Abstract
We have presented results of study of bottom sediments of the proglacial lakes enriched with meltwater of Peretolchin Glacier (the East Sayan Ridge), Chersky Glacier (the Baikalsky Ridge) and glaciers of the Kodar Ridge. Bottom sediments formed from the end of the Little Ice Age to 2013 were investigated with time resolution in year-season, using X-ray fluorescence with synchrotron radiation and inductively coupled plasma mass spectrometry. Depth–age models of the cores were estimated from year laminate layers, using 210Pb and 137Cs chronology. Intense glacier thawing was calculated from the amount of clastic matter supplied by glacier meltwater into proglacial lakes. A high content of some elements was closely associated with clastic material (e.g. Rb, Zr, Nb, Y or Th) in bottom sediments, and most likely these elements affected the intensity of glacier melting. We have defined three periods in significant increase of glacier flow/melting during the last 210 years. The first period (ca. 1800–1890), supply of suspended material by meltwater into Lake Ekhoy (the East Sayan Ridge) and Lake Preobrazhenskoe (the Kodar Ridge), was not intense until 1850 and 1875, respectively. However, the rate of meltwater supply into Lake Izumrudnoe (the Baikalsky Ridge) was high during the Little Ice Age, and it is likely attributed to local moisture from Lake Baikal. The regional glacier water balances were most likely positive during the second period (ca. 1890–1940). The third period (ca. 1940–till present) was characterised by moderate melting rate of glaciers located on the Kodar and Baikalsky Ridges, in contrast to Peretolchin Glacier that demonstrated the highest rate of melting and changes in outlines during this period.
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References
Adamenko MM, Gutak YaM, Solomina ON (2015) Glacial history of the Kuznetsky Alatau mountains. TI Glacier in Asia. Environ Earth Sci: (in last revision)
Aleshin GV (1982) Modern glaciers and their significance for relief formation of the Baikalsky Ridge. Geogr Nature Res 4:133–136 (in Russian)
An Z (2000) The history and variability of the East Asian paleomonsoon climate. Quat Sci Rev 19:171–187
Aref’ev VE, Mukhametov RM (1996) On the glaciers of the Altai and Sayan. Barnaul (In Russian)
Avsiuk GA, Kotlyakov VM (1967) Mountain glaciation in the U.S.S.R.; extension, classification and ice storage in glaciers. In: Hirobumi O (ed) Physics of snow and ice. Hokkaido Univ Inst, Low Temp Sci, Hokkaido, pp 389–394
Back S, Strecker MR (1998) Asymmetric late Pleistocene glaciations in the North Basin of the Baikal Rift, Russia. J Geol Soc 155:61–69
Bakke J, Lie Ø, Nesje A, Dahl SO, Paasche Ø (2005) Utilizing physical sediment variability in glacier-fed lakes for continuous glacier reconstructions during the Holocene, northern Folgefonna, western Norway. The Holocene 15:161–176
Binford MW (1990) Calculation and Uncertainty Analysis of 210Pb Dates for PIRLA project cores. J Paleolimnol 3:253–267
Carrivick JL, Tweed FS (2013) Proglacial lakes: character, behaviour and geological importance. Quat Sci Rev 78:34–52
Dahl SO, Bakke J, Lie O, Nesje A (2003) Reconstruction of former glacier equilibrium-line altitudes based on proglacial sites: an evaluation of approaches and selection of sites. Quat Sci Rev 22:275–287
Davison W (1993) Iron and manganese in lakes. Earth Sci Rev 34:119–163
Dyurgerov MB, Meier MF (2000) Twentieth century climate change: evidence from small glaciers. Natl Acad Sci 97:1406–1411
Galazii GI (1993) Atlas of Baikal. Roskartografia, Moscow (In Russian)
Gaillardet J, Viers J, Dupre B (2003) Treatise on Geochemistry. In: Holland HM, Turekian KK (eds) Elsevier Pergamon, Oxford 5:225–272
Ganyushkin DA, Chistyakov FV, Kunaeva EP (2015) Fluctuation of glaciers in the south-east Russian Altai and north-west Mongolia mountains since the little ice age maximum. TI Glacier in Asia. Environ Earth Sci. doi:10.1007/s12665-015-4301-2
Gardelle J, Arnaud Y, Berthier E (2011) Contrasted evolution of glacial lakes along the Hindu Kush Himalaya mountain range between 1990 and 2009. Glob Planet Chang 75:47–55
Gavshin VM, Melgunov MS, Sukhorukov FV, Bobrov VA, Kalugin IA, Klerkx J (2005) Disequilibrium between uranium and its progeny in the Lake Issyk-Kul system (Kyrgyzstan) under a combined effect of natural and manmade processes. J Environ Radioact 83:61–74
Haeberli W, Frauenfelder R, Kääb A, Wagner S (2004) Characteristics and potential climatic significance of “miniature ice caps” (crest- and cornice-type low-altitude ice archives). J Glaciol 50:129–136
Hoelzle M, Chinn T, Stumm D, Paul F, Zemp M, Haeberli W (2007) The application of glacier inventory data for estimating past climate change effects on mountain glaciers: a comparison between the European Alps and the Southern Alps of New Zealand. Glob Planet Chang 56:69–82
Huang S (2004) Merging information from different resources for new insights into climate change in the past and future. Geophys Res Lett. doi:10.1029/2004GL019781
IPCC (2001) Intergovernmental Panel on Climate Change. Climate Change 2001: The Scientific Basis. Contribution of Working Group II to the Third Assessment Report of the Intergovernmental Panel on Climate Change. Cambridge University Press, Cambridge
IPCC (2007) Intergovernmental Panel on Climate Change. IPCC Fourth Assessment Report: climate change 2007. Synthesis Report (AR4). World Meteorological Organization (WMO) and United, Geneva
Jones PD, Briffa KR, Osborn TJ, Lough JM, van Ommen TD, Vinther BM, Luterbacher J, Wahl E, Zwiers FW, Mann ME, Schmid GA, Ammann CM, Buckley BM, Cobb KM, Esper J, Goosse H, Graham N, Jansen E, Kiefer T, Kull C, Küttel M, Mosley-Thompson E, Overpeck JT, Riedwyl N, Schulz M, Tudhope AW, Villalba R, Wanner H, Wolff E, Xoplaki E (2009) High-resolution palaeoclimatology of the last millennium: a review of current status and future prospects. The Holocene 19:3–49
Juggins S (2012) rioja: Analysis of quaternary science data, R package version (0.8-5). http://cran.r-project.org/package=rioja
Karlen W, Matthews J (1992) Reconstructing Holocene glacier variations from glacier lake sediments: studies from Nordvestlandet and Jostedalsbneen-Jotunheimen, southern Norway. Geog Ann 63A:273–281
Kitov AD, Kovalenko SN, Plusnin VM (2009) Results of the 100-year observations of the dynamics of glacial geosystems of Munch-Sardyk massif. Geogr Natur Res 3:101–108
Kuznetsova LP (1978) Transfer of moisture over the territory of the USSR. Nauka, Moscow (In Russian)
Larsen DJ, Miller GH, Geirsdóttir Á, Thordarson T (2011) A 3000-year varved record of glacier activity and climate change from the proglacial lake Hvítárvatn, Iceland. Quat Sci Rev 30:2715–2731
Li Z, He Y, An W, Song L, Zhang W, Catto N, Wang Y, Wang S, Liu H, Cao W, Theakstone WH, Wang S, Du J (2011) Climate and glacier change in southwestern China during the past several decades. Environ Res Lett 6(045404):24
Lie O, Dahl SO, Nesje A, Matthews JA, Sandvold S (2004) Holocene fluctuations of a polythermal glacier in high-alpine eastern Jotunheimen, central-southern Norway. Quat Sci Rev 23:1925–1945
Liu C, Han T (1992) Relation between recent glacier variations and climate in the Tien Shan mountains, central Asia. Ann Glaciol 16:11–16
Liu XD, Cheng ZG, Yan LB, Yin ZY (2009) Elevation dependency of recent and future minimum surface air temperature trends in the Tibetan Plateau and its surroundings. Glob Planet Chang 68(3):164–174
Machguth H, Haeberli W, Paul F (2012) Mass-balance parameters derived from a synthetic network of mass-balance glaciers. J Glaciol 58(211):965–979
Margold M, Jansson KN (2011) Glacial geomorphology and glacial lakes of central Transbaikalia, Siberia, Russia. J Maps 7:18–30
Melgunov MS, Gavshin VM, Sukhorukov FV, Kalugin IA, Bobrov VA, Klerkx J (2003) Anomalies of radioactivity on the southern bank of the Ysyk-Köl Lake (Kyrgyzstan). Chem Sustain Dev 11:859–870 (In Russian)
Moberg A, Sonechkin DM, Holmgren K, Datsenko NM, Karlen W (2005) Highly variable Northern Hemisphere temperatures reconstructed from low and high-resolution proxy data. Nature 433:613–617
Ndiaye M, Davaud E, Ariztegui D, Fall M (2012) Int J Geosci 3:206
Nesbitt HW (1979) Mobility and fractionation of rare earth elements during weathering of a granodiorite. Nature 279:206–210
Nesje A, Dahl SO (2001) The Greenland 8200 cal. year BP event detected in loss-on-ignition profiles in Norwegian lacustrine sediment sequences. J Quat Sci 16:155–166
Nesje A, Bakke J, Dahl SO, Lie O, Matthews JA (2008) Norwegian mountain glaciers in the past, present and future. Glob Planet Chang 60:1–27
Nie Y, Zhang Y, Ding M, Liu L, Wang Z (2013) Lake change and its implication in the vicinity of Mt. Qomolangma (Everest), central high Himalayas, 1970–2009. Environ Earth Sci 68:251–265
Osborn TJ, Briffa KR (2006) The spatial extent of 20th century warmth in the context of the past 1200 years. Science 311:841–844
Osipov EY, Khlystov OM (2010) Glaciers and meltwater flux to Lake Baikal during the Last Glacial Maximum. Palaeogeog Palaeoclim Palaeoecol 294:4–15
Osipov EY, Osipova OP (2014) Mountain glaciers of southeast Siberia: current state and changes since the Little Ice Age. Ann Glaciol 55(66):167–176
Osipov EY, Osipova OP (2015) Glaciers of the Levaya Sygykta River watershed, Kodar Ridge, southeastern Siberia, Russia: modern morphology, climate conditions and changes over the past decades. TI Glacier in Asia. Environ Earth Sci. doi:10.1007/s12665-015-4352-4
Osipov EY, Grachev MA, Mats VD, Khlystov OM, Breitenbach S (2003) Mountain glaciers of the Pleistocene Last Glacial Maximum in the northwestern Barguzin Range (Northern Baikal Region): paleoglacial reconstruction. Russ Geol Geophys 44:652–663
Osipov EY, Ashmetev AY, Osipova OP, Klevtsov (2013) New glacier inventory of the south-east part of Eastern Sayan. Ice Snow 3:123 (In Russian)
Owen LA, Thackray G, Anderson RS, Briner J, Kaufman D, Roe G, Yi C (2009) Integrated research on mountain glaciers: current status, priorities and future prospects. Geomorphology 103(2):158–171
Paul F (2002) Changes in glacier area in Tyrol, Austria, between 1969 and 1992 derived from Landsat 5 Thematic Mapper and Austrian Glacier Inventory data. Remote Sens 23:787–799
Paul F, Haeberli W (2008) Spatial variability of glacier elevation changes in the Swiss Alps obtained from two digital elevation models. Geophys Res Lett 35:L21502. doi:10.1029/2008GL034718
Peretolchin SP (1908) Glaciers of the Munku-Sardyk ridge. Izvestiia Tomsk Technol Inst 9(1):47
Phedorin MA, Goldberg EL (2005) Prediction of absolute concentrations of elements from SR XRF scan measurements of natural wet sediments. Nucl Instrum Methods Phys Res A 543:274–279
Phedorin MA, Bobrov VA, Goldberg EL, Navez J, Zolotaryov KV, Grachev MA (2000a) SR-XFA as a method of choice in the search of signals of changing palaeoclimates in the sediments of Lake Baikal, compared to INAA and ICP-MS. Nucl Instrum Methods Phys Res A 448:394–399
Phedorin MA, Goldberg EL, Grachev MA, Levina OL, Khlystov OM, Dolbnya IP (2000b) The comparison of biogenic silica, Br and Nd distributions in the sediments of Lake Baikal as proxies of changing paleoclimates of the last 480 ky. Nucl Instrum Methods Phys Res A 448:400–406
Phedorin MA, Fedotov AP, Vorobieva SS, Ziborova GA (2008) Signature of long supercycles in the Pleistocene history of Asian limnic systems. J Paleolimnol 40:445–452
Plyusnin VM, Drozdova OV, Kitov AD, Kovalenko SN (2008) The dynamics of mountain geosystems in southern Siberia. Geogr Nat Res 2:5–14
Pokrovsky OS, Schott J, Dupre B (2006) Trace element fractionation and transport in boreal rivers and soil porewaters of permafrost-dominated basaltic terrain in Central Siberia. Geochim Cosmochim Acta 70:3239–3260
Preobrazhenskiy VS (1960) Kodar Glacial Area (Transbaikalia). IX section of the International Geophysical Year Program (Glaciology). Published by the Academy of Sciences of the USSR, Moscow (In Russian)
Rayner NA, Parker DE, Horton EB, Folland CK, Alexander LV, Rowell DP, Kent EC, Kaplan A (2003) Global analyses of SST, sea ice and night marine air temperature since the late nineteenth century. J Geophys Res 108(D14):4407. doi:10.1029/2002JD002670
Rosqvist G, Jonsson C, Yam R, Karlen W, Shemesh A (2004) Diatom oxygen isotopes in pro-glacial lake sediments from northern Sweden: a 5000 year record of atmospheric circulation. Quat Sci Rev 23:851–859
Shahgedanova M, Popovnin V, Aleynikov A, Stokes CR (2011) Geodetic mass balance of Azarova glacier, Kodar Mountains, eastern Siberia, and its links to observed and projected climatic change. Ann Glaciol 52:129–137
Shijin W, Tao Z (2014) Spatial change detection of glacial lakes in the Koshi River Basin, the Central Himalayas. Environ Earth Sci 72:4381–4391
Sochava VB (1967) Atlas of Transbaikalia. GUGK, M-Irkutsk (In Russian)
Solomina ON (2000) Retreat of mountain glaciers of northern Eurasia since the Little Ice Age maximum. Ann Glaciol 31:26–30
Solomina O, Haeberli W, Kull C, Wiles G (2008) Historical and Holocene glacier–climate variations: general concepts and overview. Glob Planet Chang 60:1–9
Song C, Huang B, Ke L, Richards KS (2014) Remote sensing of alpine lake water environment changes on the Tibetan Plateau and surroundings: A review. ISPRS J Photogramm Remote Sens 92:26–37
Steinhilber F, Beer J, Fröhlich C (2009) Total solar irradiance during the Holocene. Geophys Res Lett. doi:10.1029/2009GL040142
Stoetter J, Wastl M, Caseldine C, Haberle T (1999) Holocene palaeoclimatic reconstruction in northern Iceland: approaches and results. Quat Sci Rev 18:457–474
Stokes CR, Shahgedanova M, Evans IS, Popovnin VV (2013) Accelerated loss of alpine glaciers in the Kodar Mountains, south-eastern Siberia. Glob Planet Chang 101:82–96
Trounova VA, Zolotarev KV, Baryshev VB, Phedorin MA (1998) Analytical possibilities of SRXRF station at VEPP-3 SR-source. Nucl Instrum Methods Phys Res A 405:532–536
Vorobyeva SS, Trunova VA, Stepanova OG, Zvereva VV, Petrovskii SK, Melgunov MS, Zheleznyakova TO, Chechetkina LG, Fedotov AP (2015) Impact of glacier changes on ecosystem of proglacial lakes in high mountain regions of East Siberia (Russia). TI Glacier in Asia. Environ Earth Sci. doi:10.1007/s12665-015-4164-6
Wang N, Wu H, Wu Yu, Chen A (2015) Variations of the glacier mass balance and lake water storage in the Tarim Basin, northwest China, over the period of 2003–2009 estimated by the ICESat-GLAS data. Environ Earth Sci. doi:(in last revision)
WGMS (2011) Glacier Mass Balance Bulletin No. 11 (2008–2009). In: Zemp M, Nussbaumer SU, Gärtner-Roer I, Hoelzle M, Paul F, Haeberli W (eds) ICSU(WDS)/IUGG(IACS)/UNEP/UNESCO/WMO. World Glacier Monitoring Service, Zurich, p 102
Wilson R, D’Arrigo R, Buckley B, Büntgen U, Esper J, Frank D, Luckman B, Payette S, Vose R, Youngblut D (2007) A matter of divergence: tracking recent warming at hemispheric scales using tree ring data. J Geophys Res 112:D17103. doi:10.1029/2006JD008318
Xoplaki E, Luterbacher J, Paeth H, Dietrich D, Steiner N, Grosjean M, Wanner H (2005) European spring and autumn temperature variability and change of extremes over the last half millennium. Geophys Res Lett. doi:10.1029/2005GL023424
Ya Li, Yi Li (2014) Topographic and geometric controls on glacier changes in the central Tien Shan, China, since the Little Ice Age. Ann Glaciol 55(66):177–186
Yang B, Bräuning A, Dong Z, Zhang Z, Keqing J (2008) Late Holocene monsoonal temperate glacier fluctuations on the Tibetan Plateau. Glob Planet Chang 60:126–140
Zaloznaya VI, Postnikova NG (1966) Climate Handbook USSR. Gidrometeoizdat, Leningrad (In Russian)
Zhao QD, Ye BS, Ding YJ, Zhang SQ, Yi SH, Wang J, Shangguan DH, Zhao CC, Han HD (2013) Coupling a glacier melt model to the Variable Infiltration Capacity (VIC) model for hydrological modeling in north-western China. Environ Earth Sci 68:87–101
Zhuchenko NA, Chebykin EP, Stepanova OG, Chebykin AP, Gol’dberg EL (2008) Microwave digestion of bottom sediments from Lake Baikal for the inductively coupled plasma mass-spectrometric determination of their elemental composition. J Anal Chem 63:943–949
Zolotarev KV, Goldberg EL, Kondratyev VI, Kulipanov GN, Miginsky EG, Tsukanov VM, Phedorin MA, Kolmogorov YP (2001) Scanning SR-XRF beamline for analysis of bottom sediments. Nucl Instrum Methods Phys Res A 470:376–379
Acknowledgments
This study was supported by FANO Program VIII.76.1.6, RFBR-13-05-00022, RFBR-15-05-04525. We are grateful to Osipov E.Yu, Enishenko I.V., Vershinin K.E. and Fedotov A.A., who took part in the coring campaign in Lakes Ekhoy, Preobrazhenskoe and Izumrudnoe.
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Stepanova, O.G., Trunova, V.A., Zvereva, V.V. et al. Reconstruction of glacier fluctuations in the East Sayan, Baikalsky and Kodar Ridges (East Siberia, Russia) during the last 210 years based on high-resolution geochemical proxies from proglacial lake bottom sediments. Environ Earth Sci 74, 2029–2040 (2015). https://doi.org/10.1007/s12665-015-4457-9
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DOI: https://doi.org/10.1007/s12665-015-4457-9