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Little Ice Age subsidence and post Little Ice Age uplift at Juneau, Alaska, inferred from dendrochronology and geomorphology

Published online by Cambridge University Press:  20 January 2017

Roman J. Motyka
Roman J. Motyka*
Affiliation:
Geophysical Institute, University of Alaska Fairbanks, Fairbanks, AK 99775-7230, USA Environmental Sciences, University of Alaska Southeast, Juneau, AK 99801, USA
*
*Geophysical Institute, University of Alaska, 835 Dixon Street, Juneau, AK 99801, USA. Fax: +1-907-586-5774. Email Address:[email protected]
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Abstract

Application of dendrochronology and geomorphology to a recently emerged coastal area near Juneau, Alaska, has documented a Little Ice Age (LIA) sea-level transgression to 6.2 m above current sea level. The rise in relative sea level is attributed to regional subsidence and appears to have stabilized by the mid 16th century, based on a sea-cliff eroded into late-Pleistocene glaciomarine sediments. Land began emerging between A.D. 1770 and 1790, coincident with retreat of regional glaciers from their LIA maximums. This emergence has continued since then, paralleling regional glacier retreat. Total Juneau uplift since the late 18th century is estimated to be 3.2 m. The rate of downward colonization of newly emergent coastline by Sitka spruce during the 20th century closely parallels the rate of sea-level fall documented by analysis of local tide-gauge records (1.3 cm/yr). Regional and Glacier Bay LIA loading and unloading are inferred to be the primary mechanisms driving subsidence and uplift in the Juneau area. Climate change rather then regional tectonics has forced relative sea-level change over the last several hundred years.

Keywords

UpliftGlacier reboundTectonicsSea-level transgressionLittle Ice AgeDendrochronologyGeomorphologySitka spruce colonization
Type
Articles
Information
Quaternary Research , Volume 59 , Issue 3 , May 2003 , pp. 300 - 309
Copyright
Elsevier Science (USA)

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References

Arendt, A, Echelmeyer, K, Harrison, W.D, Lingle, C, and Valentine, V Rapid wastage of Alaska glaciers and their contribution to rising sea level. Science 297, 5580 (2002). 382 386.CrossRefGoogle ScholarPubMed
Atwater, B.F, Yamaguchi, D.K et al. Rapid resetting of an estuarine recorder of the 1964 Alaska earthquake. GSA Bulletin 113, 9 (2001). 1193 1204.Google Scholar
Atwater, B.F, Nunez, H.J, and Vita-Finzi, C Net late Holocene emergence despite earthquake-induced submergence, south-central Chile. Quaternary International 15/16, (1992). 77 85.Google Scholar
Barnes, D.F Gravity, gravity-change and other geophysical measurements in Glacier Bay National Park and Preserve. Milner, A.M, Wood, J.D Jr. Proceedings of the Second Glacier Bay Science Symposium. (1990). U.S. Government Printing Office, National Park Service, Anchorage. 12 18.Google Scholar
Bégin, Y, Berube, D, and Gregoire, M Downward migration of coastal conifers as a response to recent land emergence in eastern Hudson Bay, Quebec. Quaternary Research 40, (1993). 81 88.CrossRefGoogle Scholar
Benson, B.E, Atwater, B.F, Yamaguchi, D.K, Amidon, L.J, Brown, S.L, and Lewis, R.C Renewal of tidal forests in Washington state after a subduction earthquake in A.D. 1700. Quaternary Research 56, (2001). 139 147.CrossRefGoogle Scholar
Clague, J.J, and James, T.S History and isostatic effects of the last ice sheet in southern British Columbia. Quaternary Science Review 21, (2002). 71 87. 2002 CrossRefGoogle Scholar
Clarke, J.A An inverse problem in glacial geology. the reconstruction of glacier thinning in Glacier Bay, Alaska between AD 1910 and 1960 from relative sea level data. Journal of Glaciology 80, (1977). 481 503.Google Scholar
Cook, E.R, and Kairiukstis, L.A Methods of Dendrochronology. (1990). Kluwer Academic, Dordrecht.CrossRefGoogle Scholar
Cramer, W The effects of sea shore displacement on population age structure of coastal Alnus glutinosa (L.) Gaertn. Holarctic Ecology 8, (1985). 265 272.Google Scholar
Cruikshank, J Glaciers and climate change: perspectives from oral tradition. Arctic 54, (2001). 377 393.CrossRefGoogle Scholar
Fletcher, H.J, and Freymueller, J.T New GPS constraints on the motion of the Yakutat Block. Geophysical Research Letters 26, 19 (1999). 3029 3032.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). 55 69.CrossRefGoogle Scholar
Hicks, S.D, and Shofnos, W The documentation of land emergence from sea-level observations in southeast Alaska. Journal of Geophysical Research 70, (1965). 3315 3320.CrossRefGoogle Scholar
Horner, R.B Seismicity in the St. Elias region of Northwestern Canada and Southeastern Alaska. Bulletin of the Seismological Society of America 73, (1983). 1117 1137.Google Scholar
Horner, R.B Seismicity in the Glacier Bay region of southeast Alaska and adjacent areas of British Columbia. Milner, A.M, Wood, J.D Jr. Proceedings of the Second Glacier Bay Science Symposium. (1990). U.S. Government Printing Office, National Park Service, Anchorage. 6 11.Google Scholar
Houghton, J.T, Ding, Y, Griggs, D.J, Noguer, M, van der Linden, P.J, and Xiaosu, D Climate Change 2001. The Scientific Basis. Contribution of Working Group I, the Third Assessment Report of the Intergovernmental Panel on Climate Change (IPCC). (2001). Cambridge Univ. Press, Cambridge, UK.Google Scholar
Hudson, T, Dixon, K, and Plafker, G Regional uplift in southeastern Alaska. US Geological Survey Circular 844, (1982). 132 135.Google Scholar
Ivins, E.R, and James, T.S Simple models for late Holocene and present-day Patagonian glacier fluctuations and predictions of a geodetically detectable isostatic response. Geophysical Journal International 138, (1999). 601 624.Google Scholar
Lacher, S Dendrologische Untersuchungen moderner und historischer Gletscherstände in den Vorfeldern von Mendenhall- und Herbert-Gletscher (Juneau Icefield/Alaska). (1999). Diplomarbeit, Geographisches Institut der Universität Zürich ausgeführt an der Eidgenössischen Forschungsanstalt für Wald, Schnee und Landschaft (WSL). 126 Google Scholar
Larsen, C.F., Freymueller, J.T., Echelmeyer, K.A, Motyka, R.J., (2003). Tide gauge records of uplift along the northern Pacific-North American plate boundary, 1937 to 2001. Journal of Geophysical Research, in press Google Scholar
Larsen, C.F, Motyka, R.J, Freymueller, J.T, and Echelmeyer, K.A New GPS constraints on crustal deformation along the Fairweather Fault and implications for motion of the Yakutat Block, southern Alaska. Eos Trans. AGU 82, Fall Meet. Suppl. (2001). G41A 197. Abstract Google Scholar
Lawrence, D.B Glacier fluctuations for six centuries in southeastern Alaska and its relation to solar activity. Geographical Review 40, (1950). 191 223.Google Scholar
McGreal, W.S Marine erosion of glacial sediments from low-energy cliff-line environment near Kilkeel, Northern Ireland. Marine Geology 32, (1979). 89 103.CrossRefGoogle Scholar
Miller, R.D Gastineau Channel Formation, a composite glaciomarine deposit near Juneau. (1973). US Geological Survey Bulletin 1394-C, Alaska. C1 C20.Google Scholar
Molenaar, D., (1990). Glacier Bay and Juneau Icefield Region and the glacierized ranges of Alaska–northwestern Canada, pictorial landform map. Molenaar Landform Maps, Google Scholar
Motyka, R.J, and Beget, J.E Taku Glacier, southeast Alaska, U.S.A.. Late Holocene history of a tidewater glacier. Arctic and Alpine Research 28, (1996). 42 51.CrossRefGoogle Scholar
Motyka, R.J, O’Neel, S, Connor, C.L, and Echelmeyer, K.A 20th century thinning of Mendenhall Glacier, Alaska, and its relationship to climate, lake calving, and glacier run-off. Global and Planetary Change 35, (2002). 93 112.CrossRefGoogle Scholar
Nyman, E, and Leer, J The legacy of a Talcu River Tlingit clan. (1993). Alaska Native Language Center, Fairbanks. pp. 261 Google Scholar
Plafker, G, Gilpin, L.M, and Lahr, J.C Neotectonic map of Alaska. Plafker, G, and Berg, H.C The geology of Alaska. (1994). Geol. Soc. Am, Boulder, Colorado. The Geology of North America, v. G1, plate 12, scale 1:2,500,000, 1994 Google Scholar
Post, A, and Motyka, R.J Taku and LeConte Glaciers, Alaska. calving speed control of late Holocene asynchronous advances and retreats. Physical Geography 16, (1995). 59 82.CrossRefGoogle Scholar
Savage, J.C, and Plafker, G Tide gage measurements of uplift along the south coast of Alaska. Journal of Geophysical Research 96, (1991). 4325 4335.Google Scholar
Schweingruber, F.H Tree Rings. Basics and Applications of Dendrochronology. (1988). Dreidwl, Boston.Google Scholar
Shih, S.M., Komar, P.D., Tillotson, T., McDougal, W.C., Ruggiero, P., (1994). Wave run-up and sea-cliff erosion. in: Edge, B.L. (Ed.), Proceedings of the 24th International Conference on Coastal Engineering, (1994). pp. 21702184.Google Scholar
Stewart, I.S, Sauber, J, and Rose, J Glacio-seismotectonics. ice sheets, crustal deformation and seismicity. Quaternary Science Reviews 19, (2000). 1367 1389.Google Scholar
Stokes, M.A, and Smiley, T.L An Introduction to Tree-Ring Dating. (1968). University of Chicago Press, Chicago.Google Scholar
Tushingham, A.M, and Peltier, W.R ICE 3-G. a new global model of late Pleistocene deglaciation based upon geophysical predictions of post glacial relative sea level change. Journal of Geophysical Research 96, (1991). 4497 4523.Google Scholar
Yamaguchi, D.K, Atwater, B.F, Bunker, D.E, Benson, B.E, and Reid, M.S Tree-ring dating the 1700 Cascadia earthquake. Nature 389, (1997). 922 923. (Correction 390, 352) Google Scholar