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Review

Climate Change along the Silk Road and Its Influence on Scythian Cultural Expansion and Rise of the Mongol Empire

by
Ping Che
1 and
Jianghu Lan
2,3,4,*
1
Department of Foreign Languages, Xianyang Normal University, Xianyang 712000, China
2
State Key Laboratory of Loess and Quaternary Geology, Institute of Earth Environment, Chinese Academy of Sciences, Xi’an 710061, China
3
China-Pakistan Joint Research Center on Earth Sciences, Chengdu 610041, China
4
Center for Excellence in Quaternary Science and Global Change, Chinese Academy of Sciences, Xi’an 710061, China
*
Author to whom correspondence should be addressed.
Sustainability 2021, 13(5), 2530; https://doi.org/10.3390/su13052530
Submission received: 8 February 2021 / Revised: 20 February 2021 / Accepted: 21 February 2021 / Published: 26 February 2021
(This article belongs to the Special Issue Local- to Global-Scale Environmental Issues)
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Abstract

:
Climate change and cultural exchange both influenced cultural development along the continental Silk Road during the late Holocene, but climate change and its influence on nomadic civilizations during that time has yet to be systematically assessed. In this study, we analyzed records of climate change along the Silk Road covering key periods in the late Holocene, based on multiproxies from various archives including lake sediments, shorelines/beach ridges, peatlands, ice cores, tree rings, aeolian sediments, moraines, and historical documents. Combined with archaeological data, we assessed the influence of climate on development and expansion of representative pastoral nomadism. Our results show that the most notable climate changes in Central Asia were characterized by decreasing temperature, expanding glaciers, increasing precipitation, and increasing humidity during transitions from the Sub-Boreal to Sub-Atlantic Period (ca. 9–8th century BC) and from the Medieval Warm Period to the Little Ice Age (ca. 13–14th century AD). The two periods coincided with Scythian Cultural expansion across the steppe landscape of Central Asia and rise of the Mongol Empire, respectively. These temporal coincidences are interpreted as causally related, where temperature fall and glacial advance may have forced the pastoral nomadism to southward migration. Coeval wetness and southward migration of steppe landscape in Central Asia were beneficial for these cultural expansions, which spanned the Eurasian arid and semi-arid zone westward. Therefore, during the historical period when productivity was underdeveloped, although expansions of pastoral nomadism were closely related to internal social structures, climate change was possibly the most critical controlling factor for sustainability development and collapse.

1. Introduction

Spanning Eurasia, the Silk Road was not only an important trade passageway linking Eastern Asia and Europe in historical times but also a channel for technical, intellectual, and cultural exchange across Asia and Europe, and a link between Eastern and Western civilizations [1]. The arid and semi-arid zone, located in the hinterland of the Eurasian continent, is a key area within the continental Silk Road Economic Belt and is one of the driest areas in the world, with a fragile ecological environment highly sensitive to climate change [2,3]. A comprehensive study into climate change during this historical period has the potential to greatly increase our understanding of key issues, such as climate change process, its driving mechanisms, and prospective variations and trends, and could provide scientific evidence regarding possible climatic risks that the national “Belt and Road Initiative” [4]. In addition, previous studies showed that extensive cultural exchange between Eastern and Western civilizations occurred along the ancient Silk Road in prehistoric times [5,6,7,8]. Pagel et al. [9] even suggested that thousands of European and Asian languages split from a Eurasian language 15,000 years ago. The differentiation and dissemination of languages is closely related to human activities, which are in turn influenced by climate change [10]. Hence, interpreting past climate change is important for understanding social change, cultural/civilization exchange, and language evolution in Eurasia during prehistoric and historical periods.
Instrumental data are widely used to carry out climate change research, but there are clear limitations in temporal and spatial scales, which make it impossible to fully characterize past climate in this way. For example, the longest instrumental data available spans less than 200 years, and in Central Asia (including Northwest China) the data are at most only 60–70 years in length. This severely restricts our ability to obtain a comprehensive understanding of Earth’s past climate system, including on annual and decadal time scales. In addition, model simulations are not yet able to provide reliable predictive results independent of natural geological records [11,12]. Therefore, the most reliable method to assess our current and arguably future climate status is to reconstruct past climate change using high-resolution natural geological and biological records, accurate dating, and multiproxy interpretation.
This study summarizes data from various geological archives, including lake sediments, shorelines/beach ridges, peatlands, ice cores, tree rings, aeolian sediments, and moraines, in the arid and semi-arid zone of Central Asia. Combined with historical records, we assess past climate change along the Silk Road during critical periods over the past 3000 years. Finally, we combine this information with archaeological data and focus on the influence of transition-related climate change (cold–warm and dry–wet cycles), and assess the ecological environment of Central Asia as related to climate change during the early Sub-Atlantic Period (ca. 9–8th century BC) and the expansion of Scythian culture, as well as during the early Little Ice Age (LIA; ca. 13–14th century AD) and the rise and westward expansion of the Mongol Empire. The aim of this study is to understand the connections more clearly between climate and environmental change, and human activities and the vicissitude of civilization along the Silk Road in prehistoric and historical periods, which is benefit for understanding the sustainability for human being, especially under the continued global warming scenario.

2. Study Region

Central Asia is located in the mid-latitudes of the Northern Hemisphere, deep within the hinterland of the Eurasian continent. Its terrain is largely composed of low-elevation (<1000–1500 m) inland plains and high-altitude mountain systems (>2500 m). From west to east, they comprise the Central Asian Plain, Southern Siberian Plain, Altai Mountains-Tianshan Mountains-Pamir Plateau, Junggar Basin, Tarim Basin, and Mongolian Plateau (Figure 1). Blocked by high terrains, monsoon circulations are unable to penetrate into the region, and therefore precipitation largely depends on water vapor carried in by mid-latitude Westerlies circulation [2,3,13,14,15,16,17,18]. The sides of high mountain ranges act as “water towers” and water conservation areas, with average annual rainfall of >500 mm in windward slope. Conversely, precipitation over the plains and basins is scarce, with annual mean rainfall of <200–300 mm, and even less (<50 mm) in extremely arid water-consumption areas. Precipitation in northern semi-humid areas is greater than southern arid and semi-arid areas, which influences the natural landscapes which are, from north to south, the northern Taiga, central grassland-steppe, and southern Gobi Desert [19,20,21]. Human activities largely took place in the foothills of mountains in oasis zones [2], which hosted the central routes of the Silk Road between East Asia and eastern Mediterranean (trans-Eurasian exchange) [8]. Recently, Tan et al. [8] suggested that after the middle Holocene megadrought, the earliest transcontinental exchange started at the 5th millennium BP along the Eurasian steppe.

3. Materials and Methods

Much research has been published on late Holocene climate change in Central Asia [3,15,17,22]. Over the past decade, with the improvement of dating methods and the comprehensive application of multiproxy indictors, the mysteries of late Holocene climate change in Central Asia have become gradually clear. In this study, we selected previously published records with the most reliable chronologies and proxy indicators from various archives, such as lake sediments, shorelines/beach ridges, peatlands, ice cores, tree rings, aeolian deposits, moraines, and historical documents, to assess the climate change over the past 3000 years. The database of the records is according to several criteria: (1) records from semi-humid, semi-arid, and arid areas in Central Asia; (2) records covering our target transition periods in the late Holocene (i.e., the transitions from the Sub-Boreal to the Sub-Atlantic Period and the Medieval Warm Period (MWP) to the LIA); (3) records with a reliable chronology (the “reservoir effect” on chronology of lake sediments was evaluated); and (4) proxies are sensitive to the changes of cold–warm and dry–wet. Based on these criteria, we selected 40 records, which include 30 lake deposits and shorelines/beach ridges, 4 peatlands, 1 ice core, 1 tree rings, 2 aeolian deposits, 2 moraines, and 1 historical document. Site distribution is shown in Figure 2 and Figure 3, and more detailed information is listed in Table 1.
It should be note that, all ages were calibrated from original laboratory 14C dates to calendar years before present (1950 AD) using the Calib Rev 7.0.2 [23,24]; and we then present them as BC and AD.
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Figure 2. The distribution of climate records in Central Asia during the Scythian cultural period (ca. 9th–3rd century BC; A list of sites, including references for each record, can be found in Table 1). The brown shaded area indicates the largest areal extent influenced by Scythian culture influenced [25,26].
Figure 2. The distribution of climate records in Central Asia during the Scythian cultural period (ca. 9th–3rd century BC; A list of sites, including references for each record, can be found in Table 1). The brown shaded area indicates the largest areal extent influenced by Scythian culture influenced [25,26].
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Figure 3. The distribution of climate records in Central Asia during the Mongol Empire period (ca. 13th–14th century AD; Site numbers show in Table 1). The brown shaded area shows the largest areal extent of the Mongol Empire [27].
Figure 3. The distribution of climate records in Central Asia during the Mongol Empire period (ca. 13th–14th century AD; Site numbers show in Table 1). The brown shaded area shows the largest areal extent of the Mongol Empire [27].
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Table
Table 1. Paleoclimate archives referred to in this study. Site number as in Figure 2 and Figure 3.
Table 1. Paleoclimate archives referred to in this study. Site number as in Figure 2 and Figure 3.
No.NameLat. (°N)Long. (°E)Alt. (Meter)ProxiesProxy IndicationClimate ConditionsReferences
1Caspian Sea41.62 50.95 −27Shorelines/beach ridgesLake level750–250 BC, and since 1280 AD: high levelKroonenberg et al., 2007 [28]; Kakroodi et al., 2012 [29]
PollenLake level1350, 1352, and 1408 AD: high lake levelHaghani et al., 2016 [30]
PollenLake level650BC–50 AD: high lake levelRamezani et al., 2016 [31]
2Aral Sea45.02 59.50 29DiatomLake level, salinity, and conductivityLIA: high lake level and low salinitySorrel et al., 2006 [32]; Austin et al., 2007 [33]
3Lake Kyrtyma56.99 65.83 54Plant macrofossils and geochemical indicesMoisture and temperature850–50 BC: wetting and coldRyabogina et al., 2019 [34]
4Oshukovsko Peat bog57.05 65.86 55Plant macrofossilsMoisture and temperature850–50 BC: wet and coldRyabogina et al., 2019 [34]
5Lake Balkhash46.54 74.86 340XRF, pollen, diatom, and ostracodLake level1200–1400 AD: high lake levelEndo et al., 2012 [35]
PollenPrecipitation and temperatureSince 550 BC: increased precipitation and coldFeng et al., 2013 [36]
Shorelines and pollenLake level750–1150 AD: low lake levelSince 1250 AD: high lake levelSala et al., 2017 [37]
6Lake Son Kol41.85 75.14 3014Alkane δDn-C29MoistureLIA: wetLauterbach et al., 2014 [38]
7West Tianshan tree ring41.67 76.43 2700–3900Ring widthTemperatureLIA: coldEsper et al., 2002 [39]
8Lake Issyk-kul42.50 77.10 1603Shorelines and historical document Lake level13–19th AD: high lake levelRomanovsky, 2002 [40]
Historical document and archeological dataLake level11th BC–1st AD: 12–13 m high than model lake levelRomanovsky, 2002 [40]
Historical mapLake level15–19th AD: high lake levelNarama et al., 2010 [41]
9Lake Sasikul37.70 73.18 3816TIC and its δ18OMoistureLIA: wetLei et al., 2014 [42]
10Lake Karakul38.48 75.01 3645leaf wax δDMoistureLIA: wetAichner et al., 2015 [43]
XRF and grain sizeTemperature and glacier fluctuation1000–350 BC and LIA: decreased temperature and glacier advanceLiu et al., 2014 [44]
11Kongur Mt.38.64 75.04 4178MoraineTemperature and glacier fluctuationLIA: decreased temperature and glacier advanceSeong et al., 2009 [45]
12Muztag Ata38.35 75.17 4228MoraineTemperature and glacier fluctuationLIA: decreased temperature and glacier advanceSeong et al., 2009 [45]
13Guliya ice core35.28 81.48 6710Net accumulation ratePrecipitationLIA: increased precipitationThomspon et al., 1995 [46]; Yao et al., 1996 [47]
14Keriya River37.86 81.51 1350TerracePrecipitationLIA: increased precipitationYang et al., 2002 [48]
15Niya section37.13 82.78 1371Carbonate δ13C and grain sizeMoistureSince 1000 BC: wetZhong et al., 2004 [49]
16Lake Sayram44.61 81.16 2074TOC, C/N, grain size, carbonate content and its δ18O-δ13CMoisture and precipitation850–210 BC and 1060–1670 AD: wet and increased precipitationLan et al., 2019 [17]; Lan et al., 2020a [15]
17Lake Ebinur44.88 82.97 195Pollen and carbonate δ18OMoisture/lake levelLIA: wet and high lake levelMa et al., 2011 [50]; Wang et al., 2013 [51]
18Lake Harnur43.11 83.97 2941Grain sizePrecipitation and temperature1300–1870 AD: increased precipitation and coldLan et al., 2018 [22]
19Lake Manas45.83 85.97 244Alkenone %C37:4Salinity/lake levelLIA: low salinity and high lake level Song et al., 2015 [52]
Alkenone UK’37TemperatureLIA: cold Song et al., 2015 [52]
20Lake Bosten41.99 86.98 1051Grain size, TOC, pollen, carbonate content and its δ18O-δ13CMoisture1050–220 BC and LIA: wetChen et al., 2006 [53]; Zhang et al., 2010 [54]; Zhou et al., 2020 [55]
21Eastern Tarim Basin39.77 88.38 814Plant δ13CMoistureLIA: wetLiu et al., 2011 [56]
22Lop Nur39.71 89.92 791ShorelinesLake level1180 AD: high levelPutnam et al., 2016 [57]
23Lake Gahai37.13 97.55 2852Alkenone UK’37TemperatureLIA: coldHe et al., 2013 [58]
24Big Black peat 48.67 87.18 2167Cellulose δ18OMoistureLIA: wetXu et al., 2019 [16]
25Lake Uzunkol 50.48 87.11 1985PollenTemperature850–250 BC: coldBlyakharchuk et al., 2004 [59]
26LakeKendegelukol50.49 87.65 2050PollenMoisture850–150 BC: wetBlyakharchuk et al., 2004 [59]
27Kuray Basin50.13 88.85 2330PollenMoisture950–210 BC: wetSchlütz and Lehmkuhl, 2007 [60]
28Lake Teletskoye51.70 87.65 430PollenTemperatureSince 1250 AD: coldRudaya et al., 2016 [61]
29Lake Shira54.51 90.19 349PollenMoistureSince 1200 AD: wetHildebrandt et al., 2015 [62]
30Lake Kutuzhekovo53.59 91.94 320PollenMoisture850–50 BC: wetDirksen and van Geel, 2004 [63]; van Geel et al., 2004 [25]
31Lake Shushenskoe53.31 92.05 272PollenMoisture880–150 BC: wetDirksen et al., 2007 [64]
32Lake Big Kyzykul53.73 92.11 342PollenMoisture930 BC–400 AD: wetDirksen et al., 2007 [64]
33Lugovoe peat52.86 93.36 1299PollenMoisture900–400 BC: wet Blyakharchuk et al., 2019 [65]
34Lake White52.07 93.71 830PollenMoisture850–50 BC: wetDirksen and van Geel, 2004 [63]; van Geel et al., 2004 [25]
35Uvs Nuur50.32 92.72 760ShorelineLake level850 BC: high lake levelGrunert et al., 2000 [66]
36Bayan Nuur48.46 95.11 1505PollenMoisture1150–1850 AD: wetYang et al., 2020 [67]
37Lake Telmen48.83 97.29 1789Pollen, CaCO3, X-ray mineralogy, diatom, ostracod, TOC, δ13CMoistureSince 760 BC: wetPeck et al., 2002 [68]
38Lake Khuisiin46.61 101.76 2280PollenMoisture1380–1830 AD: wetTian et al., 2013 [69]
39Ugii Nuur47.76 102.77 1332PollenMoisture850–250 BC: wetWang et al., 2009 [70]; Wang et al., 2011 [71]
40Badain Jaran Desert39.77 102.40 1398Chloride concentrationRecharge rate of groundwater/MoistureLIA: wetMa and Edmunds, 2006 [72]; Gates et al., 2008 [73]

4. Synthesis

As shown in Table 1 and Figure 3 and Figure 4, the Central Asia has evidently experienced a series of climate change events during the late Holocene, in which lower temperature and glacier advance are remarkably attendant with enhanced precipitation, higher lake level, and increased moisture during the early Sub-Atlantic Period (ca. 850–200 BC) and early LIA (ca. 13–14th century AD). Furthermore, based on the archaeological data and historical materials, we found that the Scythian culture and the Mongol Empire were blooming and expansion at ca. 9th–3rd century BC and 1206–1368 AD, respectively, which are both broadly contemporaneous with the cold–wet climate conditions in Central Asia. In the following section, we discuss the climate change in detail and assess its influence on Scythian cultural expansion and rise of the Mongol Empire.

4.1. Climate Variations during Key Intervals of the Past 3000 Years

Owing to a decrease in solar radiation, earth’s climate system during the late Holocene has experienced significant long-term cooling with a series of centennial-scale climate oscillations. Among these, the most significant features are the transitions from the Sub-Boreal to the Sub-Atlantic Period, the Roman Warm Period to the Dark Age Cold Period (DACP), and the MWP to the LIA. Although the timings of these well-known climate transitions are possibly diachronous on a global scale [12], they are likely synchronous on a regional scale [14,15,74]. By analysis of multiple geological archives and historical document, this study focuses on climatic characteristics of the early Sub-Atlantic period and the early LIA.

4.1.1. Temperature and Glacier Fluctuations

In the early first millennium BC (ca. 1000–800 BC), the Northern Hemisphere climate became significantly colder than the Sub-Boreal to Sub-Atlantic Period (Figure 4) [25,75,76,77], with glacier advances [78]. During the Roman Warm Period, temperature rose again, whereby the subsequent low temperature during the DACP and the LIA were interrupted by the MWP (Figure 4) [79,80,81,82,83].
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Figure 4. Temperature variations and glacier fluctuations in Northern Hemisphere (NH) and Central Asia during the late Holocene. (a) Northern high-latitude (NHL) temperature anomalies (from the base year of 1961–1990) reconstructed from argon and nitrogen isotopes from trapped air in a GISP2 ice core [76], (b) Swiss Alps Glacier fluctuations [78], (c) glacier fluctuations indicated by Rb/Sr ratio of Lake Karakul on the Pamir Plateau [44], (d) temperature anomalies for the NH (black line [79]; blue line [80]) and the extra-tropical NH (red line [81]), (e) temperature indices for the West Tianshan Mountains based on tree ring width [39], (f) temperature indices for the northwestern China by analysis of UK’37 in Lake Manas [52], (g) temperature indices of Central Tianshan Mountains based on fine-grain size in Lake Harnur [22], and (h) number of 14C dates of late Holocene archaeological sites for southern Siberia and central Asia (dot line), Tuva (cross line), and Khakassia (diamond line) [25]. The gray shadings indicate the Scythian culture blooming and expansion during the early Sub-Atlantic Period and the Mongol Empire during the early Little Ice Age (LIA).
Figure 4. Temperature variations and glacier fluctuations in Northern Hemisphere (NH) and Central Asia during the late Holocene. (a) Northern high-latitude (NHL) temperature anomalies (from the base year of 1961–1990) reconstructed from argon and nitrogen isotopes from trapped air in a GISP2 ice core [76], (b) Swiss Alps Glacier fluctuations [78], (c) glacier fluctuations indicated by Rb/Sr ratio of Lake Karakul on the Pamir Plateau [44], (d) temperature anomalies for the NH (black line [79]; blue line [80]) and the extra-tropical NH (red line [81]), (e) temperature indices for the West Tianshan Mountains based on tree ring width [39], (f) temperature indices for the northwestern China by analysis of UK’37 in Lake Manas [52], (g) temperature indices of Central Tianshan Mountains based on fine-grain size in Lake Harnur [22], and (h) number of 14C dates of late Holocene archaeological sites for southern Siberia and central Asia (dot line), Tuva (cross line), and Khakassia (diamond line) [25]. The gray shadings indicate the Scythian culture blooming and expansion during the early Sub-Atlantic Period and the Mongol Empire during the early Little Ice Age (LIA).
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In Central Asia, temperature decreased, and glaciers expanded during the early Sub-Atlantic Period (Figure 4) [34,44,63,84,85]. For example, in the forest-steppe ecotone of northern Central Asia (southern Western Siberia), the combination of geochemical proxies and plant macrofossils of Lake Kyrtyma and Oshukovskoe peat bog recorded a significant cooling at ca. 850 BC [34], which is consistent with reconstructed annual average temperature change in this area [84]. Pollen-based mean annual temperature from Lake Balkhash in eastern Kazakhstan suggests that temperature in the early Sub-Atlantic Period was significantly lower than the subsequent period [36]. Unfortunately, this record does not cover the entire Sub-Atlantic Period and fails to record the Sub-Boreal to Sub-Atlantic transition. However, pollen records from Lake Uzunkol on the Ulagan Plateau in the Altai Mountains show that the pollen abundance of thermophilic Betula decreased significantly during ca. 850-250 BC, while cryophilous Pinus increased relatively [59], indicating that the temperature dropped sharply during this period. Similarly, records from Lake Kutuzhekovo in the Minusinsk depression of southern Siberia showed that abundance of Pinus sibirica remained low during ca. 850-50 BC, indicating that forest expansion was prevented, which could be explained by the persistence of relatively cold conditions [25,63]. In addition, from the high-altitude mountains in Central Asia, such as the Pamir, Tianshan, and Altai mountains, glaciers expanded in the early Sub-Atlantic Period [44,85,86,87,88]. For example, X-ray fluorescence spectroscopy (XRF) and grain size from alpine glacial Lake Karakul, located in the Pamir Mountains, revealed that the Muztag Glacier expanded significantly during 850-250 BC (Figure 4) [44].
Moreover, tree ring, ice core, lake sediment, marine sediment, speleothem, coral, glacier ice, and documentary [12,79,80,81,83] have clearly suggested that the Northern Hemisphere temperature dropped and glaciers advanced significantly during the LIA (Figure 4). In Central Asia, 1300 years tree ring data from the West Tianshan Mountains in western Central Asia suggest that temperatures during the LIA were significantly lower than for the MWP, and that below-average temperatures started to occur in 1140 AD [39]. This interpretation was supported by sediment-grain-size data of Lake Harnur in the Central Tianshan Mountains [22]. Sedimentary biomarkers from Lake Gahai and Lake Manas in northwest China showed that significant cooling during the LIA began at ca. 1250 AD [52,58,89]. The temperature reconstructions from Lake Teletskoye in the northeastern Altai Mountains showed that the LIA began at ca. 1200 AD, and that temperature fell by more than 3 °C [61]. In terms of glacial activity, sedimentary Rb/Sr ratios from Lake Karakul in the Pamirs revealed that the Muztag Glacier expanded significantly during ca. 1200–1870 AD (Figure 4) [44], which is consistent with the 10Be exposure age of moraines on Muztag Ata and Kongur Mountains [45]. Dating from 10Be, 14C, and optically stimulated luminescence (OSL) of moraines in the Tianshan and Altai Mountains also showed that the LIA experienced significant glacial expansion in that interval [88,90,91]. The glacial area in the Altai Mountains during the LIA maximum was twice as large as today, and the average weighted equilibrium line altitude (ELA) fell by ~89 m during the LIA maximum [92].
In summary, an increasing body of evidence suggests temperatures in Central Asia decreased during the early Sub-Atlantic and the LIA, associated with significant glacial advance.

4.1.2. Hydroclimatic Variations

Hydroclimatic variations during the late Holocene in Central Asia are better constrained than temperature and glacier fluctuations (Table 1). For example, Chen et al. [3] have first comprehensively reconstructed the moisture changes over the last millennium in arid Central Asia based on multiple proxies from 17 paleorecords, suggesting the LIA was relatively humid (Figure 5). This finding was supported by 34 geological records in this region [93]. Subsequently, by analysis of the hydroclimatic change over the last 2000 and 4000 years in Central Asia, Lan et al. [15,17,22] found a series of increased precipitation and/or moisture periods during the late Holocene and suggested a prevailing warm-dry and cold–wet hydroclimatic pattern over the Westerlies-dominated Central Asia during the past two millennia (Figure 5).
Geological evidences from the Caspian Sea have shown that sea level was about 3–4.5 m higher than modern sea level during 750–250 BC and since 1280 AD, indicating that the Caspian Sea had higher sea level during the early Sub-Atlantic and LIA periods (Figure 5) [28,29,94,95]. Pollen data from the Mazgah and Langarud wetlands in the southern coast of the Caspian Sea showed that tree growth was hampered during the early Sub-Atlantic Period and the LIA due to brackish water invasion during sea-level rise [30,31]. Furthermore, sedimentary diatoms from the Aral Sea indicate that salinity and palaeoconductivity decreased and sea level rose during 1350–1780 AD (Figure 5) [32,33]. Lake Kyrtyma and Oshukovskoe peat bog plant macrofossils from northern Central Asia show that Carex aquatilis reached its maximum abundance at 850–50 BC, suggesting summer precipitation and groundwater levels increased significantly during that interval, marking it the wettest stage of the late Holocene [34]. Pollen data from Lake Balkhash showed that the Artemisia/Chenopodium ratio was highest in the early Sub-Atlantic Period, indicating a humid climatic environment, which is further evidenced by a quantitative reconstruction of precipitation from pollen [36]. By analysis of sedimentary multiproxies, such as XRF, pollen, diatom, and ostracod, Endo et al. [35] proposed that Lake Balkhash had low water levels during the MWP, which rose significantly at 1200 AD. Lake Balkhash subsequently experienced a short-term water level fall in the 16th century, and then a rise again in the 17–19th century [35,37] that was also recorded in historical documents [41].
Evidence from the arid region of northwest China also indicates a clear wetness during the early Sub-Atlantic Period and LIA (Figure 5). For example, δ13C of carbonate and grain size in Niya Section [49], and δ18O and δ13C of carbonate, carbonate mineralogy, and grain size in Lake Bosten [54] from the Tarim Basin indicate moist climate condition and low salinity since ca. 1000 BC, indicating that the climate and environment had ameliorated in the early Sub-Atlantic Period (Figure 5). Furthermore, a large body of evidence has record an increase in precipitation and humidity as well as lake level during the LIA (Figure 5), such as terraces of Keriya River [48], pollen, carbonate content, and other proxy indicators from Lake Bosten [53,54,55], plant remains δ13C of aeolian sand sediment section in eastern Tarim Basin [56], shorelines of Lop Nor [57], pollen and δ13C and δ18O of bulk carbonate, and δ13C of organic matter from Lake Ebinur [50,51], biomarkers from Lake Manas [52], and the exchange rate of groundwater in the Badain Jaran Desert [72,73]. Especially, Putnam et al. [57] systematically studied geological evidence from Lop Nur, and proposed that the humid LIA inferred from high lake level start as early as at 1180 AD.
Evidence from the high mountains of Central Asia further shows that the climate had become significantly wetter during the early Sub-Atlantic Period and LIA. The biomarker evidence from Lake Karakul in the Pamir Plateau indicates a humid climate condition during the early Sub-Atlantic Period and LIA (Figure 5) [43], which is supported by the biomarker and geochemical data of Lake Sasikul [42] in the Pamir Plateau especially during the LIA. Hydrogen isotopes of C29 n-alkanes (δDn-C29), a proxy for summer precipitation in Lake Son Kol in western Tianshan Mountains, are significantly negative since 1100 AD, indicating increased summer precipitation during the LIA [38]. Shorelines/beach ridges, historical documents, and archaeological data from Lake Issyk-Kul, also located in western Tianshan Mountains, demonstrated that the lake level between the 11th century BC and the 1st century AD was 12–13 m higher than the modern level discharged into Boom canyon, and it rose again and outflowed in the 13–19th century [40,41]. Multiproxies from Lake Sayram in the Central Tianshan Mountains not only record an increase in precipitation and effective humidity from 850 to 210 BC but also significant wetness at 1060–1670 AD (the early LIA) [15,17,96], which is supported by grain-size data from Lake Harnur in the Central Tianshan Mountains (Figure 5) [22].
Pollen data of lake and peat records in the Altai and Sayan Mountains show the characteristic of increased humidity and rising lake levels in the early Sub-Atlantic Period and LIA (Table 1) [16,25,59,60,62,63,64,65,66,67]. Pollen data from Lake Telmen [68] and Lake Ugii Nuur [70,71] on the Mongolian Plateau indicate the humidity increased in the early Sub-Atlantic Period (Figure 5). In addition, pollen from Lake Khuisiin on the Mongolian Plateau [69] and the net accumulation of the Guliya ice core in the northern Tibetan Plateau [46,47] show effective humidity and precipitation increased significantly during the LIA.
In summary, evidence from various paleorecords including lake deposits, shorelines/beach ridges, peat, ice cores, tree rings, aeolian deposits, moraines, and historical documents in Central Asia indicate that the climate conditions during the early Sub-Atlantic Period (ca. 850–200 BC) and LIA (ca. 1250–1850 AD) were characterized by decreasing temperature and advancing glaciers as well as significant increases in precipitation and humidity.

4.2. Scythian Culture Blooming and Expansion

The Scythian culture, known for its horses’ bridles, weapons, and art types (animal style), was an active nomadic culture that occupied the Eurasian steppe and forest–steppe zones during the first millennium BC, ranging from northern China in the east to the Danube River in the west [25]. Most archaeological sites are located within the range of 42–55° N and 30–100° E (Figure 2) [25,26]. According to archaeological discoveries such as the Arzhan mound of the Russian Tuva Republic, the Zargalant mound in central-western Mongolia, the Besshatyr mound in Kazakhstan, the Chertomlyk mound on the north bank of the Black Sea, and the ancient mounds on the western bank of the Dnieper, the development of Scythian culture is usually subdivided into three phases: the 9–7th century BC pre-Scythian and initial Scythian phases, the 7–6th century BC early Scythian phase, and the 5th–3rd century BC classic Scythian phase [25].
After the middle of the 9th century BC, the population density and cultural development in the Tuva Republic entered a new peak, which had a fundamental influence on the cultural development of the entire Eurasian steppe zone. The early Scythian monument site, the Arzhan-1 tomb, is located in the area of Tuva Republic. 14C and dendrochronology suggest the ages of archaeological sites have been dated to the period between the late 9th and early 8th century BC [25,65]. The culture then expanded to the south and entered the Sayan–Altai–Tianshan Mountains region. Finally, it expanded westward, spanning the entire Central Asia and reaching the northern bank of the Black Sea and the western bank of the Dnieper (the oldest Scythian culture in Europe is the 8th century BC) [25]. From the perspective of migration direction and invasion waves, it is apparent that the nomadic culture in the Eurasian steppe zone predominantly migrated and invaded from north to south and from east to west [26]. Based on the St. Petersburg archaeological 14C database, van Geel et al. [25] summarized and analyzed the frequency distribution of archaeological sites in southern Siberia and Central Asia during the Holocene. Results showed that the number of archaeological sites began to increase at ca. 720 BC (ca. 3000 14C yr BP) (Figure 4 and Figure 5), indicating that the acceleration of cultural development in this region took place shortly after this time [25].
As discussed above, blooming and expansion of Scythian culture (ca. 9th–3rd centuries BC) coincided with the transition from the Sub-Boreal to Sub-Atlantic Period, when the climate in Central Asia has experienced decreasing temperature and glacial advance. The colder climate led to significant changes in nomadic culture and social structure, directly driving migration and expansion of Scythian culture to the south [60]. Simultaneously, a more humid climate with increased precipitation proved conducive to the expansion of nomadic culture. Central Asia is one of the driest regions in the world, and the Gobi Desert blocked nomadic migration. However, after the transition from the Sub-Boreal to Sub-Atlantic Period, the arid Central Asia turned “green” as grasslands moved south, transforming the desert landscape into higher plant-biomass production and thus higher-carrying-capacity grassland landscape [25]. This provided a food source for horses, allowing Scythian culture to migrate westward across the arid-semi-arid Central Asia and finally reach the Danube River in southeastern Europe.
In contrast to these changes, palynological evidence from the Beloe Ozero-3 tomb (Tuva area) during late Scythian culture showed that drying climate caused gradual decline of Scythian culture [65]. Precipitation and humidity proxy records from the Altai and Tianshan Mountains in Central Asia also show a gradual shift toward aridification at ca. 250–200 BC [15,17,59,60,64]. Therefore, in the last stage of the classic Scythian phase, the Scythian culture gradually decline and finally withdraw from the historic stage, resulting from the end of the humid early Sub-Atlantic Period.

4.3. The Rise of the Mongol Empire and Its Expansion

The Mongol Empire (1206–1368 AD) is a general term for the Mongol regime in the 13–14th century AD. It was a vast empire established by nomad across Asia and Europe, with a national territory spanning from the Pacific Ocean in the east to the Danube River and the shores of the Persian Gulf in the west, and from the South China Sea and the Indian Ocean in the south to North Asia in the north (Figure 3). In 1206 AD, Temujin, called Genghis Khan, established the Mongol Empire on the banks of the Onon River. The Mongol Empire continued to expand abroad, against the Tangut kingdom of Hsi Hsia (Xi Xia), the Liao Kingdom, the Tungusic Jin Dynasty and the Khwarezm (Khiva), and then marched through Kazakhstan/Uzbekistan to attack Eastern Europe around the Volga River. In 1241 AD, the victories approached the hinterland of Eastern Europe and conquered Poland and Hungary.
During the Mongol Empire, horse was the primary means of transportation for military conquests. According to Rossabi [97], Mongol Empire cavalry soldiers usually took three or more remounts on campaign, so the number of horses was at least three times that of the cavalry, putting enormous pressure on foraging as an energy source. During the Mongol Empire’s long-ranging military campaigns, horse fodder could not be brought solely from the Mongolian steppe, but instead needed to be foraged locally. The expansion period of the Mongol Empire coincided with wetness in early LIA over the arid Central Asia [15,17,57,96], while the monsoon region in northern China experienced significant aridification [14,98]. It is reasonable to assume that, owing to the southward migration of the Eurasia steppe during this period, the greening of mid-latitude Asian deserts facilitated the Mongolian cavalry crossing Central Asia toward Eastern Europe. On the other hand, with the beginning of the LIA, temperatures in Central Asia decreased, glaciers and snow cover expanded, and winters became more severe and protracted, which forced Mongolian nomad southward migration to the relatively warmer regions. Furthermore, due to the “greening” of Central Asia, oasis agriculture may have been transformed into pastoralism. At the same time, the agricultural empire in northern China experienced a rapid decline in the East Asian summer monsoon, causing severe droughts, famines, peasant uprisings, and a series of other societal problems [14,98]. Therefore, the southward migration and expansion of grassland landscapes contributed to the transformation of the agricultural civilization to the pastoral nomadism in Central Asia, ultimately strengthening their economic and cultural ties to the Mongols [57].

5. Conclusions

We analyzed climate change along the Silk Road during the late Holocene based on 40 records from multiple archives, such as lake sediments, shoreline/beach ridges, peatlands, ice cores, tree rings, aeolian deposits, moraines, and historical documents. We combined this information with archaeological data to establish the climatic influence on the development and expansion of the representative pastoral nomadism, such as the expansion of Scythian culture and rise of the Mongol Empire. The main point of our review paper thus is closely linked to both regional and global concerns of sustainability.
Our results show that the Silk Road experienced a succession of cold–warm and dry–wet cycles during the late Holocene. Among these, the most notable changes were characterized by decreasing temperature, expanding glacier, increasing precipitation, and increasing humidity in Central Asia, occurring over the transition from the Sub-Boreal to Sub-Atlantic Period (ca. 9–8th century BC) and from the MWP to LIA (ca. 13–14th century AD). The temperature declines and glacial advances forced pastoral nomadism southward migration. Meanwhile, the wetness and southward migration of grassland landscape in Central Asia were beneficial for the expansion of Scythian culture and the Mongol Empire, which crossed the entire arid and semi-arid Eurasia. Therefore, climate change is possibly the most key factor for the development and expansion of pastoral nomadism in prehistoric and historical periods.

Author Contributions

P.C. analyzed the data and wrote the paper; J.L. conceived and designed the research and edited the paper; P.C. and J.L. reviewed and edited the paper. All authors have read and agreed to the published version of the manuscript.

Funding

This research was funded by the Strategic Priority Research Program of Chinese Academy of Sciences, grant number XDB40010300; the Natural Science Foundation of China, grant number, 41991253, U20A2078; the National Social Science Foundation of China, grant number, 18ZDA172; and the Youth Innovation Promotion Association of the Chinese Academy of Sciences.

Acknowledgments

This work is a part of the “Belt & Road” Project of Institute of Earth Environment, Chinese Academy of Sciences.

Conflicts of Interest

The authors declare no conflict of interest.

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Figure 1. The spatial distribution of mainly geomorphic units in Central Asia and the mid-latitude Westerlies circulation.
Figure 1. The spatial distribution of mainly geomorphic units in Central Asia and the mid-latitude Westerlies circulation.
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Figure 5. Hydroclimatic variation in Central Asia during the late Holocene. (a) Absolute lake level below global sea level (b.s.l.) of Caspian Sea [28,29,30,94,95], (b) carbonate δ13C of Lake Sayram in Tianshan Mountains [15], (c) carbonate δ13C of Niya Section in the southern Tarim Basin [49], (d) Carbonate δ18O of Lake Bosten [54], (e) biomarker δD of Lake Karakul from Pamir Plateau [43], (f) Xerophytic herb content of Lake Ugii Nuur in Mongolia Plateau [70,71], (g) fine-grain size of Lake Harnur in Tianshan Mountains [22], (h) lake area of Lop Nor [57], and (i) number of 14C dates of late Holocene archaeological sites for southern Siberia and central Asia (dot line), Tuva (cross line), and Khakassia (diamond line) [25]. The gray shadings indicate the Scythian culture blooming and expansion during the early Sub-Atlantic Period and the Mongol Empire during the early LIA.
Figure 5. Hydroclimatic variation in Central Asia during the late Holocene. (a) Absolute lake level below global sea level (b.s.l.) of Caspian Sea [28,29,30,94,95], (b) carbonate δ13C of Lake Sayram in Tianshan Mountains [15], (c) carbonate δ13C of Niya Section in the southern Tarim Basin [49], (d) Carbonate δ18O of Lake Bosten [54], (e) biomarker δD of Lake Karakul from Pamir Plateau [43], (f) Xerophytic herb content of Lake Ugii Nuur in Mongolia Plateau [70,71], (g) fine-grain size of Lake Harnur in Tianshan Mountains [22], (h) lake area of Lop Nor [57], and (i) number of 14C dates of late Holocene archaeological sites for southern Siberia and central Asia (dot line), Tuva (cross line), and Khakassia (diamond line) [25]. The gray shadings indicate the Scythian culture blooming and expansion during the early Sub-Atlantic Period and the Mongol Empire during the early LIA.
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Che, P.; Lan, J. Climate Change along the Silk Road and Its Influence on Scythian Cultural Expansion and Rise of the Mongol Empire. Sustainability 2021, 13, 2530. https://doi.org/10.3390/su13052530

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Che P, Lan J. Climate Change along the Silk Road and Its Influence on Scythian Cultural Expansion and Rise of the Mongol Empire. Sustainability. 2021; 13(5):2530. https://doi.org/10.3390/su13052530

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Che, Ping, and Jianghu Lan. 2021. "Climate Change along the Silk Road and Its Influence on Scythian Cultural Expansion and Rise of the Mongol Empire" Sustainability 13, no. 5: 2530. https://doi.org/10.3390/su13052530

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