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MILLET CONSUMPTION IN SIBERIA PRIOR TO MID-SECOND MILLENNIUM BC? A REVIEW OF RECENT DEVELOPMENTS

Published online by Cambridge University Press:  05 August 2021

Svetlana V Svyatko*
Affiliation:
Queen’s University Belfast, 14Chrono Centre for Climate, the Environment, and Chronology, BelfastBT7 1NNUK
Rick J Schulting
Affiliation:
University of Oxford, School of Archaeology, 1 South Parks Road, Oxford, UK
Dmitriy Papin
Affiliation:
Altay State University, Barnaul Laboratory of Archaeology and Ethnography of South Siberia, Barnaul, Russia Siberian Branch of the Russian Academy of Sciences, Institute of Archaeology and Ethnography, Novosibirsk, Russia
Paula J Reimer
Affiliation:
Queen’s University Belfast, 14Chrono Centre for Climate, the Environment, and Chronology, BelfastBT7 1NNUK
*
*Corresponding author. Email: [email protected]
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Abstract

In this paper we discuss recent developments in documenting the spread of millet across the Eurasian steppes. We emphasize that, despite a recent proposal that millet consumption in southern Siberia can be attributed to the Early Bronze Age (i.e., the late third to early second millennium BC), at present there are no direct data for southern Siberia indicating the consumption of millet prior to the Late Bronze Age, from the 14th century BC. We also present in full the combined stable isotope and 14C datasets from the Minusinsk Basin to support this conclusion.

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 (http://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
© The Author(s), 2021. Published by Cambridge University Press on behalf of the Arizona Board of Regents on behalf of the University of Arizona

INTRODUCTION

Two of the major themes of stable isotopic research on the Eurasian steppes have involved investigating and documenting of the spread of millet (Svyatko et al. Reference Svyatko, Schulting, Mallory, Murphy, Reimer, Khartanovich, Chistov and Sablin2013; Motuzaite Matuzeviciute et al. Reference Motuzaite Matuzeviciute, Lightfoot, O’Connell, Voyakin, Liu, Loman, Svyatko, Usmanova and Jones2015) and the extent of freshwater fish consumption (Privat et al. Reference Privat, O’Connell and Hedges2007; Schulting et al. Reference Schulting, Ramsey, Bazaliiskii, Goriunova and Weber2014, Reference Schulting, Bronk Ramsey, Bazaliiskii and Weber2015; Shishlina et al. Reference Shishlina, Zazovskaya, van der Plicht and Sevastyanov2012, Reference Shishlina, Sevastyanov, Zazovskaya and van der Plicht2014, Reference Shishlina, van der Plicht and Turetsky2018; Svyatko et al. Reference Svyatko, Mertz and Reimer2015, Reference Svyatko, Schulting, Poliakov and Reimer2017a). While it began with individual sites and groups of prehistoric people, this research has also been targeting more general issues such as adoption of major economic practices and documenting changes in subsistence patterns over time and space (Svyatko et al. Reference Svyatko, Schulting, Mallory, Murphy, Reimer, Khartanovich, Chistov and Sablin2013; Motuzaite Matuzeviciute et al. Reference Motuzaite Matuzeviciute, Kiryushin, Rakhimzhanova, Svyatko, Tishkin and O’Connell2016). Most recently, there have been meta-analyses addressing various aspects of prehistoric life across the region, such as the transmission of domesticated cereals and the emergence of complex trans-regional political networks (Ventresca Miller and Makarewicz Reference Ventresca Miller and Makarewicz2019).

While the role of freshwater reservoir effects continues to be debated, stable carbon isotope (δ13C) analysis of human and faunal remains, especially when combined with radiocarbon (14C) dating, has proven very successful in tracing the spread and use of millet. This is because millets (Panicum miliaceum and Setaria italica) are the only plausible candidates for a significant increase in consumption of C4 plants on the Eurasian steppes, whether directly or through foddered animals, and thus are relatively easily traced by δ13C values in human bone collagen. Obviously, 14C dating of samples which demonstrate a clear C4 (millet) signal is crucial for understanding this process. In this contribution, we present a brief overview of isotopic studies focusing on the chronology of isotopic evidence for millet on the central Eurasian steppes, specifically within the Minusinsk Basin, and reiterate its appearance in the Late Bronze Age, from the 14th century BC.

Thus far, the earliest isotopic evidence for significant millet consumption in eastern China has been attributed to the Neolithic period (6200–5500 cal BC, Xiaojingshan and Yuezhuang sites; Hu et al. Reference Hu, Wang, Luan, Wang and Richards2008, Reference Hu, Luan, Wang, Wang and Richards2009), and in western China (Xinjiang) to the Bronze and Early Iron Age (from 2000 BC, Wang et al. Reference Wang, Fuller, Wei, Chang and Hu2016, Reference Wang, Wei, Chang, Yu, Zhang, Wang, Hu and Fuller2019; Qu et al. Reference Qu, Hu, Rao, Abuduresule, Li, Hu, Jiang, Wang and Yang2018; also summarized in Hu Reference Hu2018). By ca. 2700 cal BC, millet was used as fodder for domesticated stock in Dzhungar Alatau (southeastern Kazakhstan; Hermes et al. Reference Hermes, Frachetti, Doumani Dupuy, Mar’yashev, Nebel and Makarewicz2019). By the 17th–16th centuries BC millet consumption is isotopically recorded in southern Kazakhstan (Motuzaite Matuzeviciute et al. Reference Motuzaite Matuzeviciute, Lightfoot, O’Connell, Voyakin, Liu, Loman, Svyatko, Usmanova and Jones2015), and by the final Bronze Age in central Kazakhstan (Lightfoot et al. Reference Lightfoot, Motuzaite-Matuzeviciute, O’Connell, Kukushkin, Loman, Varfolomeev, Liu and Jones2015). To the northeast of this, in southern Siberia, millet apparently arrived in the Minusinsk Basin only during the 14th century BC (Svyatko et al. Reference Svyatko, Schulting, Mallory, Murphy, Reimer, Khartanovich, Chistov and Sablin2013), and by the 6th–7th centuries BC it is isotopically detected in the Tuva region (Murphy et al. Reference Murphy, Schulting, Beer, Kasparov and Pshenitsyna2013), though this is unlikely to mark their earliest appearance there. That said, clear isotopic evidence of significant millet consumption in Mongolia is also late, being mainly found from the 8th century BC (Wilkin et al. Reference Wilkin, Ventresca Miller, Miller, Spengler, Taylor, Fernandes, Hagan, Bleasdale, Zech, Ulziibayar, Myagmar, Boivin and Roberts2020).

In a recent synthesis, Ventresca Miller and Makarewicz (Reference Ventresca Miller and Makarewicz2019) propose that millet consumption in southern Siberia can be attributed to a much earlier period, namely, the late third to early second millennium BC (Early Bronze Age). This requires some discussion, as this conclusion, being a critical point for the perception of the history (economy, migrations, and cultural contacts) of southern Siberian populations, is inconsistent with the associated isotopic, paleobotanical and archaeological studies in the region. Their paper presents a meta-analysis of the existing stable isotope and paleobotanical data for the timing and spread of various cereals across a number of regions of the Eurasian steppe. The authors attempt not only to summarize the archaeological data, but also to demonstrate the use of cereals in regions which were previously considered to have been purely pastoral in terms of economy. This is particularly important for the Bronze Age archaeological complexes of the western and southern parts of Siberia, which have been traditionally seen as following a pastoral way of life (Gryaznov Reference Gryaznov1969).

As with any meta-analysis, there is a strong reliance on previously available data. Our main purpose in this brief paper is to correct a misunderstanding regarding the appearance of millet in southern Siberia at the end of the 3rd millennium BC, as this relies on a number of human stable carbon isotope (δ13C) values misattributed chronologically. Addressing one of the key regions of southern Siberia, the Minusinsk Basin, Ventresca Miller and Makarewicz (Reference Ventresca Miller and Makarewicz2019: p. e1) conclude that “low-level consumption of millet [was] possibly taking place in the Minusinsk Basin perhaps as early as the late third millennium cal BC” citing Svyatko et al. (Reference Svyatko, Murphy, Schulting and Mallory2007) in fig. 4 and table S5 as the source for the first millet signal in the Afanasyevo and Okunevo populations. In particular, they show two “Afanasyevo” and one “Okunevo” individuals demonstrating high δ13C values (i.e., > –17‰) that, in this region, are associated with consumption of the C4 plant millet. The authors conclude that “in the absence of radiocarbon determinations from human individuals analyzed for carbon and nitrogen isotopes, some individuals in the EBA group could date to as late as c. 2000 cal BC”, and that “low-level millet consumption by hunter-gatherer populations in the ES [Eurasian Steppe] may have taken place in the Early Bronze Age (EBA) sometime during the late third to early second millennium cal BC” (Ventresca Miller and Makarewicz Reference Ventresca Miller and Makarewicz2019: p. e5). If true, this would present a very different picture of the transmission of millet into the region.

The paper cited, Svyatko et al. (Reference Svyatko, Murphy, Schulting and Mallory2007), was one of our first reports at an early stage of our research in the area, presenting preliminary stable isotope results for the Bronze to Early Iron Age populations of the Minusinsk Basin for the proceedings of the 2007 Annual Conference of the Association for Environmental Archaeology (Poznań, Poland). Cultural attributions were based on archaeological evidence. Subsequent research, however, demonstrated that the three supposedly early individuals showing a “millet signal” in fact dated to the later Karasuk (Late Bronze Age), Tagar (Early Iron Age) and medieval periods. The 14C dates were reported (Svyatko et al. Reference Svyatko, Mallory, Murphy, Polyakov, Reimer and Schulting2009; samples UBA-7902, UBA-7904 and UBA-7920), as a part of an extensive, targeted dating program involving 88 humans from the Minusinsk Basin, previously analysed isotopically. This exercise showed that the first clear “millet signal” (δ13C > –17‰) in the Minusinsk Basin appeared in the 14th century BC, as shown in Svyatko et al. (Reference Svyatko, Schulting, Mallory, Murphy, Reimer, Khartanovich, Chistov and Sablin2013, fig. 3). We recognize that there were issues in comparing the 14C dates and stable isotope results directly in our previous publications, though our reporting of the minimum and maximum values for each archaeological period and complex clearly showed that there were no δ13C values above –17.8‰ for any period prior to the Karasuk culture (Svyatko et al. Reference Svyatko, Schulting, Mallory, Murphy, Reimer, Khartanovich, Chistov and Sablin2013: table 2). To avoid further misunderstandings, we present the full dataset here (Figure 1 and SI Table 1). Another important point to emphasize here is that even after the 14th century BC, there was considerable variability in the consumption of millet, with some individuals showing little to no use, and this continued well into the Early Iron Age (cf. Murphy et al. Reference Murphy, Schulting, Beer, Kasparov and Pshenitsyna2013; Shishlina et al. Reference Shishlina, Pankova, Sevastyanov, Kuznetsova and Demidenko2016; Wilkin et al. Reference Wilkin, Ventresca Miller, Miller, Spengler, Taylor, Fernandes, Hagan, Bleasdale, Zech, Ulziibayar, Myagmar, Boivin and Roberts2020); similar observations have been made for central Kazakhstan (Lightfoot et al. Reference Lightfoot, Motuzaite-Matuzeviciute, O’Connell, Kukushkin, Loman, Varfolomeev, Liu and Jones2015). We have previously addressed the possibility of a freshwater reservoir effect on the 14C dates obtained (Svyatko et al. Reference Svyatko, Schulting, Poliakov and Reimer2017a), and, while it remains a possibility, we do not think it would have a major impact on the date for the introduction of millet into the Minusinsk Basin.

Figure 1 Boxplots showing (a) δ13C and (b) δ15N values by culture. The lighter gray circles and number in brackets indicate individuals that have been directly 14C dated.

Southern Siberia is one of the crucial regions of cultural genesis and interaction in the steppe zone; its importance for the Bronze and Early Iron Age of the Eurasian steppe belt has been continuously emphasized in the literature since the first expeditions by German scientists on Russian service (D.G. Messerschmidt, P.S. Pallas, W. Radloff) to the area in the 18th–19th centuries. For the 20th–15th centuries BC, this region and the adjacent southern part of West Siberia are represented by a number of autochthonous cultural complexes (Elunino and Okunevo) and those where bearers migrated from the west (Afanasyevo and Andronovo), as recently confirmed by ancient DNA (Allentoft et al. Reference Allentoft, Sikora, Sjögren, Rasmussen, Rasmussen, Stenderup, Damgaard, Schroeder, Ahlström and Vinner2015). According to archaeological and archaeozoological data, they all practiced a primarily stock-rearing economy (Gryaznov Reference Gryaznov1969).

Despite the role of cereal cultivation in supplementing the pastoral economy of Bronze Age communities in the south of West Siberia being originally discussed in the 1930s, the first reliable evidence of grain consumption was recorded only for the Late Bronze Age, 14th–9th centuries BC, in the Irmen Complex Milovanovo settlement where wheat impressions on pottery were found (Sidorov Reference Sidorov1986). This was the period when the Andronovo Complex was replaced by new material culture (including bronze sickles possibly used for harvesting cereals, as well as mattocks and quernstones) seen in the Irmen and Karasuk complexes. Importantly, this was associated with increased contacts between the populations of southern Siberia and the Central Plains of China. Prior to this time, there is evidence for interactions only between the Afanasyevo or Okunevo complexes of southern Siberia and the Dzhungar Basin (e.g., Qiemu’erqieke cemetery; Jia and Betts Reference Jia and Betts2010), and between Andronovo and Xinjiang, as summarized in Svyatko et al. (Reference Svyatko, Schulting, Mallory, Murphy, Reimer, Khartanovich, Chistov and Sablin2013; see also Jia et al. Reference Jia, Betts, Cong, Jia and Doumani Dupuy2017), both regions being part of the steppe world during the Bronze Age. The first connections between Siberia and China are only attributed to the Shang period (16th–11th centuries BC; Kuzmina Reference Kuzmina2007).

Isotopically, the appearance of millet in the Late Bronze Age cultural complexes of southern Siberia was first described in Svyatko et al. (Reference Svyatko, Schulting, Mallory, Murphy, Reimer, Khartanovich, Chistov and Sablin2013), where it was placed in the 14th century BC. That paper also discussed the context and implications of this conclusion, including intensified contacts between Karasuk groups and China, further detailed in later publications (Svyatko Reference Svyatko2014, Reference Svyatko2016). Subsequent recent research on earlier periods in the area and neighboring regions (Marchenko et al. Reference Marchenko, Orlova, Panov, Zubova, Molodin, Pozdnyakova, Grishin and Uslamin2015; Motuzaite Matuzeviciute et al. Reference Motuzaite Matuzeviciute, Kiryushin, Rakhimzhanova, Svyatko, Tishkin and O’Connell2016; Svyatko et al. Reference Svyatko, Polyakov, Soenov, Stepanova, Reimer, Ogle, Tyurina, Grushin and Rykun2017c) has provided no evidence for any significant contribution of millet to human diet. However a C4 signal was detected for at least three 14th–13th centuries BC individuals out of 7 humans analysed from the Irmen Complex sites of Firsovo-14 and Plotinnaya in the upper Ob River Basin ca. 1500 km to the northwest of the Minusinsk Basin (δ13C = –16.4‰, –15.6‰, –15.5‰), with more systematic millet consumption only from the 5th century BC (δ13C = –18.2 ± 4.9‰, ranging from –24.6‰ to –14.1‰ for a group of 65 Early Iron Age individuals; Svyatko et al. Reference Svyatko, Papin and Poshekhonova2017b; Papin and Svyatko Reference Papin and Svyatko2018).

In sum, a small number of key datapoints cited by Ventresca Miller and Makarewicz (Reference Ventresca Miller and Makarewicz2019) are inaccurate regarding the timing of the appearance of significant consumption (i.e., clearly detectable isotopically) of C4 crops in southern Siberia. The presence of cereals—both wheat and millet—in the local diets has only been reliably recorded archaeologically and isotopically following the transition from Andronovo to Irmen and Karasuk cultural traditions. At present, there are no direct data for southern Siberia indicating the consumption of millet prior to the 14th century BC, at least 600 years later than suggested in Ventresca Miller and Makarewicz (Reference Ventresca Miller and Makarewicz2019). Beyond setting the record straight for a few stable isotope values, the issue is of wider relevance since it links in with larger discussions concerning the cultural exchanges and transmissions across the Eurasian steppe, particularly regarding links with China.

The 2nd millennium BC was a highly dynamic period in Eurasian prehistory, characterised by intensified East-West migrations and exchanges in material culture and ideas. This was the time of a dramatic increase in human population and settlements in China, a “revolutionary” development towards the emergence of Chinese civilization and the formation of early states. The latest research in key archaeological sites of the Inner Asian Mountain Corridor (Wang et al. Reference Wang, Wei, Chang, Yu, Zhang, Wang, Hu and Fuller2019, Reference Wang, Liu, Duan, Zhang, Liu, Reid, Zhang, Dong, Wang, Ruan, Li and An2020) demonstrates that during the 2nd millennium BC millets spread westward out of the Yellow River Basin to Xinjiang, southern Kazakhstan, Minusinsk Basin and Europe. This dynamic period apparently witnessed the first steps of formation of the so-called “Isotopic Millet Road” (Wang et al. Reference Wang, Wei, Chang, Yu, Zhang, Wang, Hu and Fuller2019) which extended from North China to Central Asia (including Siberia). This was likely driven by increased East–West contacts, including resource transfer, warfare, marriage, migration, and the rise of the Xia and Shang dynasties. The Gansu Corridor is the most likely route by which millet ultimately arrived into the Minusinsk Basin in the mid-2nd millennium BC. Millets were already in use in southeast Gansu region in the 6th millennium BC (Dadiwan site, Barton et al. Reference Barton, Newsome, Chen, Wang, Guilderson and Bettinger2009) and in northwest Gansu by at least 2000 BC (Atahan et al. Reference Atahan, Dodson, Li, Zhou, Hu, Bertuch and Sun2011; Ma et al. Reference Ma, Dong, Jia, Wang, Cui and Chen2016; see summary in Liu et al. Reference Liu, Pollard, Schulting, Rawson and Liu2021). Interestingly, at around the same time as a millet signal is detected in the Minusinsk Basin at ca. 1400 BC, there appears to be a parallel decrease in δ13C values in Gansu, suggesting the reciprocal arrival of wheat there (Ma et al. Reference Ma, Dong, Jia, Wang, Cui and Chen2016; see also Liu et al. Reference Liu, Pollard, Schulting, Rawson and Liu2021). Whether this can be linked to climate change as proposed by Ma et al. (Reference Ma, Dong, Jia, Wang, Cui and Chen2016) is a subject for further research. In any case, this was undoubtedly a major milestone in the development of the regional economy and the long-distance cultural exchanges that are at the heart of the Eurasian steppe.

Regardless of our remarks, the paper by Ventresca Miller and Makarewicz (Reference Ventresca Miller and Makarewicz2019) has important implications for the study of particular localities and ways of adoption of cereal cultivation traditions in the Eurasian steppe belt and represents a major contribution towards our understanding of the regional prehistoric economies and societies. Needless to say, only further research in particular areas, especially the 14C dating of human and/or animal remains suggestive of millet consumption, and the remains of the crops themselves, will provide us with the precise chronology and pathways of the spread of millet in Siberia.

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References

REFERENCES

Allentoft, ME, Sikora, M, Sjögren, KG, Rasmussen, S, Rasmussen, M, Stenderup, J, Damgaard, PB, Schroeder, H, Ahlström, T, Vinner, L, et al. 2015. Population genomics of Bronze Age Eurasia. Nature 522:167172.CrossRefGoogle ScholarPubMed
Atahan, P, Dodson, J, Li, X, Zhou, X, Hu, S, Bertuch, F, Sun, N. 2011. Subsistence and the isotopic signature of herding in the Bronze Age Hexi Corridor, NW Gansu, China. Journal of Archaeological Science 38(7):17471753.CrossRefGoogle Scholar
Barton, L, Newsome, SD, Chen, F-H, Wang, H, Guilderson, TP, Bettinger, RL. 2009. Agricultural origins and the isotopic identity of domestication in northern China. Proceedings of the National Academy of Sciences 106(14):55235528.CrossRefGoogle ScholarPubMed
Gryaznov, MP. 1969. The ancient civilization of South Siberia. London: Barrie & Rockliff, The Cresset Press.Google Scholar
Jia, PW, Betts, A. 2010. A reanalysis of the Qiemu’erqieke (Shamirshak) cemeteries, Xinjian, China. Journal of Indo-European Studies 38(3/4):143.Google Scholar
Jia, PW, Betts, A, Cong, D, Jia, X, Doumani Dupuy, PN. 2017. Adunqiaolu: New evidence for the Andronovo in Xinjiang, China. Antiquity 91(357):621639.CrossRefGoogle Scholar
Kuzmina, E. 2007. The origin of the Indo-Iranians. Leiden-Boston: Brill.CrossRefGoogle Scholar
Hermes, TR, Frachetti, MD, Doumani Dupuy, PN, Mar’yashev, A, Nebel, A, Makarewicz, ChA. 2019. Early integration of pastoralism and millet cultivation in Bronze Age Eurasia. Proceeding of the Royal Society B 286(1910):20191273.CrossRefGoogle Scholar
Hu, Y, Wang, S, Luan, F, Wang, C, Richards, MP. 2008. Stable isotope analysis of humans from Xiaojingshan site: implications for understanding the origin of millet agriculture in China. Journal of Archaeological Science 35(11):29602965.CrossRefGoogle Scholar
Hu, YW, Luan, FS, Wang, SG, Wang, CS, Richards, MP. 2009. Preliminary attempt to distinguish the domesticated pigs from wild boars by the methods of carbon and nitrogen stable isotope analysis. Science in China Series D-Earth Sciences 52(1):8592.CrossRefGoogle Scholar
Hu, Y. 2018. Thirty-four years of stable isotopic analyses of ancient skeletons in China: an overview, progress and prospects. Archaeometry 60(1):144156.CrossRefGoogle Scholar
Lightfoot, E, Motuzaite-Matuzeviciute, G, O’Connell, TC, Kukushkin, IA, Loman, V, Varfolomeev, V, Liu, X, Jones, MK. 2015. How “pastoral” is pastoralism? Dietary diversity in Bronze Age communities in the Central Kazakhstan Steppes. Archaeometry 57(S1):232249.CrossRefGoogle Scholar
Liu, R, Pollard, M, Schulting, R, Rawson, J. Liu, C. 2021. Synthesis of stable isotopic data for human bone collagen: A study of the broad dietary patterns across ancient China. The Holocene 31(2):302312.CrossRefGoogle Scholar
Ma, M, Dong, G, Jia, X, Wang, H, Cui, Y, Chen, F. 2016. Dietary shift after 3600 cal yr BP and its influencing factors in northwestern China: evidence from stable isotopes. Quaternary Science Reviews 145:5770.10.1016/j.quascirev.2016.05.041CrossRefGoogle Scholar
Marchenko, Z, Orlova, L, Panov, V, Zubova, A, Molodin, V, Pozdnyakova, OA, Grishin, AE, Uslamin, E. 2015. Paleodiet, radiocarbon chronology, and the possibility of freshwater reservoir effect for Preobrazhenka 6 burial ground, Western Siberia: preliminary results. Radiocarbon 57(4):595610.CrossRefGoogle Scholar
Motuzaite Matuzeviciute, G, Kiryushin, YF, Rakhimzhanova, SZ, Svyatko, S, Tishkin, AA, O’Connell, TC. 2016. Climatic or dietary change? Stable isotope analysis of Neolithic–Bronze Age populations from the Upper Ob and Tobol River basins. Holocene 26(10):17111721.CrossRefGoogle Scholar
Motuzaite Matuzeviciute, G, Lightfoot, E, O’Connell, TC, Voyakin, D, Liu, X, Loman, V, Svyatko, S, Usmanova, E, Jones, MK. 2015. The extent of cereal cultivation among the Bronze Age to Turkic period societies of Kazakhstan determined using stable isotope analysis of bone collagen. Journal of Archaeological Science 59:2334.CrossRefGoogle Scholar
Murphy, EM, Schulting, RJ, Beer, N, Kasparov, A, Pshenitsyna, M. 2013. Iron Age pastoral nomadism and agriculture in the eastern Eurasian steppe: implications from dental palaeopathology and stable carbon and nitrogen isotopes. Journal of Archaeological Science 40(5):25472560.CrossRefGoogle Scholar
Papin, DV, Svyatko, SV. 2018. The problem of emergence of agriculture in the Upper Ob region based on data from archaeology and isotope analysis. Theory and Practice of Archaeological Research 4(24):20–25. In Russian with English abstract.CrossRefGoogle Scholar
Privat, KL, O’Connell, TC, Hedges, REM. 2007. The distinction between freshwater- and terrestrial-based diets: methodological concerns and archaeological applications of sulphur stable isotope analysis. Journal of Archaeological Science 34(8):11971204.CrossRefGoogle Scholar
Qu, Y, Hu, Y, Rao, H, Abuduresule, I, Li, W, Hu, X, Jiang, H, Wang, C, Yang, Y. 2018. Diverse lifestyles and populations in the Xiaohe culture of the Lop Nur region, Xinjiang, China. Archaeological and Anthropological Sciences 10:20052014.CrossRefGoogle Scholar
Schulting, RJ, Bronk Ramsey, C, Bazaliiskii, VI, Weber, A. 2015. Highly variable freshwater reservoir effects found along the Upper Lena watershed, Cis-Baikal, Southeast Siberia. Radiocarbon 57(4):581593.CrossRefGoogle Scholar
Schulting, R, Ramsey, CB, Bazaliiskii, VI, Goriunova, OI, Weber, A. 2014. Freshwater reservoir offsets investigated through paired human-faunal 14C dating and stable carbon and nitrogen isotope analysis at Lake Baikal, Siberia. Radiocarbon 56(3):9911008.CrossRefGoogle Scholar
Shishlina, N, Zazovskaya, E, van der Plicht, J, Sevastyanov, EV. 2012. Isotopes, plants, and reservoir effects: case study from the Caspian Steppe Bronze Age. Radiocarbon 54(3–4):749–60.CrossRefGoogle Scholar
Shishlina, N, Sevastyanov, V, Zazovskaya, E, van der Plicht, J. 2014. Reservoir effect of archaeological samples from Steppe Bronze Age Cultures in Southern Russia. Radiocarbon 56(2):767–78.CrossRefGoogle Scholar
Shishlina, N, Pankova, S, Sevastyanov, V, Kuznetsova, O, Demidenko, Y. 2016. Pastoralists and mobility in the Oglakhty cemetery of southern Siberia: New evidence from stable isotopes. Antiquity 90(351):679694.CrossRefGoogle Scholar
Shishlina, NI, van der Plicht, J, Turetsky, MA. 2018. The Lebyazhinka burial ground (Middle Volga Region, Russia): new 14C dates and the reservoir effect. Radiocarbon 60(2):681690.CrossRefGoogle Scholar
Sidorov, EA. 1986. On the crop agriculture of the Irmen Culture (based on materials of the forest-steppe Ob River Region. In: Molodin VI, resp. editor. Paleoeconomika Sibiri. Novosibirsk: Nauka Siberian branch. p. 54–66. In Russian.Google Scholar
Svyatko, S. 2014. Dental palaeopathological analysis of the Eneolithic-Early Iron Age populations from the Minusinsk Basin, Southern Siberia: palaeodietary implications. Archaeology, Ethnology and Anthropology of Eurasia 2(58):143156.CrossRefGoogle Scholar
Svyatko, SV. 2016. Stable isotope analysis: outline of methodology and a review of studies in Siberia and the Eurasian Steppe. Archaeology, Ethnology and Anthropology of Eurasia 44(2):4755.CrossRefGoogle Scholar
Svyatko, SV, Mallory, JP, Murphy, EM, Polyakov, AV, Reimer, PJ, Schulting, RJ. 2009. New radiocarbon dates and a review of the chronology of prehistoric populations from the Minusinsk Basin, Southern Siberia, Russia. Radiocarbon 51(1):243273.CrossRefGoogle Scholar
Svyatko, SV, Mertz, IV, Reimer, PJ. 2015. Freshwater reservoir effect on redating of Eurasian Steppe Cultures: First results for Eneolithic and Early Bronze Age Northeast Kazakhstan. Radiocarbon 57(4):625644.CrossRefGoogle Scholar
Svyatko, S, Murphy, E, Schulting, R, Mallory, J. 2007. Environment, lifestyle and diet of prehistoric populations from the Minusinsk Basin, Southern Siberia, Russia. In: Makohonienko M, Makowiecki D, Czerniawska J, editors. Eurasian perspectives on environmental archaeology: the 2007 AEA Annual Conference. September 12–15, 2007. Poznań, Poland. Bogucki Wydawnictwo Naukowe. p. 139–142.Google Scholar
Svyatko, SV, Schulting, RJ, Mallory, J, Murphy, EM, Reimer, PJ, Khartanovich, VI, Chistov, YK, Sablin, MV. 2013. Stable isotope dietary analysis of prehistoric populations from the Minusinsk Basin, Southern Siberia, Russia: a new chronological framework for the introduction of millet to the eastern Eurasian steppe. Journal of Archaeological Science 40(11):39363945.CrossRefGoogle Scholar
Svyatko, SV, Schulting, R, Poliakov, A, Reimer, PJ. 2017a. A lack of freshwater reservoir effects in human radiocarbon dates in the Eneolithic to Iron Age in the Minusinsk Basin. Archaeological and Anthropological Sciences 9(7):13791388.CrossRefGoogle Scholar
Svyatko, SV, Papin, DV, Poshekhonova, O. 2017b. Isotopic analysis of the prehistoric cultures of the Eurasian steppes and Siberia: Short overview and new data. In: Derevyanko AP, editor. Proceedings of V (XXI) All-Russian Archaeological Congress. V. 1. Barnaul: Altai State University. p. 927–928. In Russian.Google Scholar
Svyatko, SV, Polyakov, AV, Soenov, VI, Stepanova, NF, Reimer, PJ, Ogle, N, Tyurina, EA, Grushin, SP, Rykun, MP. 2017c. Stable isotope palaeodietary analysis of the Early Bronze Age Afanasyevo Culture in the Altai Mountains, Southern Siberia. Journal of Archaeological Science: Reports 14:6575.Google Scholar
Ventresca Miller, AR, Makarewicz, CA. 2019. Intensification in pastoralist cereal use coincides with the expansion of trans-regional networks in the Eurasian Steppe. Scientific Reports 9:8363.CrossRefGoogle ScholarPubMed
Wang, T, Fuller, B, Wei, D, Chang, X, Hu, Y. 2016. Investigating dietary patterns with stable isotope ratios of collagen and starch grain analysis of dental calculus at the Iron Age cemetery site of Heigouliang, Xinjiang, China. International Journal of Osteoarchaeology 26(4):693704.CrossRefGoogle Scholar
Wang, T, Wei, D, Chang, X, Yu, Z, Zhang, X, Wang, C, Hu, Y, Fuller, BT. 2019. Tianshanbeilu and the Isotopic Millet Road: reviewing the late Neolithic/Bronze Age radiation of human millet consumption from north China to Europe. National Science Review 6(5):10241039.CrossRefGoogle Scholar
Wang, W, Liu, Y, Duan, F, Zhang, J, Liu, X, Reid, REB, Zhang, M, Dong, W, Wang, Y, Ruan, Q, Li, W, An, C-B. 2020. A comprehensive investigation of Bronze Age human dietary strategies from different altitudinal environments in the Inner Asian Mountain Corridor. Journal of Archaeological Science 121:e105201.CrossRefGoogle Scholar
Wilkin, S, Ventresca Miller, AR, Miller, BK, Spengler, RN, Taylor, WTT, Fernandes, R, Hagan, RW, Bleasdale, M, Zech, J, Ulziibayar, S, Myagmar, E, Boivin, N, Roberts, P. 2020. Economic diversification supported the growth of Mongolia’s nomadic empires. Scientific Reports 10(1):e3916.CrossRefGoogle ScholarPubMed
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Figure 1 Boxplots showing (a) δ13C and (b) δ15N values by culture. The lighter gray circles and number in brackets indicate individuals that have been directly 14C dated.

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