fraction is probably fragments of the local bedrock sourced from slump blocks and incorporated into the upper older loess and younger loess by gravity and farming. The relatively large fraction of the coarse grain-size fraction present in the older loess, exclusive of the upper 30 cm of that unit, suggests that the regional winds transporting material from the eastern TP were stronger during the Early Holocene loess deposition (>11–8.6 ka) than during the later Holocene deposition (<5.1 ka). The Late Holocene (<5.1 ka) loess was mixed with gravel sourced from local bedrock exposed in slump scarps; wetter conditions during the MHCO may have contributed to the slumping that formed the slump-block risers that are the presumed source for gravel in the younger loess. Archaeologically important stratigraphic layers in the gravelly loess suggest that human occupation of the site started soon after the Late Holocene loess deposition began, possibly due to the attractive combination of low angle surfaces created by the slump terraces and the loess soils.

Acknowledgments

The authors thank C. Suhr, P. Manley, and C. Dunn for running some of the grain-size analyses; S. Lugli for providing thin sections of the paleosol; N. McMillion for making the loess and gravelly loess thin sections; and Y. M. Liu for assistance with QGrain. We thank A. Corbett, A. Lubeck, J. Southon, C. Bertrand, H. Martinez, and other staff from the UC Irvine Keck Radiocarbon Lab for assistance in preparing and analyzing radiocarbon samples. We thank K. X. Goh, J. Schmidt, and the staff of the Jiuzhaigou National Nature Reserve Science Office for field assistance. The article benefited from conversations with R. Sletten, C. Schreiber, and S. Lugli.

Funding

The authors acknowledge funding from the Mellon Mayes Undergraduate Fellowship Program to DF, National Science Foundation BCS-1632207 to JdG and AH, National Geographic and Chiang Jing Kuo Foundation funding to JdG, a Natural Science Foundation of China postdoctoral fellowship and a Fulbright Student Fellowship to AHS, and a Program of Introducing Talents of Discipline to Universities (B08037) grant to YT.

Supplementary Material

The supplementary material for this article can be found at https://doi.org/10.1017/qua.2022.44

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Figure 0

Figure 1. Context map showing (A) location of study area in Asia with area of B outlined; (B) location of Jiuzhaigou and approximate boundaries of other loess regions in China with topography; (C) location of Heye within Jiuzhaigou; and (D) location of study site with specific terraces, longitudinal profiles, approximate boundaries of slump features identified in the field, location of Fig. 3A (marked with a star), and other important features identified. Contours are derived from GDEM data (LP DAAC, 2001).

Figure 1

Figure 2. Distribution of grain-size data from Jiuzhaigou (marked on map with bold name; data from Wen et al. [2014]) and previous studies on loess grain size in the region (Lei, 1998; Wang et al., 2003; Sheng, 2010; Yang et al., 2010a; Stauch et al., 2012; Lehmkuhl et al., 2014); size of point indicates reported mean grain size. Background elevation is from World Wildlife Fund (2008).

Figure 2

Figure 3. Photos of the study valley. (A) View looking north across Heye Catchment showing the series of slump block terraces (tens to hundreds of meters across, up to ~10 m tall). Location given on Fig. 1D with a star. Longitudinal profile line corresponds to transect in Fig. 5. (B) Close-up of the road to the upper parts of the valley. The road was completed in 2008 and was already unpassable in 2011. (C) Deformed bedrock topped by loess exposed in a road cut. (D) Zoom in of box in C showing deformed bedrock. (E) Loess–paleosol–loess sequence at HY49 (location shown in A). (F) Loess–paleosol–gravelly loess sequence that is typical of scarps in Heye Catchment. (G) Deformed bedrock, breccia, loess, and gravelly loess sequence from T2. (H) Loess, stone structure, and gravelly loess sequence shown from T7. (I) Stone structure and a charcoal-rich layer in addition to loess and gravelly loess (T7, to the left of photo in H). Scarp locations for E–I given in Figs. 1 and 6. Sketches of terrace risers are available in Supplementary Figs. S1–S10.

Figure 3

Figure 4. Catalogue ID 07JZGASN_37d. Fragments of a single ceramic vessel from T5. One of these fragments (unknown) is one of the dated sherds.

Figure 4

Figure 5. Transmitted-light thin-section micrographs of samples from Heye Catchment: (A and B) taken between crossed polarizers; (C and D) in plane-polarized light. (A) Intact section of the paleosol showing the needle-fiber calcite (labeled NFC). (B) Intact section of the paleosol showing needle fiber calcite (NFC) filling a macropore. (C) HY50 sample above the paleosol showing the lithics (RF) and aggregates (Agg.), which are coarser than quartz grains. (D) HY50 older loess sample below the paleosol.

Figure 5

Figure 6. Overview of stratigraphy, sample locations, and geochronology. (A) Longitudinal profile across the main study area with terraces labeled. HY7 is uphill of HY34, but profile is not available. T1 and T2 are not captured in the longitudinal profile, but approximate location is noted. (B) Stratigraphy of terraces and locations of samples shown. Selected dates are provided (in ka). Details on all data included are in Supplementary Tables S9 and S10. The Ashaonao excavation was at T6. Location of terraces is in Fig. 1.

Figure 6

Figure 7. All ages as a function of depth below stratigraphic surface (i.e., terrace top for gravelly loess and either terrace top or paleosol for loess, depending on stratigraphy of the terrace). 2σ error bars are shown; some are smaller than the symbols used and not visible. Dates with ages >5.1 ka and samples taken from the paleosol were not used in the correlation analysis for date as a function of depth. Data shown includes previously published OSL and 14C data for terraces in Heye Catchment (Henck et al., 2010; Feathers et al., 2012; Wen et al., 2014, 2017; d'Alpoim Guedes et al., 2015). Details of all ages shown are in Supplementary Tables S9–S12. **p < 0.01.

Figure 7

Figure 8. Example of a grain-size distribution for one sample, the three components, and the sum of the components as determined from QGrain. Each component is a lognormal distribution with the reported mean and standard deviation. Because the distributions are lognormal, the standard deviation is not symmetric in linear space. The mixture of the three lognormal distributions in the proportions noted on the figure sum to best approximate the measured distribution of this sample. Similar curves are available for all grain-size distributions analyzed in Supplementary Fig. S12.

Figure 8

Figure 9. Variations in peak grain sizes and fractions of samples. (A) Mean peak size as a function of depth below the stratigraphic boundary for all samples. Shape size indicates fraction of the sample contained in each peak. (B–F) Box plots with overlying jitters showing variability in fraction of sample contained in each peak. Samples are grouped by stratigraphic unit (lower loess, upper loess in the top 30 cm, and gravelly loess). An asterisk (*) above a box plot indicates that distribution of fraction of sediment contained in the peak for the stratigraphic unit shown in the box plot is statistically significantly (p < 0.05) from the unit with the same color as the star for the peak shown. (G–K) mean grain size for each peak shown as a box plot with overlying jitters for each stratigraphic unit. An asterisk (*) at bottom as described for B–F. Center line is the median for box plots. Box boundaries extend to 25th and 75th percentiles. Whiskers are 1.5 times the interquartile range and outliers (not shown) are beyond that range.

Figure 9

Figure 10. Conceptual model of how and when gravel became incorporated into loess in Heye Catchment.

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