Klejn, L. S., Windle, K., Ireland, R. Soviet Archaeology: Trends, Schools, and History. Oxford University Press, Oxford, 2012. https://doi.org/10.1093/acprof:osobl/9780199601356.001.0001.
Li, Y. Q. Agriculture and palaeoeconomy in prehistoric Xinjiang, China (3000–200 bc). Veg. Hist. Archaeobot. 30, 287–303 (2020).
Ventresca, M. A. R., Cheryl, AM. Intensification in pastoralist cereal use coincides with the expansion of trans-regional networks in the Eurasian Steppe. Scientific Reports. https://doi.org/10.1038/s41598-018-35758-w (2019).
Zanina, O. G., Tur, S. S., Svyatko, S. V., Soenov, V. & Borodovskiy, A. Plant food in the diet of the Early Iron Age pastoralists of Altai: Evidence from dental calculus and a grinding stone. J. Archaeol. Sci.: Rep. 35, 102740 (2021).
Svyatko, S. V. Dental palaeopathological analysis of the eneolithic-early iron age populations from the Minusinsk Basin, Southern Siberia: Palaeodietary implications. Archaeol., Ethnol. Anthropol. Eurasia 42, 143–156 (2014).
Spengler, R. N., Ryabogina, N., Tarasov, P. E. & Wagner, M. The spread of agriculture into northern Central Asia: Timing, pathways, and environmental feedbacks. Holocene 26, 1527–1540 (2016).
Zhou, X., Yu, J., Spengler, R. N., Shen, H., Zhao, K., Ge, J., Bao, Y. et al. 5,200-year-old cereal grains from the eastern Altai Mountains redate the trans-Eurasian crop exchange. Nat. Plants 6, 78–87 (2020).
Dong, G., Yang, Y., Han, J., Wang, H. & Chen, F. Exploring the history of cultural exchange in prehistoric Eurasia from the perspectives of crop diffusion and consumption. Sci. China Earth Sci. 60, 1110–1123 (2017).
Murphy, E. M., Schulting, R. J., Beer, N., Chistov, Y., Kasparov, A. K. & Pshenitsyna, M. Iron Age pastoral nomadism and agriculture in the eastern Eurasian steppe: implications from dental palaeopathology and stable carbon and nitrogen isotopes. J. Archaeol. Sci. 40, 2547–2560 (2013).
Spengler, R. N. & Willcox, G. Archaeobotanical results from Sarazm, Tajikistan, an early bronze age settlement on the edge: agriculture and exchange. Environ. Archaeol. 18, 211–221 (2013).
Spengler, R. N., Frachetti, M. D. & Doumani, P. N. Late bronze age agriculture at Tasbas in the Dzhungar Mountains of eastern Kazakhstan. Quat. Int. 348, 147–157 (2014).
An, C., Wang, W., Liu, Y., Zhang, M., Duan, F., Wang, X. et al. The Holocene environmental change in Xinjiang and its impact on prehistoric cultural exchange. Sci. Sin. Terra 50, 677–687 (2020).
Qu, Y., Hu, X., Wang, T. & Yang, Y. Early interaction of agropastoralism in Eurasia: new evidence from millet-based food consumption of Afanasyevo humans in the southern Altai Mountains, Xinjiang, China. Archaeol. Anthropol. Sci. 12, 1–11 (2020).
Motuzaitė-Matuzevičiūtė, G., Staff, R. A., Hunt, H. V., Liu, X. & Jones, M. K. The early chronology of broomcorn millet (Panicum miliaceum) in Europe. Antiquity 87, 1073–1085 (2013).
Dal, C. M., Pashkevych, G., Filipović, D., Liu, X., Motuzaitė, M. G., Stobbe, A. et al. Between Cereal Agriculture and Animal Husbandry: Millet in the Early Economy of the North Pontic Region. J. World Prehist. 35, 321–374 (2022).
Meadows, J., Dragana, F., Wiebke, K. Chronological modelling of the dispersal of broomcorn millet cultivation in Bronze Age Europe. European Association of Archaeologists, 26th Annual Meeting. 2020. https://www.researchgate.net/publication/344174657_Chronological_modelling_of_the_dispersal_of_broomcorn_millet_cultivation_in_Bronze_Age_Europe#fullTextFileContent.
Zhao, Z., Zhao, C., Yu, J., Wang, T., Cui, T. & Guo, J. Plant remains unearthed at the Donghulin site in Beijing: discussion on results of flotation. Chin. Archaeol. 21, 193–200 (2021).
Lee-Thorp, J. A. On Isotopes And Old Bones. Archaeometry 50, 925–950 (2008).
Wang, W., Liu, Y., Duan, F., Zhang, J., Liu, X., Reid, R. E., et al. A comprehensive investigation of Bronze Age human dietary strategies from different altitudinal environments in the Inner Asian Mountain Corridor. J. Archaeol. Sci. https://doi.org/10.1016/j.jas.2020.105201 (2020).
Svyatko, S. V., Schulting, R. J., Mallory, J. P., Murphy, E. M., Reimer, P. J., Khartanovich, V. I. et al. 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. J. Archaeol. Sci. 40, 3936–3945 (2013).
An, C., Dong, W., Li, H., Zhang, P., Zhao, Y., Zhao, X. et al. Variability of the stable carbon isotope ratio in modern and archaeological millets: evidence from northern China. J. Archaeol. Sci. 3, 316–322 (2015).
Wang, T., Fuller, B. T., Wei, D., Chang, X. & Hu, Y. 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. Int. J. Osteoarchaeol. 26, 693–704 (2016).
Henry, A. G. & Piperno, D. R. Using plant microfossils from dental calculus to recover human diet: a case study from Tell al-Raqā’i, Syria. J. Archaeol. Sci. 35, 1943–1950 (2008).
Fox, C. L., Pérez-Pérez, A. & Juan, J. T. Dietary information through the examination of plant phytoliths on the enamel surface of human dentition. J. Archaeol. Sci. 21, 29–34 (1994).
Yang, X., Wan, Z., Perry, L., Lu, H., Wang, Q., Zhao, C. et al. Early millet use in northern china. Proc. Natl. Acad. Sci. Usa. 10, 109 (2012).
Wu, L., Zhou, H., Li, J., Li, K. & Guo, Q. Thiessen polygon analysis and spatial pattern evolution of Neolithic cultural sites (8.0-4.0 ka bp) in Huaibei plain of Anhui, East China. Quat. Int. 521, 75–842019 (2019).
Zhu, Y., Hou, G., Lan, C. Z., Gao, J., & Pang, L. GIS based prehistoric transportation routes and zoning analysis on the Qinghai Tibet Plateau. Prog. Geogr. Sci. 03, 438-449 (2018).
Groucutt, S. H., White, S. T., Clark-Balzan, L. et al. Human occupation of the Arabian Empty Quarter during MIS 5: Evidence from Mundafan Al- Buhayrah, Saudi Arabia. Quat. Sci. Rev. 119, 116–135 (2015).
Chlachula, J. Environmental context and adaptations of prehistoric and early historical occupation in the Southern Altai (SW Siberia–East Kazakhstan). Archaeol. Anthropol. Sci. 11, 2215–2236 (2018).
Wang, X., Fuller, B. T., Zhang, P. et al. Millet manuring as a driving force for the Late Neolithic agricultural expansion of north China. Sci. Rep. 8, 5552 (2018).
Yang, J., Zhang, D., Yang, X. et al. Sustainable intensification of millet–pig agriculture in Neolithic North China. Nat. Sustain 5, 780–786 (2022).
Dong, Y. et al. The potential of stable carbon and nitrogen isotope analysis of foxtail and broomcorn millets for investigating ancient farming systems. Front. Plant Sci. 13, 1018312 (2022).
Qiu, Z., Wu, X., Guo, M. & Wang, G. Flotation results and analysis of plant remains at Xinglong Site in Kangbao County, Hebei Province from 2018 to 2019. Archaeology. 1, 106–120 (2023).
Lu, H. et al. Earliest domestication of common millet (Panicum miliaceum) in East Asia extended to 10,000 years ago. Proc. Natl. Acad. Sci. USA. 106, 7367–7372 (2009).
Yang, X., Zhang, J., Perry, L., Ma, Z., Wan, Z. et al. From the modern to the archaeological: starch grains from millets and their wild relatives in China. J. Archaeol. Sci. 39, 247–254 (2012).
Yang, X., Wan, Z., Perry, L., Lu, H., Wang, Q. et al. Early millet use in northern China. Proc. Natl. Acad. Sci. USA. 109, 3726–3730 (2012).
Li, F., Zhao, Y., Gaillard, M. J., Li, H., Sun, J. et al. Modern pollen-climate relationships in north Xinjiang, northwestern China: implications for pollen-based reconstruction of Holocene climate. Holocene 27, 951–966 (2017).
Yang, Y., Zhang, D., Sun, A. Z., Wang, W., Lan, B. et al. Pollen-based reconstructions of vegetation and climate changes during the late Holocene in the southern Altai Mountains. Holocene 29, 1450–1458 (2019).
Dongliang, Z. & Zhaodong, F. Holocene climate variations in the Altai Mountains and the surrounding areas: a synthesis of pollen records. Earth-Sci. Rev. 185, 847–869 (2018).
Zhang, D., Chen, X., Li, Y., Ran, M. & Feng, Z. Holocene moisture variations in the arid central Asia: new evidence from the southern Altai Mountains of china. Sci. Total Environ. 735, 139545 (2020).
Editorial Committee of Xinjiang Flora. Flora of Xinjiang Urumqi: Xinjiang Science and Technology Health Publishing House (1994).
Xiong, J. A comprehensive scientific survey of the Altay Mount Taishan Mountains in Xinjiang Beijing: Published by China Forestry Press (2020).
Jianhua, X., Victor, V. C., Yi, L., & Keping, M. Mapping Asia Plants: Historical outline and review of sources on floristic diversity in North Asia (Asian Russia). Glob. Ecol. Conserv., 24, e01287(2020).
Batlai, O., Shukherdorj, B., Khurelpurev, O., Oyunbileg, M., Kim, J. Y., Cho, H. J. & Choi, H. J. Contribution to the knowledge on the flora of Munkhkhairkhan Mountain area, Mongolia. J. Asia Pac. Biodivers. 10, 573–582 (2017).
Mavrodiev, Evgeny V., and A. P. Suchorukow “Systematische Beitrge zur Flora von Kasachstan.” (2003).
Zhao, P. & Xiao J. Chinese Wild Vegetable Resources (Essence) Bejing: Environmental Science Press (2006).
Ye, Q. New Compilation of Chinese Dietary Therapy Materia Medica Guangzhou: Guangdong Higher Education Press (1999).
Spengler, R., Frachetti M., Dupuy, P., Maryashev, A. N. Early agriculture and crop transmission among Bronze Age mobile pastoralists of Central Eurasia. Proc. R. Soc. B: Biol. Sci. 281 https://doi.org/10.1098/rspb.2013.3382 (2014).
Frachetti, M. D., Spengler, R. N., Fritz, G. J. & Mar’Yashev, A. N. Earliest direct evidence for broomcorn millet and wheat in the central Eurasian steppe region. Antiquity 84, 993–1010 (2010).
Doumani, P. N., Frachetti, M. D., Beardmore, R., Schmaus, T. M., Spengler, R. N. & Mar’yashev, A. N. Burial ritual, agriculture, and craft production among Bronze Age pastoralists at Tasbas (Kazakhstan). Archaeol. Res. Asia. 1, 17–32 (2015).
Vadet͡skai͡a, ĖB. Akrukh’s memoirs are on the grasslands of Central Asia. Science Magazine, Leningrad(1986). (in Russian) http://www.xn--80abubbalb5cgec5b4kf.xn--p1ai/find/lib/khkarasuk.pdf
Ivanov, N. E. & Ryaboginas, N. Ancient agriculture in Western Siberia: problems of argumentation, paleoethnobotanic methods, and analysis of data. Archaeol., Ethnol. Anthropol. Eurasia 39, 96–106 (2011).
Dudziak, A., Payunena M. Indo-European anthropological and cultural sources of the Ossetian heroic epic as an example of nomadism of ideas and values (problem statement): Индоевропейские антропологические и культурные источники осетинского героического эпоса как пример номадизма идей и ценностей (к постановке проблемы). pw [Internet]. 30 czerwiec 2019 [cytowane 9 grudzień 2024];10:289-304. (In Russian) https://czasopisma.uwm.edu.pl/index.php/pw/article/view/4525
Miller, B. K. Xiongnu Kings and the Political Order of the Steppe Empire. J. Econ. Soc. Hist. Orient. 57, 1–43 (2014).
Frachetti, M. D. Differentiated Landscapes and Non-uniform Complexity among Bronze Age Societies of the Eurasian Steppe. In: Hanks B. K., Linduff K. M., editors. Social Complexity in Prehistoric Eurasia: Monuments, Metals and Mobility. Cambridge: Cambridge University Press; 19−46 (2009).
Wang, T., Wei, D., Chang, X., Yu, Z., Zhang, X., Wang, C. et al. Tianshanbeilu and the Isotopic Millet Road: reviewing the late Neolithic/Bronze Age radiation of human millet consumption from north China to Europe. Natl. Sci. Rev. 6, 1024–1039 (2017).
Dong, W. M., An, C. B., Yu, J. J. & Chen, X. L. Study on the livelihood patterns of residents in the Bronze Age and Early Iron Age in Altay, Xinjiang: Based on bone isotopes. West. Reg. Stud. 1, 11 (2022).
Chen, X. L., Yu, J. J., You, Y. Horse Burial Customs in Karasu Cemetery in Xinjiang According to Carbon and Nitrogen Stable Isotopes. West. Reg. Res.04:89–98+143 017).http://dx.chinadoi.cn/10.16363/j.cnki.xyyj.2017.04.008
Shao, K. L., Zhang, J. P., Cong, D. X., Jia, W. M., Cui, A. N. & Wu, N. Q. Analysis of plant microfossils reveals the survival strategy of ancient people in the Adungqiaolu site. Quat. Sci. 1, 11 (2019).
Svyatko, S. V., Mallory, J. P., Murphy, E. M., Polyakov, A. V., Reimer, P. J. & Schulting, R. J. New Radiocarbon Dates and a Review of the Chronology of Prehistoric Populations from the Minusinsk Basin, Southern Siberia, Russia. Radiocarbon 51, 243–273 (2009).
Papin, D. B., Sviatko, C. B. DIET STRUCTURE O. F. The population of the Andronovskaya Culture Of Altai Based On Isotopic Analysis Data (Preliminary Results). Theory Pract. Archaeol. Res. 30:902 (2020).
Motuzaitė Matuzevičiūtė, G., Kiryushin, Y., Rakhimzhanova, S. Z., Svyatko, S. V., Tishkin, A. A. & O’Connell, T. C. Climatic or dietary change? Stable isotope analysis of Neolithic–Bronze Age populations from the Upper Ob and Tobol River basins. Holocene 26, 1711–1721 (2016).
Papin, D. B., Sviatko, C. B. According to archaeological and isotopic analysis data, there are problems with agriculture in Upper Europe. Theory and Practice of Archaeological Research. 902,571(2018).
Khabdulina, M. K. Some aspects of studying Nura Archaeological Culture (based on materials from the settlement of Shagalaly II). Archaeology of Kazakhstan [Internet]. 2018 Dec. 27 [cited 2024 Dec. 5] ;(1-2):69–85. https://www.archeokz.com/index.php/archeokz/article/view/34
Fox, C. L., Juan, J. & Albert, R. M. Phytolith analysis on dental calculus, enamel surface, and burial soil: information about diet and paleoenvironment. Am. J. Phys. Anthropol. 101, 101–113 (1996).
Tur, S. S., Kraskova, T. A. Naseleniye pazyrykskoi kultury Srednei Katuni: Zubnye indikatory paleodiety. In Drevniyei srednevekovye kochevniki Tsentralnoi Azii. Barnaul: Azbuka. 216−220 (2008).
Ventresca-Miller, A. R., Wilkin, S., Smithers, R., Larson, K., Spengler, R., Haruda, A., Kradin, N., Bazarov, B., Miyagashev, D., Odbaatar, T. et al. Adaptability of Millets and Landscapes: Ancient Cultivation in North-Central Asia. Agronomy 13, 2848 (2023).
He, L. T., Zhu, H., Li, W. Y. & Yidilis, A. Oral health and diet of residents in the Xiaohe cemetery in Lop Nur, Xinjiang. Acta Anthropol, Sin. 33, 497–509 (2014).
Zhang, X., Wei, D., Wu, Y. & Nie, Y. Yaowu H. Carbon and nitrogen stable isotope ratio analysis of Bronze Age humans from the Xiabandi cemetery, Xinjiang, China: Implications for cultural interactions between the East and West. Chin. Sci. Bull. 61, 3509–3519 (2016).
Jie, M., Jiang, H., Yang, Y., Idris, A., Hu, X. & Wang, C. Analysis of plant microfossils in food remains unearthed from the northern cemetery of Keriya River, Xinjiang. Orient. Archaeol. 1, 394–401 (2014).
Dong, G., Yang, Y., Liu, X., Li, H., Cui, Y., Wang, H. et al. Prehistoric trans-continental cultural exchange in the Hexi Corridor, northwest China. Holocene 28, 621–628 (2018).
Shao, H. Q. The evolution of cultural patterns in prehistoric Xinjiang and its relationship with neighboring cultures. Beijing: Science Press (2018). (In Chinese) https://book.sciencereading.cn/shop/book/Booksimple/show.do?id=B76C23F6611639E13E053020B0A0A22E7000
Kohl, P. L. The Making of Bronze Age Eurasia. Cambridge: Cambridge University Press; 2007. (Cambridge World Archaeology). https://doi.org/10.1017/CBO9780511618468
Jianjun, M. & Shell, C. The existence of Andronovo cultural influence in Xinjiang during the 2nd millennium BC. Antiquity 73, 570–578 (1999).
Betts, A., Jia, P. & Abuduresule, I. A new hypothesis for early Bronze Age cultural diversity in Xinjiang, China. Archaeol. Res. Asia. 17, 204–213 (2018).
Wei, P., Jia, M., Betts, A. V. G. Are-analysis of the Qiemu’erqieke (Shamirshak) cemeteries, Xinjiang, China. J. Indo-Eur. Stud. 38 (2010). https://www.researchgate.net/publication/275275447_A_re-analysis_of_the_Qiemu%27erqieke_Shamirshak_cemeteries_Xinjiang_China
Li, Y. Agriculture and palaeoeconomy in prehistoric Xinjiang, China (3000–200 BC). Veget Hist. Archaeobot. 30, 287–303 (2020).
He, K., Lu, H., Zhang, J. & Wang, C. Holocene spatiotemporal millet agricultural patterns in northern China: a dataset of archaeobotanical macroremains. Earth Syst. Sci. Data 14, 4777–4791 (2022).
Kovalev, A. (ed), Earliest Europeans in the Heart of Asia: The Chemurchek Cultural Phenomenon, Part 2, St.-Petersburg, 2015.
Lymer, K. Review of pastoralist landscapes and social interaction in bronze age eurasia by michael d. frachetti. J. R. Asiatic Soc. 20, 551–553 (2010).
Chernyky, E.N. Ancient metallurgy in the USSR-The Early Metal Age, Translated by Sarah Wright, Cambridge University Press (1992).
Krim, A. J. The Horse, the Wheel and Language. Geogr. Rev. 98, 571 (2008).
Ning, C. et al., Ancient Genomes Reveal Yamnaya-Related Ancestry and a Potential Source of Indo-European Speakers in Iron Age Tianshan, Curr. Biol. https://doi.org/10.1016/j.cub.2019.06.044 (2019).
Jacobsontepfer, E. The hunter, the stag, and the mother of animals. London: Oxford University Press (2015).
En, W. On the age of the deer stone in Mongolia and related problems. Archaeology and Cultural Relics. 1, 10 (2003).
Emma, C. Traders and raiders on China’s northern frontier /. Arthur M. Sackler Gallery, Smithsonian Institution, in association with University of Washington Press.
Shelach-Lavi, G. ‘Steppe Land Interactions and Their Effects on Chinese Cultures during the Second and Early First Millennia BCE’, in Reuven Amitai, and Michal Biran (eds), Nomads as Agents of Cultural Change: The Mongols and Their Eurasian Predecessors (Honolulu, HI, 2014; online edn, Hawai’i Scholarship Online, 17 Nov. 2016), https://doi.org/10.21313/hawaii/9780824839789.003.0002, accessed 5 Dec. 2024.
Li, T., Ning, C., Zhushchikhovskaya, I. S., Hudson, M. & Robbeets, M. Millet agriculture dispersed from Northeast China to the Russian Far East: Integrating archaeology, genetics, and linguistics. Archaeol. Res. Asia. 22, 100177 (2022).
Liu, L., Duncan, N. A., Chen, X., Liu, G. & Zhao, H. Plant domestication, cultivation, and foraging by the first farmers in early Neolithic Northeast China: Evidence from microbotanical remains. Holocene 25, 1965–1978 (2015).
Cosmo, N. D. Ancient Inner Asian Nomads: Their Economic Basis and Its Significance In Chinese History. J. Asian Stud. 53, 1092–1126 (1994).
Liu, X., Hunt, H. V. & Jones, M. K. River valleys and foothills: changing archaeological perceptions of North China’s earliest farms. Antiquity 83, 82–95 (2009).
Svyatko, S. V., Schulting, R. J., Papin, D. & Reimer, P. J. Millet consumption in siberia prior to mid-second millennium bc? A review of recent developments. Radiocarbon 63, 1547–1554 (2021).
Barton, L. et al. Agricultural origins and the isotopic identity of domestication in northern China. Proc. Natl. Acad. Sci. 106, 5523–5528 (2009).
Kovalev, A. A., Erdenebaatar D. Discovery of new cultures of the Bronze Age in Mongolia according to the data obtained by the International Central Asian Archaeological Expedition. In: Current Archaeological Research in Mongolia. Bonn: Bonn University Press. 149–170(2009).
Korolyuk, E. A. & Polosmak, N. V. Plant Remains From Noin Ula Burial Mounds 20 And 31 (Northern Mongolia). Archaeol. Ethnol. Anthropol. Eurasia 38, 57–63 (2010).
Wright, J., Honeychurch, W. & Amartuvshin, C. The Xiongnu settlements of Egiin Gol, Mongolia. Antiquity 83, 372–387 (2009).
Wilkin, S., Miller, A. V., Miller, B. K., Iii, R. N. S., Taylor, W. T. T., Fernandes, R. et al. Economic Diversification Supported the Growth of Mongolia’s Nomadic Empires. Sci. Rep. 10, 3916 (2020).
Gravel-Miguel, C., Wren, C. D. Agent-based least-cost path analysis and the diffusion of Cantabrian Lower Magdalenian engraved scapulae. J. Archaeol. Sci. https://doi.org/10.1016/J.JAS.2018.08.014 (2018).
Howey, M. C. Using multi-criteria cost surface analysis to explore past regional landscapes: a case study of ritual activity and social interaction in Michigan, AD 1200–1600. J. Archaeol. Sci. 34, 1830–1846 (2007).
Stolarksy, K., Doyle, P.G. & Snell, J. L. Random Walks and Electric Networks. American Mathematical Monthly. 94: 202–205(1987).
Xu, C., Zhu Y., Wang, Y. GIS based analysis of traffic routes and geological division of Qinghai-Tibetan in Prehistoric Period. DEStech Trans. Eng. Technol. Res. (2018).
Gueimil-Farina, APOC. “Dotting the joins”: a non-reconstructive use of Least Cost Paths to approach ancient roads. The case of the Roman roads in the NW Iberian Peninsula. J. Archaeol. Sci. 54: 31–44(2015).
Wachtel, I., Zidon, R., Garti, S. et al. Predictive modeling for archaeological site locations: Comparing logistic regression and maximal entropy in north Israel and north-east China. J. Archaeol. Sci. 92, 28–36 (2018).
Lancuo, Z., Hou, G., Xu, C., Jiang, Y., Wang, W., Gao, J., et al. Simulation of exchange routes on the Qinghai-Tibetan Plateau shows succession from the neolithic to the bronze age and strong control of the physical environment and production mode. Front. Earth Sci. https://doi.org/10.3389/feart.2022.1079055 (2023).
Roffet-Salque, M., Arkadiusz, M., Valdes, P. J., Kamilla, P., Joanna, P., Lech, C. et al. Evidence for the impact of the 8.2-kyBP climate event on Near Eastern early farmers. Proc. Natl. Acad. Sci. USA. 115, 8705–8709 (2018).
Marcott, S. A., Shakun, J. D., Clark, P. U. & Mix, A. C. A reconstruction of regional and global temperature for the past 11,300 years. Science 339, 1198–1201 (2013).
Feng, Z., Sun, A., Abdusalih, N., Ran, M., Kurban, A., Lan, B. et al. Vegetation changes and associated climatic changes in the southern Altai Mountains within China during the Holocene. Holocene 27, 683–693 (2017).
Chen, F., Jia, J., Chen, J., Li, G., Zhang, X., Xie, H. et al. A persistent Holocene wetting trend in arid central Asia, with wettest conditions in the late Holocene, revealed by multi-proxy analyses of loess-paleosol sequences in Xinjiang, China. Quat. Sci. Rev. 146, 134–146 (2016).
Zhang, D. L. & Feng, Z. D. Holocene climate variations in the Altai Mountains and the surrounding areas: A synthesis of pollen records. Earth-Sci. Rev. 185, 847–869 (2018).
Xu, H., Zhou, K., Lan, J., Zhang, G. & Zhou, X. Arid Central Asia saw mid-Holocene drought. Geology 47, 255–258 (2019).
Rao, Z., Huang, C., Xie, L., Shi, F., Zhao, Y., Cao, J. et al. Long-term summer warming trend during the Holocene in central Asia indicated by alpine peat α-cellulose δ13C record. Quat. Sci. Rev. 203, 56–67 (2019).
Lightfoot, E., Motuzaitė-Matuzevičiūtė, G., O’Connell, T. C., Kukushkin, I. A., Loman, V., Varfolomeev, V. et al. How ‘pastoral’ is pastoralism? Dietary diversity in Bronze Age communities in the Central Kazakhstan steppes*. Archaeometry 57, 232–249 (2015).
Marchenko, Z. V., Panov, V. S., Grishin, A. E., Zubova, A. V. Reconstruction and dynamics of food structure of the odino people in the baraba forest-steppe area during the 3rd millennium bc: according to archaeological and isotopic data. Vestnik arheologii antropologii i etnografii. 164-178 (2016).
Tang, Y. Holocene environmental changes inferred from GDGTs from peatlands in the Altai Mountains, Xinjiang of China. Master’s Thesis, Lanzhou University of China (in Chinese) (2014).
Xiaozhong, H., Wei, P., Natalia, R., Grimm, E. C., Xuemei, C., & Xianyong, C., et al. Holocene vegetation and climate dynamics in the Altai Mountains and surrounding areas. Geophys. Res. Lett., https://doi.org/10.1029/2018GL078028 (2018).
Hu, Y., Huang, X., Demberel, O., Zhang, J., Xiang, L., Gundegmaa, V. et al. Quantitative reconstruction of precipitation changes in the Mongolian Altai Mountains since 13.7 ka. CATENA 234, 13 (2024).
Sun, A., Feng, Z., Ran, M. & Zhang, C. Pollen-recorded bioclimatic variations of the last 22,600 years retrieved from Achit Nuur core in the western Mongolian plateau. Quat. Int. 311, 36–43 (2013).
Aizen, E. M., Aizen, V. B., Takeuchi, N., Mayewski, P. A., Grigholm, B., Joswiak, D. R. et al. Abrupt and moderate climate changes in the mid-latitudes of Asia during the Holocene. J. Glaciol. 62, 411–439 (2016).
Chen, F.-H. et al. Vegetation and climate history reconstructed from an alpine lake in central Tianshan Mountains since 8.5 ka bp. Palaeogeogr. Palaeoclimatol. Palaeoecol.: Int. J. Geo-Sci. 432, 36–48 (2015).
