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Tree-ring dates on two pre-Little Ice Age advances in Glacier Bay National Park and Preserve, Alaska, USA

Published online by Cambridge University Press:  20 January 2017

Gregory C. Wiles ,
Daniel E. Lawson ,
Eva Lyon ,
Nicholas Wiesenberg  and
R. D. D'Arrigo
Gregory C. Wiles*
Affiliation:
Department of Geology, The College of Wooster, 1189 Beall Ave, Wooster, OH, 44691, USA
Daniel E. Lawson
Affiliation:
Cold Regions Research and Engineering Lab (CRREL), 72 Lyme Road, Hanover, NH 03755, USA
Eva Lyon
Affiliation:
Department of Geology, Utah State University, 1400 Old Main Hill Logan, UT 84322, USA
Nicholas Wiesenberg
Affiliation:
1276 Scenic Heights Drive, Wooster, OH 44691, USA
R. D. D'Arrigo
Affiliation:
Tree Ring Lab, Lamont-Doherty Earth Observatory, Palisades, NY 10964, USA
*
Corresponding author. Fax: + 1 330 263 2249. E-mail addresses:[email protected] (G.C. Wiles), [email protected] (D.E. Lawson), [email protected] (E. Lyon), [email protected] (N. Wiesenberg), [email protected] (R.D. D'Arrigo).
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Abstract

Two interstadial tree ring-width chronologies from Geikie Inlet, Glacier Bay Southeast, Alaska were built from 40 logs. One of these chronologies has been calendar dated to AD 224–999 (775 yr) crossdating with a living ring-width chronology from Prince William Sound, Alaska. Trees in this chronology were likely killed through inundation by sediments and meltwater from the advancing Geikie Glacier and its tributaries ca. AD 850. The earlier tree-ring chronology spans 545 yr and is a floating ring-width series tied to radiocarbon ages of about 3000 cal yr BP. This tree-ring work indicates two intervals of glacial expansion by the Geikie Glacier system toward the main trunk glacier in Glacier Bay between 3400 and 3000 cal yr BP and again about AD 850. The timing of both expansions is consistent with patterns of ice advance at tidewater glaciers in other parts of Alaska and British Columbia about the same time, and with a relative sea-level history from just outside Glacier Bay in Icy Strait. This emerging tree-ring dated history builds on previous radiocarbon-based glacial histories and is the first study to use tree-ring dating to assign calendar dates to glacial activity for Glacier Bay.

Keywords

Glacier BayAlaskaTree ringsDendrochronologyGlacial historyFirst millennium AD
Type
Short Paper
Information
Quaternary Research , Volume 76 , Issue 2 , September 2011 , pp. 190 - 195
Copyright
University of Washington

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References

Barclay, D.J., Gloss Barclay, J.L., Calkin, P.E., and Wiles, G.C. A revised and extended Holocene history of Icy Bay, southern Alaska: Arctic. Antarctic and Alpine Research 38, (2006). 153162.Google Scholar
Barclay, D.J., Wiles, G.C., and Calkin, P.E. Tree-ring cross-dates for a first millennium AD advance of Tebenkof Glacier, southern, Alaska. Quaternary Research 71, (2009). 2226. doi:http://dx.doi.org/10.1016/j.yqres.2008.09.005CrossRefGoogle Scholar
Barclay, D.J., Wiles, G.C., and Calkin, P.E. Holocene glacier fluctuations in Alaska. Quaternary Sciences Reviews 28, (2009). 20342048.Google Scholar
Brown, C.S., Meier, M.F., and Post, A. Calving speed of Alaska tidewater glaciers, with application to Columbia Glacier. U.S. Geological Survey Professional Paper 1258-C. (1982). Google Scholar
Capps, D., Wiles, G.C., Luckman, B.H. and Clague, J., in press. Elevation-constrained dendrochronology of lakes dammed by Brady Glacier, Glacier Bay National Park and Preserve, Alaska. The Holocene, DOI:http://dx.doi.org/10.1177/0959683610391315Google Scholar
Chapin, F.S., Walker, L.R., Fastie, C.L., and Sharman, L.C. Mechanisms of primary succession following deglaciation at Glacier Bay. Alaska: Ecological Monographs 64, (1994). 26 Google Scholar
Clague, J.J., and Evans, S.G. Historic retreat of Grand Pacific and Melbern Glaciers, Saint Elias Mountains, Canada: an analogue for decay of the Cordilleran ice sheet at the end of the Pleistocene. Journal of Glaciology 39, (1993). 619624.CrossRefGoogle Scholar
Connor, C., Streveler, G., Post, A., Monteith, D., and Howell, W. The Neoglacial landscape and human history of Glacier Bay, Glacier Bay National Park and Preserve, southeast Alaska, USA. The Holocene 19, (2009). 381393.Google Scholar
Derksen, S.J. Glacial geology of the Brady Glacier region, Alaska. Ohio State University Institute of Polar Studies Report 60, (1976). 97 Google Scholar
Elliott, J., Larsen, C.F., Freymueller, J.T., and Motyka, R.J. Tectonic block motion and glacial isostatic adjustment in Southeast Alaska and adjacent Canada constrained by GPS measurements. Journal of Geophysical Research (2010). http://dx.doi.org/10.1029/2009JB007139Google Scholar
Fastie, C.L. Causes and ecosystems consequences of multiple pathways of primary succession at Glacier Bay, Alaska. Ecology 76, (1995). 18991916.Google Scholar
Goldthwait, R.P. Glacial history. Mirksy, A. The Ohio State University Institute of Polar Studies Report 20, (1966). 167 p.Google Scholar
Goodwin, R.G. Holocene glaciolacustrine sedimentation in Muir Inlet and ice advance in Glacier Bay, Alaska, U.S.A. Arctic and Alpine Research 20, (1988). 5569.Google Scholar
Grissino-Meyer, H.D. Evaluating crossdating accuracy: a manual and tutorial for the computer program COFECHA. Tree-Ring Research 57, (2001). 205221.Google Scholar
Hicks, S.D., and Shofnos, W. The determination of land emergence from sea level observations in southeastern Alaska. Journal of Geophysical Research 70, (1965). 33153320.Google Scholar
Holmes, R.L. Computer-assisted quality control in tree-ring dating and measurement. Tree-Ring Bulletin 43, (1983). 6978.Google Scholar
Hunter, L.E., Powell, R.D., and Lawson, D.E. Flux of debris transported by ice at three Alaskan tidewater glaciers. Journal of Glaciology 42, (1996). 123135.CrossRefGoogle Scholar
Lamb, W.K. George Vancouver: a Voyage of Discovery to the North Pacific Ocean and Around the World, 1791–1795, 4 Vols. (1984). Hakluyt Society, London, UK.Google Scholar
Larsen, C.F., Motyka, R.J., Freymuller, J.T., Echelmeyer, K.A., and Ivins, E.R. Rapid viscoelastic uplift in southeast Alaska caused by post-Little Ice Age glacial retreat. Earth and Planetary Science Letters 237, (2005). 548560.Google Scholar
Lawson, D.E., Finnegan, D.C., Kopczynski, S.E., and Bigl, S.R. Early to mid-Holocene glacier fluctuations in Glacier Bay, Alaska. Piatt, J.F., and Gende, S.M. Proceedings of the Fourth Glacier Bay Science Symposium, October 26–28, 2004. U.S. Geological Survey Scientific Investigations Report 2007–5047 (2007). 5456.Google Scholar
Mann, D.H. Reliability of a fjord glacier's fluctuations for paleoclimatic reconstructions. Quaternary Research 25, (1986). 1024.CrossRefGoogle Scholar
Mann, D.H., and Hamilton, T.D. Late Pleistocene and Holocene paleoenvironments of the North Pacific coast. Quaternary Science Reviews 14, (1995). 449471.Google Scholar
Mann, D.H., and Streveler, G.P. Post-glacial relative sea level, isostasy, and glacial history in Icy Strait, Southeast Alaska, USA. Quaternary Research 69, (2008). 201216.Google Scholar
Mann, D.H., and Ugolini, F.C. Holocene glacial history of the Lituya district, southeast Alaska. Canadian Journal of Earth Sciences 22, (1985). 913928.CrossRefGoogle Scholar
Mann, D.H., Crowell, A.L., Hamilton, T.D., and Finney, B.P. Holocene geologic and climatic history around the Gulf of Alaska. Arctic Anthropology 35, (1998). 112131.Google Scholar
McKenzie, G.D., and Goldthwait, R.G. Glacial history of the last eleven thousand years in Adams Inlet, southeastern Alaska. Geological Society of America Bulletin 82, (1971). 17671782.Google Scholar
Meier, M.F., and Post, A. Fast tidewater glaciers. Journal of Geophysical Research 92(B9), (1987). 90519058.CrossRefGoogle Scholar
Molnia, B.F. Late nineteenth to early twenty-first century behavior of Alaskan glaciers as indicators of changing regional climate. Global and Planetary Change 56, (2007). 2356. http://dx.doi.org/10.1016/j.gloplacha.2006.07.011Google Scholar
Motyka, R.J. Post little ice age uplift at Juneau, Alaska reconstructed from dendrochronology and geomorphology. Quaternary Research 59, (2003). 300309.CrossRefGoogle Scholar
Motyka, R.J., Larsen, C.F., Freymueller, J.T., and Echelmeyer, K.A. Post Little Ice Age glacial rebound in Glacier Bay National Park and surrounding areas. Alaska Park Science 6, (2007). 3641.Google Scholar
Pfeffer, W.T. A simple mechanism for irreversible tidewater glacier retreat. Journal of Geophysical Research 112, (2007). F03S25 http://dx.doi.org/10.1029/2006JF000590Google Scholar
Pilcher, J.R. Sample preparation, cross-dating, and measurement. Cook, E.R., and Kairiukstis, L.A. Methods of Dendrochronology: Applications in the Environmental Sciences. (1989). Kluwer Academic Publishers, Dordrecht, The Netherlands. 4051.Google Scholar
Post, A. Preliminary hydrology and historic terminal changes of Columbia Glacier. (1975). U.S. Geological Survey Hydrological Investigation Atlas, Map HA-525, Alaska.Google Scholar
Post, A., and Motyka, R.J. Taku and Le-Conte Glaciers, Alaska — calving-speed control of Late-Holocene asynchronous advances and retreats. Physical Geography 16, (1995). 5982.Google Scholar
Powell, R.D. Grounding-line systems as second-order controls on fluctuations of tidewater termini of temperate glaciers. Anderson, J.B., and Ashley, G.M. Glacial Marine Sedimentation: Paleoclimatic Significance. (1991). Google Scholar
Reimer, P.J., Baillie, M.G.L., Bard, E., Bayliss, A., Beck, J.W., Bertrand, C.J.H., Blackwell, P.G., Buck, C.E., Burr, G.S., Cutler, K.B., Damon, P.E., Edwards, R.L., Fairbanks, R.G., Friedrich, M., Guilderson, T.P., Hogg, A.G., Hughen, K.A., Kromer, B., McCormac, F.G., Manning, S.W., Ramsey, C.B., Reimer, R.W., Remmele, S., Southon, J.R., Stuiver, M., Talamo, S., Taylor, F.W., van der Plicht, J., and Weyhenmeyer, C.E. IntCal04 Terrestrial radiocarbon age calibration, 26–0 ka BP. Radiocarbon 46, (2004). 10291058.Google Scholar
Reyes, A.V., Wiles, G.C., Smith, D.J., Barclay, D.J., Allen, S., Jackson, S., Larocque, S., Laxton, S., Lewis, D., Calkin, P.E., and Clague, J.J. Expansion of alpine glaciers in Pacific North America in the first millennium AD. Geology 34, (2006). 5760. http://dx.doi.org/10.1130/G21902.1Google Scholar
Stokes, M.A., and Smiley, T.L. An Introduction to Tree-ring Dating. (1996). The University of Arizona Press, Tucson. 73 p.Google Scholar
Stuiver, M., Reimer, P.J., and Reimer, R.W. CALIB 5.0. www.programanddocumentation (2005). Google Scholar
Syvitski, J.P.M. On the deposition of sediment within glacier-influenced fjords: oceanographic controls. Powell, R.D., and Elverhoi, A. Modern Glacimarine Environments: Glacial and Marine Controls of Modern Lithofacies and Biofacies. Marine Geology 85, (1989). 301329.CrossRefGoogle Scholar
Telford, R.J., Heegaard, E., and Birks, H.J.B. The intercept is a poor estimate of a calibrated radiocarbon age. The Holocene 14, (2004). 296298.Google Scholar
Wiles, G.C., Calkin, P.E., and Post, A. Glacial fluctuations in the Kenai Fjords, Alaska, U.S.A.: an evaluation of controls on iceberg-calving glaciers. Arctic and Alpine Research 27, (1995). 234245.CrossRefGoogle Scholar
Wiles, G.C., Barclay, D.J., Calkin, P.E., and Lowell, T.V. Century to millennial-scale temperature variations for the last two thousand years inferred from Glacial Geologic Records of Southern Alaska. Global and Planetary Change 57, (2008). http://dx.doi.org/10.1016/j.gloplacha.2006.07.036Google Scholar
Wiles, G.C. et al. Ring-width Tree-ring Chronologies from Alaska — 7 Series: IGBP PAGES/World Data Center for Paleoclimatology Data Contribution Series # 2009, ak090–ak096. (2009). NOAA/NCDC Paleoclimatology Program, Boulder CO, USA. ftp://ftp.ncdc.noaa.gov/pub/data/paleo/treering/updates/ Google Scholar
Wilson, R., Wiles, G., D'Arrigo, R., and Zweck, C. Cycles and shifts: 1300-years of multi-decadal temperature variability in the Gulf of Alaska. Climate Dynamics 28, (2007). 425440.Google Scholar