Abstract
Knowledge of historical changes in moisture within semi-arid and arid regions is the basis of climatic change predictions and strategies in response to long-term drought. In this study, a multiproxy peat record with high-resolution from Sichanghu in the northern Tianshan was used to document the changes in vegetation and climate over the past 450 years in the arid Central Asia. The pollen, grain size, and loss on ignition (LOI) records indicate that the productivity of local peat began to increase at ∼1730 AD. The vegetation in the Sichanghu area experienced several transitions, from temperate desert to dense desert, marsh meadow, and steppe desert vegetation. The climate in the study area was extremely dry during the early stages of the Little Ice Age (LIA) (before 1730 AD) and relatively wet during the late stages (1730–1880 AD). The inferred changes in the moisture conditions of the Sichanghu peatland since the LIA may have been controlled by the extent of Arctic sea ice, the North Atlantic Oscillation, and the Siberian High via the connections of large-scale atmospheric circulations such as the Westerlies.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Aizen V B, Aizen E M, Joswiak D R, Fujita K, Takeuchi N, Nikitin S A (2006). Climatic and atmospheric circulation pattern variability from ice-core isotope/geochemistry records (Altai, Tien Shan and Tibet). Ann Glaciol, 43(1): 49–60
An C B, Lu Y B, Zhao J J, Tao S C, Dong W M, Li H, Jin M, Wang Z L (2012). A high-resolution record of Holocene environmental and climatic changes from Lake Balikun (Xinjiang, China): implications for Central Asia. Holocene, 22(1): 43–52
Beni A N, Lahijani H, Harami R M, Arpe K, Leroy S A G, Marriner N, Berberian M, Andrieu-Ponel V, Djamali M, Mahboubi A, Reimer P J (2013). Caspian Sea level changes during the last millennium: historical and geological evidence from the south Caspian Sea. Clim Past, 9(4): 1645–1665
Blaauw M, Christen J A (2011). Flexible paleoclimate age-depth models using an autoregressive gamma process. Bayesian Anal, 6(3): 457–474
Buckley B M, Anchukaitis K J, Penny D, Fletcher R, Cook E R, Sano M, Nam C, Wichienkeeo A, Minh T T, Hong T M (2010). Climate as a contributing factor in the demise of Angkor, Cambodia. Proc Natl Acad Sci USA, 107(15): 6748–6752
Cao X Y, Herzschuh U, Ni J, Zhao Y, Bohmer T (2015). Spatial and temporal distributions of major tree taxa in eastern continental Asia during the last 22,000 years. Holocene, 25(1): 79–91
Chen F H, Chen J H, Holmes J, Boomer I, Austin P, Gates J B, Wang N L, Brooks S J, Zhang J W (2010a). Moisture changes over the last millennium in arid Central Asia: a review, synthesis and comparison with monsoon region. Quat Sci Rev, 29(7–8): 1055–1068
Chen F H, Huang X Z, Zhang J W, Holmes J A, Chen J H (2006). Humid Little Ice Age in Central Asia documented by Bosten Lake, Xinjiang, China. Sci China Earth Sci, 49(12): 1280–1290
Chen F, Yuan Y J, Wei W S, Yu S L, Zhang T W, Shang H M, Zhang R B, Qin L, Fan Z A (2015a). Tree-ring recorded hydroclimatic change in Tianshan mountains during the past 500 years. Quat Int, 358: 35–41
Chen F, Yu Z, Yang M, Ito E, Wang S, Madsen D B, Huang X, Zhao Y, Sato T, John B. Birks H, Boomer I, Chen J, An C, Wünnemann B (2008). Holocene moisture evolution in arid Central Asia and its out-of-phase relationship with Asian monsoon history. Quat Sci Rev, 27(3): 351–364
Chen F H, Chen J H, Huang W, Chen S Q, Huang X Z, Jin L Y, Jia J, Zhang X J, An C B, Zhang J W, Zhao Y, Yu Z C, Zhang R H, Liu J B, Zhou A F, Feng S (2019). Westerlies Asia and monsoonal Asia: spatiotemporal differences in climate change and possible mechanisms on decadal to sub-orbital timescales. Earth Sci Rev, 192: 337–354
Chen J H, Chen F H, Feng S, Huang W, Liu J B, Zhou A F (2015b). Hydroclimatic changes in China and surroundings during the Medieval Climate Anomaly and Little Ice Age: spatial patterns and possible mechanisms. Quat Sci Rev, 107: 98–111
Chen J H, Chen F H, Zhang E L, Brooks S J, Zhou A F, Zhang J W (2009). A 1000-year chironomid-based salinity reconstruction from varved sediments of Sugan Lake, Qaidam Basin, arid Northwest China, and its palaeoclimatic significance. Chin Sci Bull, 54(20): 3749–3759
Chen Y, Ni J, Herzschuh U (2010b). Quantifying modern biomes based on surface pollen data in China. Global Planet Change, 74(3–4): 114–131
Chiba T, Endo K, Sugai T, Haraguchi T, Kondo R, Kubota J (2016). Reconstruction of Lake Balkhash levels and precipitation/evaporation changes during the last 2000 years from fossil diatom assemblages. Quat Int, 397: 330–341
Cohen J, Screen J A, Furtado J C, Barlow M, Whittleston D, Coumou D, Francis J, Dethloff K, Entekhabi D, Overland J, Jones J (2014). Recent Arctic amplification and extreme mid-latitude weather. Nat Geosci, 7(9): 627–637
Cook E R, D’Arrigo R D, Mann M E (2002). A well-verified, multiproxy reconstruction of the winter North Atlantic Oscillation Index since A. D. 1400. J Clim, 15(13): 1754–1764
Davi N K, D’Arrigo R, Jacoby G C, Cook E R, Anchukaitis K J, Nachin B, Rao M P, Leland C (2015). A long-term context (931–2005 CE) for rapid warming over Central Asia. Quat Sci Rev, 121: 89–97
Dean W E (1974). Determination of carbonate and organic-matter in calcareous sediments and sedimentary-rocks by loss on ignition: comparison with other methods. J Sediment Petrol, 44(1): 242–248
Eichler A, Tinner W, Brütsch S, Olivier S, Papina T, Schwikowski M (2011). An ice-core based history of Siberian forest fires since AD 1250. Quat Sci Rev, 30(9–10): 1027–1034
Fægri K, Iversen J (1989). Textbook of Pollen Analysis. London: John Wiley and Sons
Ferronskii V I, Polyakov V A, Brezgunov V S, Vlasova L S, Karpychev Y A, Bobkov A F, Romaniovskii V V, Johnson T, Ricketts D, Rasmussen K (2003). Variations in the hydrological regime of Kara-Bogaz-Gol Gulf, Lake Issyk-Kul, and the Aral Sea assessed based on data of bottom sediment studies. Water Resour, 30(3): 252–259
Grimm E C (1987). CONISS: A Fortran 77 program for stratigraphically constrained cluster analysis by the method of incremental sum of squares. Comput Geosci, 13(1): 13–35
Guiot J, Goeury C (1996). PPPbase, a software for statistical analysis of paleoecological and paleoclimatological data. Dendrochronologia, 14: 295–300
Heiri O, Lotter A F, Lemcke G (2001). Loss on ignition as a method for estimating organic and carbonate content in sediments: reproducibility and comparability of results. J Paleolimnol, 25(1): 101–110
Herzschuh U (2007). Reliability of pollen ratios for environmental reconstructions on the Tibetan Plateau. J Biogeogr, 34(7): 1265–1273
Hong B, Gasse F, Uchida M, Hong Y, Leng X, Shibata Y, An N, Zhu Y, Wang Y (2015). Increasing summer rainfall in arid eastern-Central Asia over the past 8500 years. Sci Rep, 4(1): 5279
Huang W, Feng S, Chen J H, Chen F H (2015a). Physical mechanisms of summer precipitation variations in the Tarim Basin in northwestern China. J Clim, 28(9): 3579–3591
Huang X Z, Chen C Z, Jia W N, An C B, Zhou A F, Zhang J W, Jin M, Xia D S, Chen F H, Grimm E C (2015b). Vegetation and climate history reconstructed from an alpine lake in central Tianshan Mountains since 8.5 ka BP. Palaeogeogr Palaeoclimatol Palaeoecol, 432: 36–48
Hurrell J W (1995). Decadal trends in the North Atlantic oscillation: regional temperatures and precipitation. Science, 269(5224): 676–679
Lean J (2000). Evolution of the Sun’s spectral irradiance since the Maunder Minimum. Geophys Res Lett, 27(16): 2425–2428
Li G Q, Chen F H, Xia D S, Yang H, Zhang X J, Madsen D, Oldknow C, Wei H T, Rao Z G, Qiang M R (2018). A Tianshan Mountains loesspaleosol sequence indicates anti-phase climatic variations in arid Central Asia and in East Asia. Earth Planet Sci Lett, 494: 153–163
Li Y C (2012). Pollen-vegetation-climate relationship in some desert and steppe communities in Northern China. In: Schluchter C, Nietlispach J, XVIII INQUA Congress Abstracts, Quat Int, 279–280
Liu W G, Liu Z H, An Z S, Wang X L, Chang H (2011). Wet climate during the ‘Little Ice Age’ in the arid Tarim Basin, northwestern China. Holocene, 21(3): 409–416
Luo C X, Zheng Z, Tarasov P, Pan A D, Huang K Y, Beaudouin C, An F Z (2009). Characteristics of the modern pollen distribution and their relationship to vegetation in the Xinjiang region, northwestern China. Rev Palaeobot Palynol, 153(3–4): 282–295
Ma Q F, Zhu L P, Wang J B, Ju J T, Lü X M, Wang Y, Guo Y, Yang R M, Kasper T, Haberzettl T, Tang L Y (2017). Artemma/Chenopodiaceae ratio from surface lake sediments on the central and western Tibetan Plateau and its application. Palaeogeogr Palaeoclimatol Palaeoecol, 479: 138–145
Mann M E, Zhang Z, Rutherford S, Bradley R S, Hughes M K, Shindell D, Ammann C, Faluvegi G, Ni F (2009). Global signatures and dynamical origins of the Little Ice Age and Medieval Climate Anomaly. Science, 326(5957): 1256–1260
Meeker L D, Mayewski P A (2002). A 1400-year high-resolution record of atmospheric circulation over the North Atlantic and Asia. Holocene, 12(3): 257–266
PAGES 2k Consortium (2013). Continental-scale temperature variability during the past two millennia. Nat Geosci, 6: 339–346 doi:https://doi.org/10.1038/ngeo1797
Paulsen D E, Li H C, Ku T L (2003). Climate variability in central China over the last 1270 years revealed by high-resolution stalagmite records. Quat Sci Rev, 22(5–7): 691–701
Prentice I C, Guiot J, Huntley B, Jolly D, Cheddadi R (1996). Reconstructing biomes from palaeoecological data: a general method and its application to European pollen data at 0 and 6 ka. Clim Dyn, 12(3): 185–194
Qin J G, Taylor D, Atahan P, Zhang X R, Wu G X, Dodson J, Zheng H B, Itzstein-Davey F (2011). Neolithic agriculture, freshwater resources and rapid environmental changes on the lower Yangtze, China. Quat Res, 75(1): 55–65
Rao Z G, Wu D D, Shi F X, Guo H C, Cao J T, Chen F H (2019). Reconciling the ‘westerlies’ and ‘monsoon’ models: a new hypothesis for the Holocene moisture evolution of the Xinjiang region, NW China. Earth Sci Rev, 191: 263–272
Raible C C, Yoshimori M, Stocker T F, Casty C (2007). Extreme midlatitude cyclones and their implications for precipitation and wind speed extremes in simulations of the Maunder Minimum versus present day conditions. Clim Dyn, 28(4): 409–423
R Code Team (2012). R: A Language and Environment for Statistical Computing. Vienna: R Foundation for Statistical Computing
Reimer P J, Bard E, Bayliss A, Beck J W, Blackwell P G, Ramsey C B, Buck C E, Cheng H, Edwards R L, Friedrich M, Grootes P M, Guilderson T P, Haflidason H, Hajdas I, Hatté C, Heaton T J, Hoffmann D L, Hogg A G, Hughen K A, Kaiser K F, Kromer B, Manning S W, Niu M, Reimer R W, Richards D A, Scott E M, Southon J R, Staff R A, Turney C S M, van der Plicht J (2013). Intcal13 and marine13 radiocarbon age calibration curves 0–50000 years Cal BP. Radiocarbon, 55(4): 1869–1887
Shi Y F, Shen Y P, Kang E, Li D L, Ding Y J, Zhang G W, Hu R J (2006). Recent and future climate change in Northwest China. Clim Change, 80(3–4): 379–393
Song M, Zhou A F, Zhang X N, Zhao C, He Y X, Yang W Q, Liu W G, Li S H, Liu Z H (2015). Solar imprints on Asian inland moisture fluctuations over the last millennium. Holocene, 25(12): 1935–1943
Ter Braak C J F, Šmilauer P (2002). CANOCO Reference Manual and CanoDraw for Windows User’s Guide: Software for Canonical Community Ordination (Version 4.5). Ithaca, NY: Microcomputer Power
Tian F, Herzschuh U, Dallmeyer A, Xu Q H, Mischke S, Biskaborn B K (2013). Environmental variability in the monsoon-westerlies transition zone during the last 1200 years: lake sediment analyses from central Mongolia and supra-regional synthesis. Quat Sci Rev, 73: 31–47
Trouet V, Esper J, Graham N E, Baker A, Scourse J D, Frank D C (2009). Persistent positive North Atlantic oscillation mode dominated the Medieval Climate Anomaly. Science, 324(5923): 78–80
Wang F X (1995). Pollen Morphology in China. Beijing: Science Press (in Chinese)
Wang N L, Jiang X, Thompson L G, Davis M E (2007). Accumulation rates over the past 500 years recorded in ice cores from the northern and southern Tibetan Plateau, China. Arct Antarct Alp Res, 39(4): 671–677
Wang S W, Ye J L, Gong D Y (1998). Climate in China during the Little Ice Age. Quat Sci, 18(1): 54–64 (in Chinese)
Wei H C, Zhao Y (2016). Surface pollen and its relationships with modern vegetation and climate in the Tianshan Mountains, northwestern China. Veg Hist Archaeobot, 25(1): 19–27
Wu B Y, Su J Z, Zhang R H (2011). Effects of autumn-winter Arctic sea ice on winter Siberian High. Chin Sci Bull, 56(30): 3220–3228
Wu J L, Liu J J, Wang S M (2004). Climatic change record from stable isotopes in Lake Aibi, Xinjiang during the past 1500 years. Quat Sci, 24(5): 585–590 (in Chinese)
Yan S, Kong Z C, Yang Z J (2003). Pollen analysis and its significance of the Sichanghu section in Jimusaer county, Xijiang. Acta Bot Bor-Occid Sin, 23(4): 531–536 (in Chinese)
Yang B, Braeuning A, Johnson K R, Shi Y F (2002). General characteristics of temperature variation in China during the last two millennia. Geophys Res Lett, 29(9): 1–4
Yang M X, Yao T D, Wang H J (2006). Microparticle content records of the Dunde ice core and dust storms in northwestern China. J Asian Earth Sci, 27(2): 223–229
Yang Z J, Zhang Y, Ren H B, Yan S, Kong Z C, Ma K P, Ni J (2016). Altitudinal changes of surface pollen and vegetation on the north slope of the Middle Tianshan Mountains, China. J Arid Land, 8(5): 799–810
Yao T D, Jiao K Q, Tian L D, Yang Z H, Shi W L, Thompson L G (1996a). Climatic variations since the Little Ice Age recorded in the Guliya ice core. Sci China Ser D Earth Sci, 39(6): 587–596
Yao T D, Thompson L G, Qin D H, Tian L D, Jiao K Q, Yang Z H, Xie C (1996b). Variations in temperature and precipitation in the past 2000 a on the Xizang (Tibet) Plateau-Guliya ice core record. Sci China Ser D Earth Sci, 39(4): 425–433
Zhang H, Zhang Y, Kong Z C, Yang Z J, Li Y M, Tarasov P E (2015). Late Holocene climate change and anthropogenic activities in north Xinjiang: evidence from a peatland archive, the Caotanhu Wetland. Holocene, 25(2): 323–332
Zhang Q, Xiao C D, Ding M H, Dou T F (2018). Reconstruction of autumn sea ice extent changes since 1289AD in the Barents-Kara Sea, Arctic. Sci China Earth Sci, 61(9): 1279–1291
Zhang Y, Kong Z C, Yan S, Yang Z J, Ni J (2004). “Medieval Warm Period” in Xinjiang—rediscussion on paleoenvironment of the Sichanghu profile in Gurbantunggut Desert. Quat Sci, 24(6): 701–708 (in Chinese)
Zhang Y, Kong Z C, Yan S, Yang Z J, Ni J (2009). “Medieval Warm Period” on the northern slope of central Tianshan Mountains, Xinjiang, NW China. Geophys Res Lett, 36(11): L11702
Zhang Y, Meyers P A, Liu X T, Wang G P, Ma X H, Li X Y, Yuan Y X, Wen B (2016). Holocene climate changes in the Central Asia mountain region inferred from a peat sequence from the Altai Mountains, Xinjiang, northwestern China. Quat Sci Rev, 152: 19–30
Zhao Y, Li F R, Hou Y T, Sun J H, Zhao W W, Tang Y, Li H (2012a). Surface pollen and its relationships with modern vegetation and climate on the Loess Plateau and surrounding deserts in China. Rev Palaeobot Palynol, 181: 47–53
Zhao Y, Liu H Y, Li F R, Huang X Z, Sun J H, Zhao W W, Herzschuh U, Tang Y (2012b). Application and limitations of the Artemisia/Chenopodiaceae pollen ratio in arid and semi-arid China. Holocene, 22(12): 1385–1392
Zhao Y, Yu Z C, Liu X J, Zhao C, Chen F H, Zhang K (2010). Late Holocene vegetation and climate oscillations in the Qaidam Basin of the northeastern Tibetan Plateau. Quat Res, 73(1): 59–69
Zhao Y, Yu Z C, Tang Y, Li H, Yang B, Li F R, Zhao W W, Sun J H, Chen J H, Li Q, Zhou A F (2014). Peatland initiation and carbon accumulation in China over the last 50,000 years. Earth Sci Rev, 128: 139–146
Zhao Y, Yu Z, Zhao W W (2011). Holocene vegetation and climate histories in the eastern Tibetan Plateau: controls by insolation-driven temperature or monsoon-derived precipitation changes? Quat Sci Rev, 30(9–10): 1173–1184
Acknowledgements
This work was supported by the National Natural Science Foundation of China (Grant Nos. 41690113, 41977395, 41671202 and 41471169), the Strategic Priority Research Program of the Chinese Academy of Sciences (No. XDA20070101), and the National Key Research and Development Program of China (Grant No. 2016YFA0600501). We wish to thank the anonymous reviewers, and Qiaoyu Cui, Feng Qin and Jie Xu for valuable suggestions.
Author information
Authors and Affiliations
Corresponding author
Rights and permissions
About this article
Cite this article
Ren, W., Zhao, Y., Li, Q. et al. Changes in vegetation and moisture in the northern Tianshan of China over the past 450 years. Front. Earth Sci. 14, 479–491 (2020). https://doi.org/10.1007/s11707-019-0788-2
Received:
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.1007/s11707-019-0788-2