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Article

Microblade–Based Societies in North China at the End of the Ice Age

by
Meng Zhang
1,2
1
Department of Cultural Heritage and Museology, Fudan University, Shanghai 200433, China
2
Institute of Archaeological Science, Fudan University, Shanghai 200433, China
Quaternary 2020, 3(3), 20; https://doi.org/10.3390/quat3030020
Submission received: 23 May 2020 / Revised: 28 June 2020 / Accepted: 3 July 2020 / Published: 9 July 2020
(This article belongs to the Special Issue Advances in East Asian Agricultural Origins Studies: The Pleistocene to Holocene Transition)
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Abstract

:
One of the most prominent cultural changes during the end of Ice Age in northeastern Asia was the adoption of microblade technology by prehistoric hunter–gatherers to deal with the challenge brought by the climate deterioration and oscillation during and post the Last Glacial Maximum (LGM). The Pleistocene to Holocene transition in North China witnessed the rise of broader spectrum subsistence alongside a series of cultural changes, including adoption of food production, highly mobile lifeways being replaced by sedentism, and the formation of new social organization based on their agricultural land–use patterns. From the perspective of technological change, this project aims to build a socio–ecological framework to examine the cultural change of prehistoric microblade–based societies. In contrast to previous studies, the present research employs a macroecological approach based on Binford’s Constructing Frames of Reference (2001) to reconstruct the behaviors and demography of prehistoric foraging groups, under both modern and LGM climate conditions. Three case studies are conducted to show cultural and technological changes among microblade–based societies in North China during the Pleistocene–Holocene transition.

1. Introduction

During the Pleistocene to Holocene transition, northern China not only witnessed a broad spectrum revolution, intensification, and food production, but also saw the increasing use of durable stone tools linked to a terrestrial plant–dependent economy and the fading of microblade technology linked to highly mobile hunting–dominated lifeways. This process is generalized by Chen and Yu [1,2] as the Paleolithic to Neolithic Transition (PNT) (ca. 15,000–8500 Carbon 14 [C14] BP) in the period after the Late Upper Paleolithic (LUP) (ca. 24,000–15,000 C14 BP). Archaeological records suggest that the early Neolithic sites and sites with cultivation dated to the terminal Pleistocene are both located in relatively small habitats in basins, valleys and foothills of forest–steppe ecotones in the zone between the terrestrial plant threshold and the storage threshold in Lewis Binford’s system (effective temperature [ET] = 12.75 − 15.25 °C) [3]. Agriculture appeared on the North China Plain after humans achieved sophisticated food production technologies during the Middle Holocene. Chen also attributes food production to collectors who practiced logistical strategies in Binford’s forager–collector system [4,5]. Microblade–based societies cannot securely be classified as either foragers or collectors, but according to Chen’s proposition, it seems that the foragers in northern China (if there were such) may have changed their subsistence–settlement system to collecting during the terminal Pleistocene. Current archaeological records are inadequate to fully test this hypothesis, but they can be investigated from a macroecological and analogical viewpoint. Recent research indicates that in northern China during the transition from the unpacked to the packed population condition, hunting-dominated subsistence is expected to become gathering-dominated subsistence in the west (the Loess Plateau), and fishing–dominated subsistence in the east (North China Plain) in which lakes and marshes formed at the end of the Last Ice Age [6]. Most early sites associated with cultivation, ground stone tools, and microblade assemblages are located along the boundary of the gathering–fishing–dominated subsistence line, suggesting that prehistoric foraging societies might have been practicing a mixed economy.
This project only focuses on the relationship between the rise of food production and the decline of microblade–based societies, within the time range from the Last Glacial Maximum to early Holocene. The decline of microblade–based societies cannot be explained as humans migrating out to the frontiers, since the archaeological record in Northern China tends to support an explanation of cultural transition rather than replacement [7]. In the following three sub–topics concerning Northern China, I apply the macroecological approach to study the development and decline of microblade–based societies under the background of the PNT, with the time range from the LGM to the early Holocene.

2. Methodology

The present project employs an analogical research strategy from the anthropological side to evaluate ideas generalized from the archaeological side in the previous studies which mainly followed a cultural–historical paradigm. The main methodology adopted here is macroecology, developed from the late Lewis Binford’s book Constructing Frames of Reference [3], which has been fully standardized by his colleague Amber Johnson as a calculation program EnvCalc 2.1 [8]. This program makes possible the reconstruction of prehistoric hunter–gatherers’ foraging strategies possible on a global scale [9] and the regional scale [7,10,11]. More than 300 variables derived from the program can be grouped as four datasets: (1) Climate, biomes, and habitat; (2) Minimalist terrestrial model; (3) Modelling density-dependent change in hunter-gatherer subsistence; and (4) Growth rate model and density–controlled subsistence (the variables referring to the present research are listed in Table 1). These variables provide an irreplaceable referential framework to help anthropologists predict/project hunter–gatherers’ foraging strategies in a specific region even the foraging populations no longer exist due to cultural transformation or resettlement. For example, several variables, including duration of growing season (GROWC), net aboveground productivity (NAGP), and terrestrial model value for population density (TERMD2), are used to test the hypotheses of the transition from hunter–gathering to farming in the Near East by Binford [3] (pp. 434–464).
The author’s dissertation combines macroecological approach of hunter–gatherers, modern and simulated LGM climatic data, and prehistoric technological organization associated with microblade technology to investigate the role of microblade technology in the development of human adaptations in NE Asia, especially northern China, during the closing millennia of the Upper Pleistocene and across the Pleistocene–Holocene transition [6]. Microblade–based societies as a new concept provides a fresh perspective to characterize a socio-technologically adaptive convergence and radiation of human groups before and after the Last Glacial Maximum (LGM) across NE Asia, in which people adopted microblade technology as the basis for the lithic elements of composite tools/weapons to help organize their lives in their territories, depending, of course, on the availability and quality of local lithic resources.

3. Archaeological Sites Associated with Microblade Technology in North China

North China, in the narrow sense, refers two subregions: the Loess Plateau in the west and the North China Plain in the east. According to archaeological record recovered, the southern limit of distribution of microblade technology during the late Pleistocene is northern side of the Qinling Mountain and the Huaihe River, which is also the north–south division of modern Chinese geography. The northern line of North China is along the Great Wall, which is also the steppe–forest ecotone during the early Holocene.
Since this paper mainly focuses on the period of origin of food production, using Shizitan site as an example to discuss the possibility of plant-intensified exploitation behaviors during the LGM, and at the end, using the Donghulin site to talk about the demise of microblade–based societies, data collected for this project are associated with those sites dated to the Pleistocene–Holocene transition (Table 2). They are mainly Accelerator Mass Spectrometry Carbon 14 (AMS C14) dates, as well as latitudes and longitudes of the sites. To further discuss issues of the broad spectrum revolution, archaeological data are categorized into artifact assemblage, site organization, and biological remains are also shown in Table 3.

4. Microblade–Based Societies during the Last Glacial Maximum

Among archaeological sites in north China associated with microblade assemblages, the Shizitan site is best studied, especially in the terms of interdisciplinary approach focusing on human behaviors at a specific site. Shizitan is located at the Jixian County, SW Shanxi Province. Several localities are distributed along the Qingshuihe River, a tributary of the Yellow River. In recent years, Li Liu, in collaboration with local archaeologists, has been conducting a research project on plant use at this site, based on use–wear and residue analyses, suggesting that prehistoric plant use in northern China can be traced back to the immediately pre–LGM period, about 28 ky cal. BP [31,32,33,34]. The plant use, including harvesting and processing using stone tools, can be divided into 6 phases (Table 4). This work suggests near–continuous exploitation of various plants in the Middle Yellow River Valley (both the Xiachuan site and the Longwangchan site share many material features with the Shizitan site, including microblades, grinding stones, and hematite processing) [31]. Their investigation provides substantial evidence of an early broad–spectrum subsistence strategy in the Upper Paleolithic northern China.
Liu et al. [33] propose the viewpoint, “The trajectory from intensified collection of a wide range of wild plants to domestication of a small number of species was a very long process in north China”, and suggest that it “parallels the transition from the ‘broad spectrum revolution’ to agriculture in the Near East” (pp. 3524). Although they did not use the term “intensification” to generalize this process, plant processing could be seen as a means of food resource intensification, since people need to invest much labor to extract energy from plants, including tubers and seeds. Plant use might suggest a local population packing effect during the LGM in the Middle Yellow River Valley, possibly caused by southward movement of prehistoric peoples from the north or the west, which can be tested as a hypothesis.
The effective temperature (ET) value of the Shizitan site under LGM climatic conditions was below the terrestrial plant threshold, suggesting that the prehistoric foraging societies needed to depend on terrestrial animal resources during the LGM. However, a relatively longer growing season than that of Siberia provides this location higher net above–ground productivity and primary biomass. The Shizitan site is also located in the belt of high secondary biomass, making it a place that possessed plenty of both terrestrial plants and animals. The Qingshuihe River, a small tributary of the Yellow River, also provided people with enough water and aquatic resources for survival, although archaeologists have not found substantial evidence of fishing. The maps in Figure 2, Figure 3, Figure 4, Figure 5 and Figure 6 support the following characterization of the environment and resource use at the Shizitan site:
Around 23,000–18,000 years ago during the LGM, the Qingshui River valley appears to have been an area with a wide range of faunal and floral resources, which attracted small hunting-gathering groups. In addition to hunting, people collected and processed many types of plants, including grass seeds of Triticeae and Paniceae, Vigna beans, D. opposita yam, and T. kirilowii snakegourd roots, among others”.
[32] (p. 5384)
Thus, there is no question that prehistoric hunter–gatherers in this region adopted a mixed economy to satisfy their subsistence requirements, which might have been a general strategy adopted by the peoples during the LGM. The peoples in the lower latitudes or above the subpolar bottleneck (ET = 11.53 °C) have significantly more terrestrial plant resources to utilize.
The question is whether resource intensification on terrestrial plants was practiced during the LGM. According to the maps produced under the growth rate model, unpacked/packed maps show that the location of the Shizitan site is expected to have favored a gathering-dominated economy if population became packed, while it would have favored a hunting–dominated economy if population was unpacked (Figure 7). The ethnographic projected population density map under LGM climatic conditions (Figure 8) suggests that local resource cannot support a high population density in the region where the Shizitan site is located (2–3.033 persons per 100 km2). The patterns resulting from these projections can only be used if hunter–gatherers in this location were organized like recent hunter–gatherers in similar contexts, rather than used to say what the archaeological record actually was. In addition, the packing threshold was developed using data for mobile plant-dependent hunter–gatherers who used no long–term storage—the density threshold at which highly mobile hunters might need to intensify would be lower. In other words, the occupants at the Shizitan site during the LGM might have intensified plant resources especially for storage. But more archaeological evidence is needed to support this hypothesis.
Is there any other possible explanation for the existence of intensive plant use at the Shizitan site? The map of EXDMOV1 (projected total distance moved, scaled for subsistence type, for groups with year round camp to camp mobility pattern) shows that foraging societies in northern China during the LGM had to adopt highly mobile lifeways (comparing with the values of EXDMOV1 under current climatic conditions) (Figure 9). Widespread microblade technology provided them with effective and light composite weaponry to hunt animals; some microblades were used as reaping knife inserts to harvest and process plant resources. Microblade–based societies successfully adapted to the deteriorated environment with relatively lower primary and secondary biomass. The region surrounding the Shizitan has a relatively lower value in terms of expected distance of residential movement (250–300 miles) than its neighboring regions to the east and northwest, which suggests that the occupational duration in one location might be longer and occasional sedentism might have happened during the LGM (Figure 9). Maps of population group size in the subsistence-settlement system (Figure 10) suggest that under LGM climatic conditions, prehistoric foraging societies near the Shizitan site, as well as the Longwangchan and Xiachuan sites, harbored 20–25 persons in the most dispersed settlement phase, 90–120 persons in the most aggregated phase, both less than its eastern neighboring regions. However, the site is located in the zone with high GROUP3 values (400–500 persons), representing a high probability of annual or every several year’s aggregation. Although it is located at the edge of GROUP3 isoline (400 persons), the Qingshuihe–Yellow River system and valley environment offer an advantage with regard to supporting populations, especially aggregations. The Shizitan site and Longwangchan site Locality 1 share almost the same archaeological record, suggesting that prehistoric foragers could easily have crossed the Yellow River in winter on ice under very low temperatures during the LGM and post-LGM Pleistocene (personal communication with Y.-H. Song). The combination of high GROUP3 size in this region and its river valley topography might have made the Shizitan site an ideal place for multi-group aggregations (annually or every few years). This hypothesis is consistent with the archaeological record associated with 285 hearths at Locality S29 (Table 5). Microblade assemblages imply the existence of organized hunting activities, and plant remains studied in Li Liu’s project might prove the association between plant-use behaviors and the activities surrounding the hearths in localities S14 and S29 in further research [31,32,33]. At least, this hypothesis has been partly supported by the recent analysis of Locality S29 [25], but detailed discussion of human aggregation at the Shizitan site is needed.
To sum up, the macroecological approach suggests that intensification might not have existed at the Shizitan site during the LGM. The archaeological record of plant resource exploitation at the Shizitan site indicates that increasing population densities might have made intensification important. However, plants may have been used as supplementary food resources (tubers and wild millet) in daily life. Just as the maps suggested, the plant foods also might have been used to satisfy the regional band requirements of periodic aggregations at the Shizitan site (e.g., Localities S29 and Loc. 14). Unfortunately, because of a lack of lithic refitting research, the hypothesis proposed here remains speculative, although the limited available evidence is suggestive. Limited by the preliminarily published data, testing this hypothesis will require more evidence and question-oriented studies in the future. Plant use at the Shizitan site lasted until the early Holocene, when it was totally abandoned. This is a key site for archaeologists to investigate the process of a potential broad spectrum revolution in the Upper Paleolithic of the Middle Yellow River Basin, and/or to study subsistence-settlement systems and technological organization of microblade-based societies in northern China, since it possesses a complete record from Phase I to Phase III (and some in Phase IV).

5. Broad Spectrum Revolution and Intensification during the Pleistocene–Holocene Transition

The Late Pleistocene and Early Holocene in northern China witnessed the transformation from societies composed of mobile hunter-gatherers equipped with microblade technology to societies equipped with ground stone tools, pottery, food production, and durable dwellings. There have been many studies on these aspects of the transition. Although their appearances can be dated to different specific times in different regions, the formation of agricultural societies can be seen as an emergent event, rather than as the simple overlap of historical events. Chen and Yu [1,2] have termed this period the Paleolithic to Neolithic transition (PNT). They “synthesize a broad range of diagnostic artifacts, settlements, site structure, and biological remains to develop a working hypothesis that agriculture was differentially developed or adopted according to ‘initial conditions’ of habitat, resource structure, and cultural organization” [2]. The authors noted multiple and divergent evolutionary pathways, including northern China (divided at the Taihangshan Mts. into the North China Plain and Loess Plateau). Published data on the chronology and archaeological record of northern China linked to the PNT are presented, clearly showing basic information on diagnostic artifacts, settlements, and site structure associated with social organization, and potential species for domestication Tables 1 and 2 in ref [2], with updated information from recently published results. The two papers by Chen and Yu [1,2] clearly and successfully illustrate cultural change during the PNT of Northern and Southern China, but the authors did not fully apply a macroecological approach in their study.
Since I have shown a series of maps of Northern China for the Shizitan case under LGM conditions, I now only show the corresponding maps under modern climatic conditions, representing the early Holocene. Readers can compare the maps under the two sets of climatic conditions.
The Pleistocene–Holocene transition witnessed a dramatic change from glacial to interglacial, especially after the Younger Dryas. The Terminal Pleistocene after the LGM (starting at 15 ky uncalibrated BP), experienced several climatic phases of relatively warm and cold periods. The Younger Dryas is seen as a stimulus for food production in Northern China and the Near East [7]. In this project, the maps of LGM climatic conditions can be read similarly to those under Younger Dryas conditions, since paleoclimate data suggests that the Younger Dryas was associated with marine isotopic values as low as those of the LGM, but during a much shorter time (about 1300 years, 12.9–11.6 ky cal. BP, or about 600 years, 10.8–10.2 ky uncalibrated BP) [34,35].
Effective temperature dramatically increased and the isoline of the terrestrial plant threshold (ET = 12.75 °C) moved northward. Several sites with the best evidence of food production are located around this isoline (Nanzhuangtou, Zhuannian, and Donghulin) (Figure 2). In contrast to the more localized and fragmentary distribution of growing season isolines under LGM climatic conditions, the length of the growing season dramatically increased, causing more gradual change along latitudes (34° N–40° N) under interglacial conditions (Figure 3), which could help in the formation of belts favorable for stable plant growth and provide a good initial condition for cultivation. The increases of ET and length of growing season resulted in an increase of net above–ground productivity and primary biomass (Figure 4 and Figure 5). Secondary biomass also increased and the central region moved northwest to the modern forest–steppe ecotone along the southwest–northeast China line Figures 5 and 7 in ref [6]. Under modern climatic conditions (early Holocene), the three sites—Nanzhuangtou, Zhuannian, and Donghulin—are all located at the edge of the zones with high values of both primary and secondary biomass, i.e., the transition zone (Figure 6). This phenomenon matches the basic hypothesis advanced by Binford [36,37], that early food production would appear in zones adjacent to areas with the most resources, as a cultural adaptation after mobility declined or ceased to be effective to solve the problems of population growth.
The growth rate model also shows the replacement of terrestrial hunting by gathering and aquatic resource use. Different from the maps under LGM climatic conditions, the subsistence replacement indeed happened during the Pleistocene to Holocene transition—Chen and Yu’s Paleolithic to Neolithic Transition. For northern China (above 30° N), hunting in some places was replaced by the gathering of terrestrial plants (e.g., the Gezishan site in Upper Yellow River Basin), by aquatic resource use (some sites in NE China, such as the Houtaomuga and Shuangta sites), or food production (i.e., Nanzhuangtou, Zhuannian, Donghulin, and other PNT sites, as well as the early Neolithic sites) (Figure 11). The hunters north to the Yanshan Mts. (north to the area of Beijing) retained their hunting–dominated lifeways in a mixed economy with the aid of advanced microblade technology (pencil–shaped microcores) during the early and middle Holocene, perhaps as specialized hunters who exchanged wild meat with neighboring agriculturists, who were in turn finally replaced by pastoralism (about 1000 BC) [38]. The sites of Nanzhuangtou, Zhuannian, and Donghulin are all located in the boundary regions of combined hunting, gathering and fishing under the packed population condition, suggesting that they needed to manage a pluralistic subsistence style. This is supported by the coexistence of microblade–equipped hunting weaponry, pottery, mortars and pestles, and polished tools at the Zhuannian and Donghulin sites. The lack of any microblade assemblage at the Nanzhuangtou site perhaps resulted from the sampling representation of the excavated area (300 out of 2000 m2), or a higher level of food production with a very low level of hunting activities. In addition, evidence of hunting activity calls for further research focus, since some sites are located near water systems and people are expected to have exploited some aquatic resources.
The increase of sedentary life can also be investigated from the viewpoint of a macroecological approach, in terms of projected population density and expected distance of residential movement per year. The Nanzhuangtou, Zhuannian, and Donghulin sites are located at the position of 2/3 packing threshold, and the Bianbiandong cave site is at the packing threshold (Figure 8). Thus, the people at Bianbiandong should have experienced population pressure, while the occupants at sites Nanzhuangtou, Zhuannian, and Donghulin might have experienced population packing if they emphasized hunting during the early Holocene. If they were mobile hunter–gatherers, their mobility should have dramatically decreased from 250/300–350 miles travelled per year during the Younger Dryas (see the EXDMOV1 under LGM climatic conditions), to 200–250 miles per year during the early Holocene (Figure 9). However, if they were sedentary hunter-gatherers their mobility only needed to be 20–40 miles per year during early Holocene (Figure 12). For people who practiced cultivation, the decrease in mobility could focus on a habitat where they could use low-energy food resources through dietary expansion and/or intensification. Therefore, zones with relatively lower primary and secondary biomass compared to neighboring regions associated with optimal resource distribution could serve as new locations in which ‘daughter’ groups could practice food production [37,38]. The lifeways built on sedentism (decreased mobility) favored durable ground/polished and expedient stone tools, rather than highly curated and formal chipped stone tools designed for mobile hunting, because the most important part of the economy became plant resource–use and even cultivation [39,40]. This may explain the disappearance of microblade assemblages in early Neolithic sites in northern China.

6. The Demise of Microblade–Based Societies

The Early Holocene witnessed the disappearance of microblade technologies in North China and the demise of microblade-based societies, although there were a few later sites associated with some of these technologies. However, investigating this cultural process is tough, since those specializing in Neolithic archaeology rarely report those data in the early stages. There are few published data on microblades or microcores in the Neolithic sites (8500–2000 BP) of the northern China cultural region. Although this can be explained as a reporting bias of Neolithic archaeologists, in fact there may be a real absence or very few microblades in the sites. In contrast, Holocene microblade assemblages have been reported in some sites of the Inner Mongolia Steppe, in NE and NW China, on the Tibetan Plateau, and in SW China, all of which are frontier regions of China. Details of the disappearance of microblade technology are little known, let alone the process of the decline and disappearance of microblade–based societies. Among the sites dated to the late PNT after the Younger Dryas event, only the Donghulin site has been researched in detail in Tian-Xing Cui’s [15] dissertation. Microblade assemblages at this site co-exist with ground stone and other percussion tools. By contrast with the classic microblade technology at sites dated to terminal Pleistocene, such as Hutouliang [41], Lingjing [42], Yujiagou [20], and Shuidonggou Locality 12 [28,43], the microcores at the Donghulin site show great variety with unstandardized production methods (Cui used many subtypes to classify them), and some tools show expedient characteristics. The degeneration of microblade production methods might be a result of the transition to a patchy environment composed of forest and grassland. Forest animals dominate the fauna of the Donghulin site (Figure 13), which might impede the use of weaponry equipped with microblades, since open landscape was being replaced by forest and marshes that favor alternative hunting technologies. Paleoethnobotanical research suggests that the occupants at the Donghulin site intensified the use of plant products. Macrobotanical remains including Gramineae, Leguminosae, and Celtis sinensis, and microbotanical remains (starch) on mortars and pestles including Triticeae and wild foxtail millet (Setaria italica), imply a broad–spectrum economy and intensification. Sedentism had already been adopted by the late PNT occupants, which also reduced the use of microblade technology designed for highly mobile lifeways.
To sum up, the current published archaeological record is inadequate to explain the cultural process of microblade technology disappearance in northern China. However, the correlation between the decline of microblade–based societies and the rise of agriculture is certain, and we need further detailed studies to build the links.

7. Conclusions

This paper does not aim to provide a synthesis of archaeological sites associated with microblade technology, but rather to explore the mechanisms of cultural change for prehistoric hunter–gatherers equipped with microblade products during and after the Last Glacial Maximum. Three sequential stages of microblade–based societies are addressed in this paper, and the conclusion can be summarized as follows:
(1) Based on the calculated results in the EnvCalc2.1 program under LGM climatic conditions, especially the variables BIO5 (primary biomass), WDEN (projected density) and EXGRP3 (annual or several-year aggregation size), the plant use at the Shizitan site might not be linked with resource intensification, but rather with social group aggregation in a region with relatively high productivity of plant resources. However, the equifinality in the archaeological explanation needs to be further studied to evaluate alternative hypotheses, including the scale and seasonality of human aggregation and the possibility of resource intensification.
(2) The sites dated to the Pleistocene–Holocene transition experienced Paleolithic to Neolithic technological and economic transitions, marked by use of pottery, appearance of permanent settlements, and widespread adoption of ground stone tools. The broad spectrum revolution and subsistence intensification can be explained within the framework of the macroecological approach; the replacement of the hunting-dominated economy by a gathering-and/or-fishing-dominated economy is linked with population growth during the interglacial or interstadial periods, matching the maps under the packed condition of regional population. Decreased mobility also provided the occupants an opportunity to use low-energy food resources through dietary expansion and/or intensification. Against this background, microblade-based weaponry became less significant in daily life due to the previously open landscape becoming more closed, leading to a decrease in the density of large herd ungulates, and durable ground/polished and expedient stone tools were favored.
(3) The disappearance of microblade technology accompanies the end of microblade-based societies in North China. At present, there are very few publications on this period but the microblade assemblages at the Donghulin site show much less standardization in microblade production. This might be linked with the full adaptation of sedentary lifeways and significant decreases of wild ungulates during the Neolithic.
The present research provides a case study using the macroecological approach for exploring the technological change of prehistoric foraging societies equipped with microblade technology in North China, facing dramatic climatic oscillation during the end of the Ice Age. Although a research framework has been built in this project, more substantial archaeological research is needed using systematic observation of interassemblage variability, a well–controlled chronological database, detailed studies on the function of targeted tools with the aid of use–wear analysis, and interdisciplinary projects on land–use patterns and resource exploitation to test hypotheses proposed here on the cultural dynamics of the microblade-based societies.

Funding

This research received no external funding

Acknowledgments

This paper is developed from the author’s dissertation at the Department of Anthropology, University of New Mexico, under the supervision of Lawrence Straus, Bruce Huckell, Robert Hitchcock, Amber Johnson, and Pei–Lin Yu. The research was supported by the Binford Fellowship, TAships, CSC, Moore Research Grant, and the CCKF when I was in the PhD program at the UNM. This project is also supported by the Subject Fundamental Development Project of Fudan University. Yanhua Song and Fagang Wang as well as other archaeologists showed me Paleolithic collections in Shanxi and Hebei Provinces. Tianxing Cui gave me permission to use the archaeological profile as Figure 13 in the present paper. The reviewers provided valuable and constructive suggestions. In addition, this paper is dedicated to Lewis Binford and Ofer Bar–Yosef, who provided me with a toolkit and precious suggestions to deal with the microblade technology issue in prehistory.

Conflicts of Interest

The author declares no conflict of interest.

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Figure 1. Archaeological sites dated to Pleistocene-Holocene transition in Northern China. PNT sites: 1 Nanzhuangtou; 2 Zhuannian; 3 Donghulin; 4 Lijiagou; 5 Bianbiandong; 6 Kengnan; 7 Yujiagou; 8 Ma’anshan; 9 Hutouliang; 10 Mengjiaquan; 11 Jijitan; 12 Xueguan; 13 Lingjing LUP sites: 14 Shizitan; 15 Xiachuan; 16 Longwangchan Other sites: 17 Xishi; 18 Shuidonggou Locality 12; 19 Dadiwan, Component 4; 20 Gezishan; 21 PY-04.
Figure 1. Archaeological sites dated to Pleistocene-Holocene transition in Northern China. PNT sites: 1 Nanzhuangtou; 2 Zhuannian; 3 Donghulin; 4 Lijiagou; 5 Bianbiandong; 6 Kengnan; 7 Yujiagou; 8 Ma’anshan; 9 Hutouliang; 10 Mengjiaquan; 11 Jijitan; 12 Xueguan; 13 Lingjing LUP sites: 14 Shizitan; 15 Xiachuan; 16 Longwangchan Other sites: 17 Xishi; 18 Shuidonggou Locality 12; 19 Dadiwan, Component 4; 20 Gezishan; 21 PY-04.
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Figure 2. Archaeological sites dated to the Pleistocene to Holocene transition on the maps of effective temperature (ET) in Northern China under LGM and modern climatic conditions.
Figure 2. Archaeological sites dated to the Pleistocene to Holocene transition on the maps of effective temperature (ET) in Northern China under LGM and modern climatic conditions.
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Figure 3. Archaeological sites dated to the Pleistocene to Holocene transition on the maps of growing season (GROWC) of Northern China under LGM and modern climatic conditions.
Figure 3. Archaeological sites dated to the Pleistocene to Holocene transition on the maps of growing season (GROWC) of Northern China under LGM and modern climatic conditions.
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Figure 4. Archaeological sites dated to the Pleistocene to Holocene transition on the maps of net above–ground productivity (NAGP) in Northern China under LGM and modern climatic conditions.
Figure 4. Archaeological sites dated to the Pleistocene to Holocene transition on the maps of net above–ground productivity (NAGP) in Northern China under LGM and modern climatic conditions.
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Figure 5. Archaeological sites dated to the Pleistocene to Holocene transition on the maps of primary biomass (BIO5) of Northern China under LGM and modern climatic conditions.
Figure 5. Archaeological sites dated to the Pleistocene to Holocene transition on the maps of primary biomass (BIO5) of Northern China under LGM and modern climatic conditions.
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Figure 6. Archaeological sites dated to the Pleistocene to Holocene transition on the maps of secondary biomass (expected moderate body–size ungulate biomass, EXPREY) of northern China under LGM and modern climatic conditions.
Figure 6. Archaeological sites dated to the Pleistocene to Holocene transition on the maps of secondary biomass (expected moderate body–size ungulate biomass, EXPREY) of northern China under LGM and modern climatic conditions.
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Figure 7. Archaeological sites dated to the Pleistocene to Holocene transition on the maps of projected unpacked and packed HG subsistence specialty (UPSUBSPE and D1PSUBSPE) in northern China under LGM climatic conditions.
Figure 7. Archaeological sites dated to the Pleistocene to Holocene transition on the maps of projected unpacked and packed HG subsistence specialty (UPSUBSPE and D1PSUBSPE) in northern China under LGM climatic conditions.
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Figure 8. Archaeological sites dated to the Pleistocene to Holocene transition on the maps of projected HG population density (WDEN) of northern China under LGM and modern climatic conditions.
Figure 8. Archaeological sites dated to the Pleistocene to Holocene transition on the maps of projected HG population density (WDEN) of northern China under LGM and modern climatic conditions.
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Figure 9. Archaeological sites dated to the Pleistocene to Holocene transition on the maps of expected distance of residential movement per year of hunter–gatherers (EXDMOV1) in northern China under LGM and modern climatic conditions.
Figure 9. Archaeological sites dated to the Pleistocene to Holocene transition on the maps of expected distance of residential movement per year of hunter–gatherers (EXDMOV1) in northern China under LGM and modern climatic conditions.
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Figure 10. Archaeological sites dated to the Pleistocene to Holocene transition on the maps of expected hunter–gatherer group size in northern China under LGM climatic conditions.
Figure 10. Archaeological sites dated to the Pleistocene to Holocene transition on the maps of expected hunter–gatherer group size in northern China under LGM climatic conditions.
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Figure 11. Archaeological sites dated to the Pleistocene to Holocene transition on the maps of projected unpacked and packed hunter–gatherer subsistence specialty (UPSUBSPE and D1PSUBSPE) in northern China under modern climatic conditions.
Figure 11. Archaeological sites dated to the Pleistocene to Holocene transition on the maps of projected unpacked and packed hunter–gatherer subsistence specialty (UPSUBSPE and D1PSUBSPE) in northern China under modern climatic conditions.
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Figure 12. Archaeological sites dated to the Pleistocene–Holocene transition on the map of EXDMOV2 (expected distance of residential movement per year of hunter–gatherers with central location or who are primarily sedentary) in northern China under modern climatic conditions.
Figure 12. Archaeological sites dated to the Pleistocene–Holocene transition on the map of EXDMOV2 (expected distance of residential movement per year of hunter–gatherers with central location or who are primarily sedentary) in northern China under modern climatic conditions.
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Figure 13. Number of identified specimens (NISPs) and minimal number of individuals (MNIs) of fauna at the Donghulin site (permission from Dr. Tian–Xing Cui).
Figure 13. Number of identified specimens (NISPs) and minimal number of individuals (MNIs) of fauna at the Donghulin site (permission from Dr. Tian–Xing Cui).
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Table
Table 1. Key variables used in this research project.
Table 1. Key variables used in this research project.
Topics and ModelsHunter-GatherersVariableDefinition 1
Climate, Biomes, and HabitatClimateGROWCLength of growing season: Length of growing season. Number of months with mean temperatures greater than 8 degrees Celsius
ETEffective temperature: a measure designed to examine biological implications of ambient warmth
Biomes and habitatNAGPNet above–ground productivity
BIO5Primary biomass
EXPREYExpected moderate body-size ungulate biomass (kg/km2)
Minimalist Terrestrial ModelPopulation density TERMH2Number of persons per 100 km2 unit who could be supported by the ungulate resources alone
TERMG2Number of persons per 100 km2 unit who could be supported by the plant resources alone
TERMD2Population density expected at a particular location, expressed in terms of persons per 100 km2
Subsistence specialtySUBSPX2Terrestrial model expected subsistence bias for use with ethnographic cases
h = hunting, g = gathering, m = mixed, u = uninhabited
Modelling Density–Dependent Change in Hunter–Gatherer SubsistenceSubsistenceSUBSPEOrdinal classification of projected hunter–gatherer subsistence specialty
1 = hunting, 2 = gathering, 3 = fishing
Population densityWDENProjected hunter-gatherer density
Group sizeEXGRP1Projected mean size of smallest residential group, segmented by group pattern and subsistence specialization bias
EXGRP2Projected mean size of largest residential seasonal camps, segmented by group pattern and subsistence specialization bias
EXGRP3Projected mean size of periodic regional camps, segmented by group pattern and subsistence specialization bias
MobilityEXDMOV1Projected total distance moved, scaled for subsistence type, for groups with year round camp to camp mobility pattern
EXDMOV2Projected total distance moved, scaled for subsistence type, for groups who move into and out of a central location or who are primarily sedentary
Growth Rate Model and Density–Controlled SubsistenceSubsistence specialty against the unpacked backgroundUPSUBSPEOrdinal classification of projected unpacked HG subsistence specialty (packing multiplier = 0.5)
1 = hunting, 2 = gathering, 3 = fishing
Subsistence specialty against the packed background D1PSUBSPEOrdinal classification of projected packed HG subsistence specialty (packing multiplier = 1)
1 = hunting, 2 = gathering, 3 = fishing
Note: 1 from “variables used or calculated in EnvCalc2.1 program (except UPSUBSPE and D1PSUBSPE) [8].
Table
Table 2. Chronometric dates of the sites in the Paleolithic to Neolithic Transition (PNT) group.
Table 2. Chronometric dates of the sites in the Paleolithic to Neolithic Transition (PNT) group.
SiteLayerMaterialMethodLab. No.DatesCal. BC (2–sigma)Reference
Nanzhuangtoulayer 5–6woodAMS C14BK861209875 ± 16010,028–9112 (87.2%)
9083–9041 (1.1%)
9026–8838 (7.1%)		Yuan et al. [12]
woodAMS C14Bk861219690 ± 959298–8799 (95.4%)Yuan et al. [12]
woodAMS C14BK870939810 ± 1009669–9116 (86.1%)
9076–9055 (0.6%)
9016–8843 (8.7%)		Yuan et al. [12]
woodAMS C14BK890649850 ± 909752–9722 (1%)
9692–9146 (94.4%)		Yuan et al. [12]
Layer 6charcoalAMS C14BK8707510,510 ± 10010,731–10,149 (95.4%)Yuan et al. [12]
Layer 5siltAMS C14BK870869980 ± 1009983–9941 (1.6%)
9877–9266 (93.8%)		Yuan et al. [12]
siltAMS C14BK8708810,815 ± 14011,096–10,576 (94%)
10,518–10,485 (1.4%)		Yuan et al. [12]
Zhuannian AMS C14 9200 ± 1008701–8676 (1.4%)
8646–8250 (94%)		Ren and Wu [13]
AMS C14 c.9800 Yu [14]
DonghulinM1 (Burial 1)human boneAMS C14 9570 ± 709216–8755 (95.4%)Cui [15]
Layer 8, T3charcoalAMS C14 9180 ± 808608–8273 (95.4%)Cui [15]
Layer 7, T3charcoalAMS C14 9155 ± 408528–8521 (0.8%)
8473–8282 (94.6%)		Cui [15]
Layer 4, T3charcoalAMS C14 8780 ± 908205–8035 (20.6%)
8016–7606 (74.8%)		Cui [15]
Layer 4, T9charcoalAMS C14 8805 ± 508204–8102 (13.8%)
8096–8036 (5.6%)
8015–7711 (75.6%)
7692–7685 (0.4%)		Cui [15]
Layer 3, T9charcoalAMS C14 8772 ± 408165–8138 (1.5%)
7973–7647 (93.9%)		Cui [15]
Layer 2, T9PineappleAMS C14 8885 ± 558240–7825 (95.4%)Cui [15]
Lijiagou (north area)Layer 6charcoalAMS C14BA0914948950 ± 408272–8166 (44.3%)
8131–7970 (51.1%)		He et al. [16]
Layer 5charcoalAMS C14BA0914178015 ± 357064–6814 (95.4%)He et al. [16]
Layer 4charcoalAMS C14BA0914167740 ± 406642–6483 (95.4%)He et al. [16]
Lijiagou (south area)Layer 4charcoal (3 samples)AMS C1410300–10500 cal. BP Zhao et al. [17]
Bianbiandong Human skullAMS C14BA043088675 ± 407786–7768 (2%)
7759–7592 (93.4%)		Sun et al. [18]
Human skullAMS C14BA043098670 ± 307738–7597 (95.4%)Sun et al. [18]
Animal skullAMS C14BA0431010,030 ± 409800–9786 (1.2%)
9773–9381 (94.2%)		Sun et al. [18]
Human skullAMS C14BA043178730 ± 507941–7605 (95.4%)Sun et al. [18]
Area I Layer 3AAnimal boneAMS C14BA072268505 ± 457596–7507 (95.4%)Sun et al. [18]
Area I Layer 3BAnimal boneAMS C14BA072278585 ± 407704–7700 (0.5%)
7681–7541 (94.9%)		Sun et al. [18]
Area I Layer 4Animal boneAMS C14BA072288180 ± 457321–7067 (95.4%)Sun et al. [18]
Layer 2Animal boneAMS C14BA072296120 ± 455211–4944 (95.4%)Sun et al. [18]
CollectedAnimal boneAMS C14BA072306305 ± 405364–5214 (95.4%)Sun et al. [18]
KengnanLayer 2, 3 C14~10,000–9000 BP (calibrated?) Li, Song [19]
Yujiagou OSL 18 ka–14 ka Mei [20]
Ma’anshan 1
HutouliangTerrace IIboneConv. C14PV–015610,690 ± 12010,879–10,428 (93.3%)
10,391–10,352 (0.8%)
10,335–10,287 (1.2%)		IA–CASS [21]
Layer 6 (upper)polymineralOSL 9.2 ± 1.4 ka Nagatomo et al. [22]
polymineralOSL 9.0 ± 1.3ka Nagatomo et al. [22]
Mengjiaquan
Jijitan 1
Xueguan charcoalConv.C14BK8101613,170 ± 15014,274–13,371 (95.4%)IA–CASS [21]
LingjingLayer 5charred materialAMS C14IAAA–9212311,360 ± 5011,350–11,145 (95.4%)Li et al. [23]
Layer 5charred materialAMS C14IAAA–9212411,490 ± 5011,502–11,285 (95.4%)Li et al. [23]
Layer 5charred materialAMS C14IAAA–9212511,930 ± 5012,009–11,930 (8.6%)
11,915–11,625 (86.8%)		Li et al. [23]
Layer 5charcoalAMS C14IAAA–10008028,610 ± 12031,223–30,139 (95.4%)Li et al. [23]
Layer 5burnt boneAMS C14IAAA–10008211,520 ± 4011,499–11,331 (95.4%)Li et al. [23]
Layer 5burnt boneAMS C14IAAA–10263411,400 ± 5011,406–11,168 (95.4%)Li et al. [23]
Layer 5charcoalAMS C14IAAA–10263511,600 ± 5011,601–11,365 (95.4%)Li et al. [23]
Layer 5charred material on sherdAMS C14IAAA–102636 8610 ± 407723–7576 (95.4%)Li et al. [23]
Layer 5charred material (charcoal?)AMS C14IAAA–10263810,180 ± 4010,106–9757 (95.4%)Li et al. [23]
Layer 5charred material (charcoal?)AMS C14IAAA–10263911,710 ± 5011,763–11,721 (3.2%)
11,681–11,483 (92.2%)		Li et al. [23]
Layer 5charred material (charcoal?)AMS C14IAAA–10264011,860 ± 5011,822–11,613 (95.4%)Li et al. [23]
Layer 5burnt boneAMS C14IAAA–10264111,290 ± 5011,307–11,115 (95.4%)Li et al. [23]
Layer 5charred material (charcoal?)AMS C14IAAA–10264210,970 ± 5011,032–10,772 (95.4%)Li et al. [23]
Layer 5charred material (burnt bone?)AMS C14IAAA–10264311,280 ± 5011,302–11,109 (94.4%)Li et al. [23]
Layer 5Charcoal (?)AMS C14IAAA–10264411,550 ± 5011,525–11,335 (95.4%)Li et al. [23]
Layer 5charred material (?)AMS C14IAAA–10264511,470 ± 5011,489–11,251 (95.4%)Li et al. [23]
Layer 5charcoalAMS C14IAAA–10264711,220 ± 5011,242–11,046 (95.4%)Li et al. [23]
Layer 5charcoalAMS C14IAAA–10264811,520 ± 5011,511–11,321 (95.4%)Li et al. [23]
Layer 5charred material (burnt bone?)AMS C14IAAA–10264911,800 ± 5011,801–11,587 (89%)
11,576–11,532 (6.4%)		Li et al. [23]
Layer 5charred material (charcoal?)AMS C14IAAA–10265011,860 ± 5011,822–11,613 (95.4%)Li et al. [23]
Shizitan, Locality S29Layer 1boneAMS C14BA1012911,175 ± 6011,203–10,903 (95.4%)Song [24]
Layer 2 (203 cm deep)BoneAMS C14BA10141414,650 ± 7016,077–15,674 (95.4%)Song and Shi [25]
Layer 2 (200–206 cm deep)BoneAMS C14BA1013215,725 ± 8017,238–16,844 (95.4%)Song and Shi [25]
Layer 2 (248 cm deep)CharcoalAMS C14BA1013116,760 ± 6518,494–18,058 (95.4%)Song and Shi [25]
Layer 2 (276 cm deep)BoneAMS C14BA10141615,390 ± 7016,862–16,553 (95.4%)Song and Shi [25]
Layer 3 (282 cm deep)BoneAMS C14BA10141917,200 ± 5018,987–18,615 (95.4%)Song and Shi [25]
Layer 3 (303 cm deep)BoneAMS C14BA1013317,360 ± 6019,232–18,762 (95.4%)Song and Shi [25]
Layer 4 (465 cm deep)BoneAMS C14BA10142017,500 ± 7019,449–18,936 (95.4%)Song and Shi [25]
Layer 4 (469 cm deep)BoneAMS C14BA1013416,170 ± 5017,754–17,367 (95.4%)Song and Shi [25]
Layer 4 (605 cm deep)BoneAMS C14BA1013516,930 ± 5018,649–18,268 (95.4%)Song and Shi [25]
Layer 4 (620 cm deep)BoneAMS C14BA10142216,750 ± 8018,511–18,030 (95.4%)Song and Shi [25]
Layer 4 (622 cm deep)BoneAMS C14BA10142118,570 ± 6020,638–20,363 (95.4%)Song and Shi [25]
Layer 4 (624 cm deep)BoneAMS C14BA10142319,210 ± 8021,495–20,943 (95.4%)Song and Shi [25]
Layer 4 (640 cm deep)ToothAMS C14BA1013617,040 ± 6018,804–18,391 (95.4%)Song and Shi [25]
Layer 5 (772 cm deep)BoneAMS C14BA1013718,360 ± 7020,477–20,025 (95.4%)Song and Shi [25]
Layer 5 (787 cm deep)CharcoalAMS C14BA1048520,420 ± 8022,973–22,319 (95.4%)Song and Shi [25]
Layer 5 (750.5 cm deep)BoneAMS C14BA10142619,650 ± 10022,028–21,432 (95.4%)Song and Shi [25]
Layer 5 (751.5 cm deep)CharcoalAMS C14BA10142719,510 ± 7021,815–21,244 (95.4%)Song and Shi [25]
Layer 5 (750.5 cm deep)CharcoalAMS C14BA10142819,940 ± 7022,284–21,811 (95.4%)Song and Shi [25]
Layer 5 (804 cm deep)CharcoalAMS C14BA10142919,710 ± 8022,050–21,535 (95.4%)Song and Shi [25]
Layer 5 (801.8 cm deep)CharcoalAMS C14BA10143019,860 ± 7022,185–21,707 (95.4%)Song and Shi [25]
Layer 6 (968 cm deep)BoneAMS C14BA10143118,140 ± 8020,326–19,812 (95.4%)Song and Shi [25]
Layer 6 (964 cm deep)CharcoalAMS C14BA10143320,410 ± 8022,961–22,306 (95.4%)Song and Shi [25]
Layer 6 (964 cm deep)BoneAMS C14BA10143419,850 ± 8022,190–21,680 (95.4%)Song and Shi [25]
Layer 6 (961.5 cm deep)ToothAMS C14BA12195420,155 ± 4522,471–22,067 (95.4%)Song and Shi [25]
Layer 6 (1004 cm deep)CharcoalAMS C14BA1048720,500 ± 10023,117–22,388 (95.4%)Song and Shi [25]
Layer 6 (1004 cm deep)BoneAMS C14BA1048818,090 ± 7020,242–19,733 (95.4%)Song and Shi [25]
Layer 6 (1004 cm deep)BoneAMS C14BA12195118,280 ± 4520,393–19,978 (95.4%)Song and Shi [25]
Layer 6 (1026 cm deep)CharcoalAMS C14BA10143820,350 ± 9022,886–22,201 (95.4%)Song and Shi [25]
Layer 7 (1160 cm deep)BoneAMS C14BA12196021,690 ± 8024,151–23,840 (95.4%)Song and Shi [25]
Layer 7 (1160 cm deep)BoneAMS C14BA10143919,650 ± 8021,996–21,465 (95.4%)Song and Shi [25]
Layer 7 (1160 cm deep)CharcoalAMS C14BA10144220,010 ± 7022,353–21,901 (95.4%)Song and Shi [25]
Layer 7–8 boundary (1355 cm deep)BoneAMS C14BA10144520,510 ± 9023,107–22,414 (95.4%)Song and Shi [25]
Layer 8 (1425 cm deep)CharcoalAMS C14BA10144424,185 ± 9026,575–25,976 (95.4%)Song and Shi [25]
Shizitan, Locality S5Layer 1boneAMS C14BA1014049220 ± 508565–8299 (95.4%)Song and Shi [26]
Some other sites dated to PNT time range, but not related to origin of food production (data shown below, recorded as others in the maps)
Shuidonggou Locality 12Layer 11charcoalAMS C14LUG06–549797 ± 919654–9580(2.5%)
9548–9478 (2.3%)
9465–9117 (80.9%)
9074–9056 (0.5%)
9013–8911 (7%)
8905–8845 (2.2%)		Liu et al. [27]
Layer 11quartzOSLIEE111011.6 ± 0.6 ka Nagatomo et al. [22]
L1–L5cultural layers formed between 11,000 and 12,000 years ago, starting at the middle of the Younger Dryas Yi [28]
Gezishan 53S/0WStratum E Beta 9724110,230 ± 5010,189–9810 (95.4%)Elston et al. [29]
Stratum E/F Beta 8673111,620 ± 7011,626–11,353 (95.4%)Elston et al. [29]
Stratum G2 Beta 9724212,710 ± 7013,398–12,857 (95.4%)Elston et al. [29]
Gezishan 3N/3WStratum D Beta 8673210,020 ± 609818–9318 (95.4%)Elston et al. [29]
Stratum D Beta 9734610,130 ± 7010,086–9452 (95.4%)Elston et al. [29]
PY–04 charcoalAMS C14CAMS9420210,670 ± 4010,759–10,618 (95.4%)Barton et al. [30]
Note: 1 no absolute date available.
Table
Table 3. Presence of markers of the PNT in North China, by site 3 Table 2 modified from [2]. These sites are mapped in Figure 1.
Table 3. Presence of markers of the PNT in North China, by site 3 Table 2 modified from [2]. These sites are mapped in Figure 1.
SiteTypeArtifact AssemblageSite OrganizationBiological Remains
ABCDEFGHIJKLMNOPQRS
NanzhuangtouPNT01110000110.501110011
ZhuannianPNT1111011101000000000
Donghulin 1PNT11110111111111110.500
LijiagouPNT111010110.510.501000000
BianbiandongPNT01110001110.50.51010000
KengnanPNT0110000100000000000
YujiagouPNT1100100000000000000
Ma’anshanPNT1100100111001000000
HutouliangPNT10.500100000000000000
MengjiaquanPNT1000001100000000000
JijitanPNT1000100000000000000
XueguanPNT1000000.5000000000000
Lingjing 1PNT1100000000000000000
Shizitan 2LUP1011000111000001000
XiachuanLUP1000100100000000000
LongwangchanLUP101100110.51000000000
1 = present0.5 = possibly present0 = not discovered yet.
Notes: The rows: A = microblade, B = pottery, C = mortar (millstone), D = pestle (millstick), E = adze, F = stone container, G = polished tool, H = diversity of artifact types, I = hearth, J = diversity of site types, K = structure, L = grave, M = central camp, N = ditch, O = pit, P = foxtail millet, Q = broomcorn millet, R = dog, S = wild pig (boar). The columns: Other sites without data except microblades: Xishi (Late Upper Paleolithic, LUP); Shuidonggou Loc. 12; Dadiwan (Component 4); Gezishan (Pigeon Mountain); PY–04, all classified as “other” (see maps of Northern Chinanorthern China). 1 updated information according to Cui [15]; 2 new site added according to Li et al. [23]; 3 updated information of Locality 29 according to Liu et al. [31].
Table
Table 4. Phases of plant use at the Shizitan (SZT) site (data collected from [31]).
Table 4. Phases of plant use at the Shizitan (SZT) site (data collected from [31]).
PhaseSite and StratumMaterialFunction for PlantsPlant Use
Phase I
(pre-Last Glacial Maximum (LGM))		Stratum 8, SZT 292 FL
2 SL		FL: cutting, scraping
SL: processing		Starchy plants, including Panicoideae (possibly Job’s tears), Triticeae and yam
No clear evidence for wild millet collection
Phase II
(the early part of LGM)		Stratum 7, SZT 297 MB
3 FL
4 SL
1HS		MB: cutting
FL: plant cutting
SL: processing *
HS: processing		Wild cereals (e.g., Triticeae, Job’s tears and wild millets), tubers and other plants
Phase III
(the late part of LGM)		Strata 6, 5, and 4, SZT 291 MB
7 FL
3 SL		MB: cutting
FL: cutting
SL: processing		Wild cereals, and especially Panicoideae
Phase IV
(the terminal LGM)		Strata 3 and 2, SZT 294 FL
4 SL		FL: cutting
SL: processing		Grasses, including Panicoideae and Triticeae.
Tubers are much less well represented
Phase V
(warmer conditions)		Stratum 1, SZT 292 FLFL: cuttingUnknown, only one non–specific phytolith was recovered.
Phase VI
(Early Holocene)		Stratum 1, SZT 52 FLFL: cuttingUnknown, only starch
Notes: FL: flake, MB: microblade, SL: slab or slab fragment, HS: handstone. * Both slab fragments and handstones are used for processing plant food and minerals.
Table
Table 5. Hearths in the Shizitan site, Locality S29 [25].
Table 5. Hearths in the Shizitan site, Locality S29 [25].
Type of HearthNumberPercentage
Above–ground hearth26592.98%
Above–ground hearth with sandstone rocks134.56%
Round–pit hearth51.76%
Hearth with stone–floored pit20.7%
Total285100%

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Zhang, M. Microblade–Based Societies in North China at the End of the Ice Age. Quaternary 2020, 3, 20. https://doi.org/10.3390/quat3030020

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Zhang, M. (2020). Microblade–Based Societies in North China at the End of the Ice Age. Quaternary, 3(3), 20. https://doi.org/10.3390/quat3030020

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