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Holocene glacier fluctuations inferred from lacustrine sediment, Emerald Lake, Kenai Peninsula, Alaska

Published online by Cambridge University Press:  20 January 2017

Taylor S. LaBrecque
Affiliation:
School of Earth Sciences & Environmental Sustainability, Northern Arizona University, Flagstaff, AZ 86011-4099, USA
Darrell S. Kaufman*
Affiliation:
School of Earth Sciences & Environmental Sustainability, Northern Arizona University, Flagstaff, AZ 86011-4099, USA
*
Corresponding author. E-mail address:[email protected] (D.S. Kaufman).

Abstract

Physical and biological characteristics of lacustrine sediment from Emerald Lake were used to reconstruct the Holocene glacier history of Grewingk Glacier, southern Alaska. Emerald Lake is an ice-marginal threshold lake, receiving glaciofluvial sediment when Grewingk Glacier overtops the topographic divide that separates it from the lake. Sub-bottom acoustical profiles were used to locate core sites to maximize both the length and resolution of the sedimentary sequence recovered in the 4-m-long cores. The age model for the composite sequence is based on 13 14C ages and a 210Pb profile. A sharp transition from the basal inorganic mud to organic-rich mud at 11.4 ± 0.2 ka marks the initial retreat of Grewingk Glacier below the divide of Emerald Lake. The overlaying organic-rich mud is interrupted by stony mud that records a re-advance between 10.7 ± 0.2 and 9.8 ± 0.2 ka. The glacier did not spill meltwater into the lake again until the Little Ice Age, consistent with previously documented Little Ice Ages advances on the Kenai Peninsula. The retreat of Grewingk Glacier at 11.4 ka took place as temperature increased following the Younger Dryas, and the subsequent re-advance corresponds with a climate reversal beginning around 11 ka across southern Alaska.

Type
Original Articles
Copyright
University of Washington

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References

Appleby, P.G., Oldfield, F., (1978). The calculation of lead-210 dates assuming a constant rate of supply of unsupported 210Pb to the sediment. Catena 5, 18.Google Scholar
Bailey, H.L., Kaufman, D.S., Henderson, A.C.G., Leng, M.J., (2015). Synoptic-scale circulation controls on the δ18O in precipitation across Beringia. Geophysical Research Letters 42, 46084616.Google Scholar
Barclay, D., Wiles, G., Calkin, P., (2009). Holocene glacier fluctuations in Alaska. Quaternary Science Reviews 28, 20342048.Google Scholar
Binford, M.W., (1990). Calculation and uncertainty analysis of 210Pb dates for PIRLA project lake sediment cores.. Journal of Paleolimnology 3, 253267.Google Scholar
Blaauw, M., (2010). Methods and code for ‘classical’ age-modeling of radiocarbon sequences. Quaternary Geochronology 5, 512518.Google Scholar
Briner, J.P., Kaufman, D.S., Werner, A., Caffee, M., Levy, L., Kaplan, M.R., Finkel, R.C., (2002). Glacier readvance during the late glacial (Younger Dryas?) in the Ahklun Mountains, southwestern Alaska. Geology 30, 679682.Google Scholar
Clegg, B.F., Kelly, R., Clarke, G.H., Walker, I.R., Hu, F.S., (2011). Nonlinear response of summer temperature to Holocene isolation forcing in Alaska. Proceedings of the National Academy of Sciences of the United States of America 108, 1929919304.CrossRefGoogle Scholar
D'Arrigo, R., Wilson, R., Jacoby, G., (2006). On the long-term context for late twentieth century warming. Journal of Geophysical Research 111, D03103.Google Scholar
Daigle, T., Kaufman, D.S., (2009). Holocene climate inferred from glacier extent, lake sediment and tree rings at Goat Lake, Kenai Mountains, Alaska, USA. Journal of Quaternary Science 24, 3345.Google Scholar
Dall, W.H., (1896). 17th Annual report. Journal of the American Geography Society.. 28, 120.Google Scholar
D'Arrigo, R., Jacoby, G., (1999). Northern North American tree-ring evidence for regional temperature changes after major volcanic events. Climatic Change 41, 115.Google Scholar
Davi, N.K., Jacoby, G.C., Wiles, G.C., (2003). Boreal temperature variability inferred from maximum latewood density and tree-ring with data, Wrangell Mountain region, Alaska. Quaternary Research 60, 252262.Google Scholar
Davis, P.T., Menounos, B., Osborn, G., (2009). Holocene and latest Pleistocene alpine glacier fluctuations: a global perspective. Quaternary Science Reviews 28, 20212033.Google Scholar
de Fontaine, C.S., Kaufman, D.S., Anderson, R.S., Werner, A., Waythomas, C.F., Brown, T.A., (2007). Late Quaternary distal tephra-fall deposits in lacustrine sediments, Kenai Peninsula, Alaska. Quaternary Research 68, 6478.Google Scholar
Gilbert, G.K., (1903). Glaciers and glaciation. Harriman Alaska Expedition. Vol. 3, (New York., 231 pp.).Google Scholar
Heine, J.T., (1998). Extent, timing and climatic implications of glacier advances Mount Rainier, Washington, U.S.A., at the Pleistocene/Holocene transition. Quaternary Science Reviews 17, 11391148.Google Scholar
Hildreth, W., Fierstein, J., (2012). The Novarupta-Katmai eruption of 1912 largest eruption of the twentieth century; centennial perspectives. U.S. Geological Survey Professional Paper 1791, 259 pp.Google Scholar
Hu, F.S., Kaufman, D., Yoneji, S., Nelson, D., Shemesh, A., Huang, Y., Tian, J., Bond, G., Clegg,, B., Brown, T., (2003). Cyclic variation and solar forcing of Holocene climate in the Alaskan subarctic. Science 301, 18901892.Google Scholar
Hu, F.S., Nelson, D.M., Clarke, G.H., Rühland, K.M., Huang, Y., Kaufman, D.S., Smol, J.P., (2006). Abrupt climatic events during the last glacial-interglacial transition in Alaska: Geophysical Research Letters. 33, L18708. http://dx.doi.org/10.1029/2006GL027261.Google Scholar
Ivy Ochs, S., Kerschner, H., Maisch, M., Christl, M., Kubik, P.W., Schluchter, C., (2009). Latest Pleistocene and Holocene glacier variations in the European Alps. Quaternary Science Reviews 28, 21372149.Google Scholar
Jones, M.C., Peteet, D.M., Kurdyla, D., Guilderson, T., (2009). Climate and vegetation history from a 14,000-year peatland record, Kenai Peninsula, Alaska. Quaternary Research 72, 207217.CrossRefGoogle Scholar
Jones, M.C., Wooller, M., Peteet, D.M., (2014). A deglacial and Holocene record of climate variability in south-central Alaska from stable oxygen isotopes and plant macrofossils in peat. Quaternary Science Reviews 87, 111.Google Scholar
Kaufman, D.S., Anderson, R.S., Hu, F.S., Berg, E., Werner, A., (2010). Evidence for a variable and wet Younger Dryas in southern Alaska. Quaternary Science Reviews 29, 14451452.CrossRefGoogle Scholar
Kaufman, D.S., Axford, Y., Anderson, R.S., Lamoureux, S.F., Schindler, D.E., Walker, I.R., Werner, A., (2012). A multi-proxy record of the Last Glacial Maximum and last 14,500 years of paleoenvironmental change at Lone Spruce Pond, southwestern Alaska. Journal of Paleolimnology 48, 926.Google Scholar
Kaufman, D.S., Axford, Y.L., Henerson, A., McKay, N.P., Oswald, W.W., Saenger, C., Anderson, R.S., Bailey, H.L., Clegg, B., Gajewski, K., Hu, F.S., Jones, M.C., Massa, C., Routson, C.C., Werner, A., Wooller, M.J., Yu, Z., (2015). Holocene climate changes in eastern Beringia (NW North America) — a systemic review of multi-proxy evidence. Quaternary Science Reviews (in press).Google Scholar
LaBrecque, T.S., (2014). Holocene glacier fluctuations and tephra fall inferred from lacustrine sediment MS Thesis Northern Arizona University, Emerald Lake. Alaska (130 pp. http://pqdtopen.proquest.com/pubnum/1563867.html).Google Scholar
McKay, N., Kaufman, D., (2009). Holocene climate and glacier variability at Hallet and Greyling Lakes, Chugach Mountains, south-central Alaska. Journal of Paleolimnology 41, 143159.Google Scholar
Menounos, B., Koch, J., Osborn, G., Clague, J.J., Mazzucchi, D., (2004). Early Holocene glacier advance, southern Coast Mountains, British Columbia, Canada. Quaternary Science Reviews 23, 15431550.Google Scholar
Menounos, B., Osborn, G., Clague, J.J., Luckman, B.H., (2009). Latest Pleistocene and Holocene glacier fluctuations in western Canada. Quaternary Science Reviews 28, 20492074.Google Scholar
Nesje, A., (2009). Latest Pleistocene and Holocene alpine glacier fluctuations in Scandinavia. Quaternary Science Reviews 28, 21192136.Google Scholar
Reger, R.D., Sturmann, A.G., Berg, E.E., Burns, P.A.C., (2008). A Guide to the Late Quater- nary History of Northern and Western Kenai Peninsula, Alaska. State of Alaska Department of Natural Resources Division of Geological & Geophysical Surveys (112 pp.).Google Scholar
Rein, B., Sirocko, F., (2002). In-situ reflectance spectroscopy-analysing techniques for highresolution pigment logging in sediment cores. International Journal of Earth Sciences 91, 950954.Google Scholar
Solomina, O.N., Bradley, R.S., Hodgson, D.A., Ivy-Ochs, S., Jomelli, V., Macintosh, A.N., Nesje, A., Owen, L.A., Wanner, H., Wiles, G.C., Young, N.E., (2015). Holocene glacier fluctuations. Quaternary Science Reviews 111, 934.Google Scholar
Stuiver, M., Reimer, P.J., (1993). Extended 14C database and revised CALIB radiocarbon calibration program. Radiocarbon 35, 215230.Google Scholar
Ten Brink, N.W., Waythomas, C.F., (1985). Late Wisconsin glacial chronology of the north- central Alaska Range: a regional synthesis and its implications for early human settlements. National Geographic Research Report 19, 1533.Google Scholar
Thomas, E.K., Szymanski, J., Briner, J.P., (2010). Holocene alpine glaciation inferred from lacustrine sediments on northeastern Baffin Island, Arctic Canada. Journal of Quaternary Science 25, 146161.Google Scholar
Viau, A.E., Gajewski, K., Sawada, M.C., Bunbury, J., (2008). Low- and high-frequency climate variability in eastern Beringia during the past 25,000 years. Canadian Journal of Earth Sciences 45, 14351453.CrossRefGoogle Scholar
Wanner, H., Solomina, O., Grosjean, M., Ritz, S.P., Jetel, M., (2011). Structure and origin ofHolocene cold events. Quaternary Science Reviews 30, 31093123.Google Scholar
Wiles, G., Calkin, P., (1994). Late Holocene high-resolution glacial chronologies and climate, Kenai Mountains Alaska. Geological Society of America Bulletin 106, 281303.2.3.CO;2>CrossRefGoogle Scholar
Wiles, G.C., D'Arrigo, R.D., Jacoby, G.C., (1998). Gulf of Alaska atmosphere–ocean variability over recent centuries inferred from coastal tree-ring records. Climatic Change 38, 289306.Google Scholar
Wiles, G.C., D'Arrigo, R.D., Villalba, R., Calkin, P.E., Barclay, D.J., (2004). Century-scale solar variability and Alaskan temperature change over the past millennium. Geophysical Research Letters 31, 134.Google Scholar
Wiles, G.C., D'Arrigo, R.D., Barclay, D., Wilson, R.S., Jarvis, S.K., Vargo, L., Frank, D., (2014). Surface air temperature variability reconstructed with tree rings for the Gulf of Alaska over the past 1200 years. The Holocene 24, 198208.Google Scholar
Young, N.E., Briner, J.P., Kaufman, D.S., (2009). Late Pleistocene and Holocene glaciation of the Fish Lake valley, northeastern Alaska Range, Alaska. Journal of Quaternary Science 24, 677689.Google Scholar
Yu, Z., Walker, K.N., Evenson, E.B., Hajdas, I., (2008). Lateglacial and early Holocene climate oscillations in Matanuska Valley, south-central Alaska. Quaternary Science Reviews 27, 148161.Google Scholar
Zander, P.D., Kaufman, D.S., Kuehn, S.C., Wallace, K.L., Anderson, R.S., (2013). Early and late Holocene glacial fluctuations and tephrostratigraphy, Cabin Lake, Alaska. Journal of Quaternary Science 28, 761771.Google Scholar
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