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Correlation of Alaskan varve Thickness with Climatic Parameters, and use in Paleoclimatic Reconstruction

Published online by Cambridge University Press:  20 January 2017

James A. Perkins
Affiliation:
U.S. Geological Survey, 345 Middlefield Road, Menlo Park, California 94025 USA
John D. Sims
Affiliation:
U.S. Geological Survey, 345 Middlefield Road, Menlo Park, California 94025 USA

Abstract

The thickness of varves in the sediments of Skilak Lake, Alaska, are correlated with the mean annual temperature (r = 0.574), inversely correlated with the mean annual cumulative snowfall (r = −0.794), and not correlated with the mean annual precipitation (r = 0.202) of the southern Alaska climatological division for the years 1907–1934 A.D. Varve thickness in Skilak Lake is sensitive to annual temperature and snowfall because Skilak Glacier, the dominant source of sediment for Skilak Lake, is sensitive to these climatic parameters. Trends of varve thickness are well correlated with trends of mean annual cumulative snowfall ( = −0.902) of the southern Alaska climatological division and with trends of mean annual temperature of the southern ( = 0.831) and northern ( = 0.786) Alaska climatological divisions. Trends of varve thickness also correlate with trends of annual temperature in Seattle and North Head, Washington ( = 0.632 and 0.850, respectively). Comparisons of trends of varve thickness with trends of annual temperature in California, Oregon, and Washington suggest no widespread regional correlation. Trends of annual snowfall in the southern Alaska climatological division and trends of annual temperature in the southern and northern Alaska climatological divisions are reconstructed for the years 1700–1906 A.D. Climatic reconstructions on the basis of varve thickness in Skilak Lake utilize equations derived from the regression of series of smoothed climatological data on series of smoothed varve thickness. Reconstruction of trends of mean annual cunulative snowfall in the southern Alaska climatological division suggests that snowfall during the 1700s and 1800s was much greater than that during the early and mid-1900s. The periods 1770–1790 and 1890–1906 show marked decreases in the mean annual snowfall. Reconstructed trends of the annual temperature of the northern and southern Alaska climatological divisions suggest that annual temperatures during the 1700s and 1800s were lower than those of the early and mid-1900s. Two periods of relatively high annual temperatures coincide with the periods of low annual snowfall thus determined.

Type
Original Articles
Copyright
University of Washington

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References

Agterberg, F.P. Banerjee, I. 1969 Stochastic model for the deposition of varves in glacial lake Barlow-Ojibway, Ontario, Canada Canadian Journal of Earth Sciences 6 625652 Google Scholar
Ashley, G.M. 1975 Rhythmic sedimentation in glacial lake Hitchcock, Massachusetts-Connecticut Jopling, A.V. McDonald, B.C. Glaciofluvial and Glaciolacustrine Sedimentation Society of Economic Paleontologists and Mineralogists 302320Special PublicationGoogle Scholar
Bouma, A.H. 1962 Sedimentology of Some Flysch Deposits. A Graphic Approach to Facies Interpretation Elsevier New York Google Scholar
Coats, R.R. 1950 Volcanic activity in the Aleutian Arc. United States Geological Survey Bulletin 974-B Google Scholar
De Geer, G. 1912 A geochronology of the last 12,000 years Procceedings of International Geological Conference, XI Stockholm, 1910 Vol. 1 241253Comptes RendueGoogle Scholar
Dorrer, E. Wendler, G. 1976 Climatic and photogrammetric speculations on mass-balance changes of McCall Glacier, Brooks Range, Alaska Journal of Glaciology 17 479490 CrossRefGoogle Scholar
Gilbert, R. 1973 Processes of underflow and sediment transport British Columbia mountain lake Fluvial Processes and Sedimentation. Proceedings of Hydrology Symposium Held at University of AlbertaEdmonton, May 8 and 9, 1973493507 Google Scholar
Granar, L. 1956 Dating of recent fluvial sediments from the estuary of the Angerman River Geologiska Foreningens i Stockholm Forhandlingar 78 654658 Google Scholar
Gustavson, T.C. 1975 Sedimentation and physical limnology in proglacial malaspina Lake, southeastern Alaska Jopling, A.V. McDonald, B.C. Glaciofluvial and Glaciolacustrine Sedimentation Society of Economic Paleontologists and Mineralogists 249263Special PublicationCrossRefGoogle Scholar
Jacobs, J.D. Leung, C.Y.Y. 1981 Paleoclimatic implications of topoclimatic diversity in Arctic Canada Mahaney, W.C. Quaternary Paleoclimate Geo Abstracts Norwich, U.K 6376 Google Scholar
Johnston, J. 1972 Econometric Methods McGraw-Hill New York Google Scholar
Karlstrom, T.N.V. 1964 Quaternary Geology of the Kenai Lowlands and Glacial History of the Cook Inlet Region, Alaska United States Geological Survey Professional Paper 443 Google Scholar
Kuenen, Ph.H. 1951 Mechanics of varve formation and the action of turbidity currents Geologiska Foreningens i Stockholm Forhandlingar 73 6984 CrossRefGoogle Scholar
Mitchell, J.M. Jr. Dzerdzeevskii, B. Flohn, H. Hodmeyr, W.L. Lamb, H.H. Rao, K.N. Wallen, C.C. 1966 Climatic Change World Meteorological Organization GenevaTechnical Note 79Google Scholar
Ostrem, G. 1977 Glaciological investigations at Nigards breen, Norway Norsk Geografiska Tidsskrifft 30 187209 Google Scholar
Renberg, I. 1976 Annually laminated sediment in Lake Rudetjarn, Medelpad province, northern Sweden Geologiska Foreningens i Stockholm Forhandlingar 98 355360 Google Scholar
Rymer, M.J. Sims, J.D. 1976 Preliminary Survey of Modern Glaciolacustrine Sediments for Earthquake-Induced Deformational Structures, South-Central Alaska United States Geological SurveyOpen-File Report 76-373 Google Scholar
Sims, J.D. 1973 Earthquake-induced structures in sediments of Van Norman Lake, San Fernando, California Science 182 161163 CrossRefGoogle Scholar
Sims, J.D. 1975 Determining earthquake recurrence intervals from deformational structures in young lacustrine sediments Tectonophysics 28 142152 Google Scholar
Stenborg, T. 1970 Delay of run-off from a glacier basin Geografiska Annaler 53 130 Google Scholar
Sturm, M. Matter, A. 1978 Turbidites and varves in Lake Brienz (Switzerland): Deposition of clastic detritus by density currents Matter, A. Tucker, M.E. Modern and Ancient Lake Sediments International Association of Sedimentologists 145168Special PublicationGoogle Scholar
Tangborn, W. 1980 Two models for estimating climate-glacier relationships in the north Cascades, Washington, U.S.A. Journal of Glaciology 25 321 CrossRefGoogle Scholar
Tolonen, K. 1980 Comparison between radiocarbon and varve dating in Lake Lampellonfarvi, south Finland Boreas 9 1119 CrossRefGoogle Scholar
U.S. Weather Bureau 1930 Climatic Summary of the United States United States Department of Agriculture, Weather BureauSections 1,3,15,17Google Scholar
U.S. Weather Bureau 1934a Climatological Data—Alaska Section Vol. 40 United States Department of Agriculture, Weather Bureau Google Scholar
U.S. Weather Bureau 1931–1934b Climatological Data—California Section Vols. 35–38 United States Department of Agriculture, Weather Bureau Google Scholar
U.S. Weather Bureau 1931–1934c Climatological Data—Oregon Section Vols. 37–40 United States Department of Agriculture, Weather Bureau Google Scholar
U.S. Weather Bureau 1931–1934d Climatological Data—Washington Section Vols. 35–38 United States Department of Agriculture, Weather Bureau Google Scholar
Wendler, G. Ishikawa, N. 1973 Experimental study of the amount of ice melt using three different methods: A contribution to the international hydrological decade Journal of Glaciology 12 399410 Google Scholar
Wendler, G. Weller, G. 1974 A heat-balance study on McCall Glacier, Brooks Range, Alaska: A contribution to the international hydrological decade Journal of Glaciology 13 1326 Google Scholar
Yamamoto, A. Kanari, S. Fukuo, Y. Horie, S. 1974 Consolidation and dating of the sediments in core samples from Lake Biwa Horie, Sh. Paleolimnology of Lake Biwa and the Japanese Pleistocene vo. 2 University of Kyoto Japan 135146 Google Scholar