Hostname: page-component-848d4c4894-ndmmz Total loading time: 0 Render date: 2024-06-01T14:08:11.365Z Has data issue: false hasContentIssue false
  • English
  • Français

Heightened North Pacific Storminess during Synchronous Late Holocene Erosion of Northwest Alaska Beach Ridges

Published online by Cambridge University Press:  20 January 2017

Owen K. Mason  and
James W. Jordan
Owen K. Mason
Affiliation:
Alaska Quaternary Center, University of Alaska Museum, 907 Yukon Drive, Fairbanks, Alaska 99775-1200
James W. Jordan
Affiliation:
Alaska Quaternary Center, University of Alaska Museum, 907 Yukon Drive, Fairbanks, Alaska 99775-1200
Get access Rights & Permissions [Opens in a new window]

Abstract

A progradational regime of falling sea level and/or high sediment input has produced extensive beach ridge plains in northwest Alaska during the last 4000 yr. Eleven Chukchi Sea beach ridge complexes, oriented at various angles to wind fetch, provide a cumulative history of longshore transport and erosion. Archaeological and geological upper limiting radiocarbon ages (n = 59) allow correlations between depositional units on seven beach ridge complexes. Progradation started 4000 yr B.P. at nearly all complexes, as eustatic sea level stabilized. Two disconformities or truncations are found on most of the complexes, providing time-parallel storm horizons, dated at 3300-1700 and 1200-900 14C yr B.P. Between 1700 and 1200 14C yr B.P. most of the complexes prograded, indicating the predominance of less-stormy conditions. Modern synoptic patterns that produce Chukchi beach ridge erosion are linked to northerly shifts in North Pacific storm tracks. The regionwide beach ridge erosional truncations correlate with records of glacier expansion, heightened precipitation evident in tree-rings, stream flooding, and shelf deposits reworked by storm surges.

Type
Research Article
Information
Quaternary Research , Volume 40 , Issue 1 , July 1993 , pp. 55 - 69
Copyright
University of Washington

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

Biasing, T. J., and Fritts, H. C. (1975). Past climate of Alaska and northwestern Canada as reconstructed from tree rings. In “Climate of the Arctic” (Weller, G. and Bowling, S. A., Eds.), pp. 4858. Geo-physical Institute, Fairbanks.Google Scholar
Brigham, J. (1985). “Marine Stratigraphy and Amino acid Geochronol-ogy of the Gubik Formation, Western Arctic Coastal Plain, Alaska.” Unpublished Ph.D. dissertation, University of Colorado.Google Scholar
Calkin, P. (1988). Holocene glaciation of Alaska (and adjoining Yukon Territory, Canada). Quaternary Science Reviews, 7, 159184.Google Scholar
Carter, R. W. G., and Orford, J. D. (1981). Overwash processes along a gravel beach in southeast Ireland. Earth Surface Processes and Landforms 6, 413426.Google Scholar
Carter, R. W. G., and Stone, G. W. (1989). Mechanisms associated with the failure of eroding sand dunes, Magilligan, Northern Ireland. Earth Surface Processes and Landforms 14, 110.CrossRefGoogle Scholar
Cooper, N. S., and Whysall, K. D. (1989). Recent decadal climate variations in the Tropical Pacific. International Journal of Climatology 9, 221242.CrossRefGoogle Scholar
Creager, J. S., and McManus, D. A. (1966). Geology of the southeastern Chukchi Sea. In “Environment of the Cape Thompson Region, Alaska” (Wilimovsky, N. J. and Wolfe, J. N., Eds.), pp. 755786. United States Atomic Energy Commission, Oakridge.Google Scholar
Curray, J. R. Emmel, F. J., and Crampton, P. J. S. (1969). Holocene history of a strand plain, lagoonal coast, Nayarit, Mexico. In “Coastal Lagoons: A Symposium” (Castanares, A. A., Ed.), pp. 63100. Universidad Nacional Autonoma de México, México.Google Scholar
Elias, S. A. Short, S. K., and Phillips, R. L. (1992). Paleoecology of late-glacial peats from the Bering Land Bridge, Chukchi Sea shelf region, northwestern Alaska. Quaternary Research 38, 371378.Google Scholar
Faas, R. W. (1966). Paleoecology of an arctic estuary. Arctic 19, 343348.CrossRefGoogle Scholar
Fritts, H. C. (1991). “Reconstructing Large-scale Climatic Patterns from Tree-Ring Data.” Univ. of Arizona Press, Tucson.Google Scholar
Giddings, J. L. (1948). Chronology of the Kobuk-Kotzebue Sites. Tree-ring Bulletin 14, 2632.Google Scholar
Giddings, J. L. (1952). Driftwood and problems of Arctic sea currents. Proceedings, American Philosophical Society 96, 129142.Google Scholar
Giddings, J. L., and Anderson, D. D. (1986). “Beach Ridge Archaeology of Cape Krusenstern: Eskimo and Pre-Eskimo Settlements Around Kotzebue Sound.” Publications in Archaeology 20. National Park Service, Washington.Google Scholar
Gfeller, C Oeschger, H., and Schwarz, U. (1961). Bern radiocarbon dates II. Radiocarbon 3, 1525.CrossRefGoogle Scholar
Hamilton, T. D. (1981). Episodic alluviation in the central Brooks Range—Chronology, correlations and climatic implications. In “United States Geological Survey in Alaska Accomplishments during 1979” (Albert, N. R. D. and Hudson, T., Eds.), pp. 2124. U.S. Geological Survey Circular 823B.Google Scholar
Hamilton, T. D. Ager, T. A., and Robinson, S. W. (1983). Late Ho-locene ice wedges near Fairbanks, Alaska, U.S.A.: Environmental setting and history of growth. Arctic and Alpine Research 15, 157168.Google Scholar
Harritt, R. K. (In press). “Eskimo Prehistory on Seward Peninsula.” National Park Service, Anchorage.Google Scholar
Hopkins, D. M. (1967). Quaternary marine transgressions in Alaska. In “The Bering Land Bridge” (Hopkins, D. M., Ed.), pp. 4790. Stanford Univ. Press, Stanford.Google Scholar
Hopkins, D. M. (1973). Sea level history in Beringia during the last 250,000 years. Quaternary Research 3, 520540.Google Scholar
Hopkins, D. M, (1986). Coastal processes and coastal erosion hazards at the Cape Krusenstern Monument. In “Beach Ridge Archaelogy of Cape Krusenstern” (Giddings, J. L. and Anderson, D. D., Eds.), Appendix I, pp. 350–355. Publications in Archaeology 20, National Park Service, Washington.Google Scholar
Hopkins, D. M. (1988). The Espenberg Maars: A record of explosive volcanic activity in the Devil Mt.-Cape Espenberg, Seward Peninsula, Alaska. In “The Bering Land National Preserve: An Archaeological Survey, Volume I” (Schaaf, J., Ed.), pp. 262321. National Park Service, Alaska Region. Resources Management Report 14. Anchorage.Google Scholar
Hume, J. D. (1965). Sea-level changes during the last 2000 years at Pt. Barrow, Alaska. Science 150, 11651166.CrossRefGoogle Scholar
Jacoby, G. (1982). The Arctic. In “Climate from Tree Rings” (Hughes, M. K. Kelly, P. M. Pilcher, J. R., and LaMarche, V. C. Jr., Eds.), pp. 107114. Cambridge Univ. Press, Cambridge.Google Scholar
Jordan, J. W. (1988). Erosion characteristics and retreat rates along the north coast of Seward Peninsula, In “The Bering Land National Preserve: An Archaeological Survey, Volume I” (Schaaf, J., Ed.), pp. 322362, Research/Resources Management Report 14, National Park Service, Anchorage.Google Scholar
Jordan, J. W. (1990). “Late Holocene development of barrier islands in the southern Chukchi Sea, Alaska.” Unpublished Master’s thesis, University of Alaska.Google Scholar
Kowalik, Z. (1984). Storm surges in the Beaufort and Chukchi Seas. Journal of Geophysical Research, 89 (C6), 10,57010,578.CrossRefGoogle Scholar
La Belle, J. C Wise, J. L. Voelker, R. P. Schulze, R. H., and Wohl, G. M. (1983). “Alaska Marine Ice Atlas.” Arctic Environmental Information and Data Center, University of Alaska, Anchorage.Google Scholar
Mason, O. K. (1990). “Beach Ridge Geomorphology of Kotzebue Sound.” Unpublished Ph.D. Dissertation, University of Alaska.Google Scholar
Mason, O. K. (1992). A geoarchaeological methodology for studying prograding coastal sequences: Beach ridge geomorphology in Kotzebue Sound, Alaska. In “Paleoshorelines and Prehistory: An Exploration of Method” (Johnson, L. L. and Stright, M. J., Eds.), pp. 5581. CRC Press, Boca Raton, FL.Google Scholar
Mason, O. K., and Begét, J. E. (1991). Late Holocene flood history of the Tanana River, Alaska U.S.A. Arctic and Alpine Research 23, 392403.CrossRefGoogle Scholar
Mason, O. K., and Jordan, J. W. (1991). A proxy late Holocene climate record deduced from NW Alaska beach ridges. In “Proceedings, International Conference on the Role of the Polar Regions in Global Change,” Vol. II (Weller, G. Wilson, C., and Severin, B., Eds.), pp. 649657. Geophysical Institute, Fairbanks.Google Scholar
Mason, O. K., and Ludwig, S. L. (1990). Resurrecting beach ridge archaeology: Parallel depositional histories from St. Lawrence Island and Cape Krusenstern, Alaska. Geoarchaeology 5, 349373.Google Scholar
McCulloch, D. S. (1967). Quaternary Geology of the Alaskan shore of Chukchi Sea. In “The Bering Land Bridge” (Hopkins, D. M., Ed.), pp. 91120. Stanford Univ. Press, Stanford.Google Scholar
McManus, D. A. Creager, J. S. Echols, R. J., and Holmes, M. L. (1983). The Holocene transgression on the Arctic flank of Beringia: Chukchi valley to Chukchi estuary to Chukchi Sea. In “Quaternary Coastlines and Marine Archaeology: Towards a Prehistory of Land Bridges and Continents” (Masters, P. M. and Fleming, N. C., Eds.), pp. 365388. Academic Press, New York.Google Scholar
Moore, G. W. (1960). Arctic beach sedimentation. In “Environment of the Cape Thompson Region, Alaska” (Wilimovsky, N. and Wolfe, J. N., Eds.), pp. 587608, Atomic Energy Commission, Oak Ridge.Google Scholar
Moore, G. W., and Giddings, J. L. (1961). Record of 5000 years of Arctic wind direction recorded by Alaskan beach ridges. Geological Society America Special Publication 68. [Abstract] Google Scholar
Naidu, A. S., and Gardner, G. (1988). Marine Geology. In “The Environment and Resources of the southern Chukchi Sea” (Hameedi, M. J. and Naidu, A. S., Eds.), pp. 1128. Outer Continental Shelf (OCS) Study, Mineral Management Study 870113.Google Scholar
Nelson, C. H. (1982). Modern shallow-water graded sand layers from storm surges, Bering shelf: A mimic of bouma sequences and tur-bidite systems. Journal of Sedimentary Petrology 52, 537545.Google Scholar
Nelson, C. H., and Creager, J. S. (1977). Displacement of Yukon-derived sediment from Bering Sea to Chukchi Sea during Holocene time. Geology 5, 141145.2.0.CO;2>CrossRefGoogle Scholar
Patton, W. W. Jr., and Miller, T. P. (1968). Regional geologic map of the Selawik and southeastern Baird Mountains Quadrangles, Alaska. U.S. Geological Survey Miscellaneous Geological Investigations Map 1530.Google Scholar
Peterson, C. D. Jackson, P. L. O’Neill, D. J. Rosenfeld, C. L., and Kimerling, A. J. (1990). Littoral cell response to interannual climate forcing 1983-1987 on the central Oregon coast, USA. Journal of Coastal Research 6, 87110.Google Scholar
Péwé, T. L., and Church, R. E. (1962). Age of the spit at Barrow, Alaska. Geological Society of America Bulletin 73, 12871291.CrossRefGoogle Scholar
Psuty, N. P. (1988). Sediment Budget and Dune/beach interaction. Journal of Coastal Research Special Issue 3, 14.Google Scholar
Ralph, E. K., and Ackerman, R. E. (1961). University of Pennsylvania Radiocarbon Dates IV. Radiocarbon 3, 414.CrossRefGoogle Scholar
Robinson, S. W., and Trimble, D. A. (1981). US Geological Survey Radiocarbon Measurements II. Radiocarbon 23, 305321.Google Scholar
Robinson, S. W., and Trimble, D. A. (1983). US Geological Survey Radiocarbon Measurements III. Radiocarbon 25, 143151.Google Scholar
Sainsbury, C. L. (1967). Upper Pleistocene features in the Bering Strait area. United States Geological Survey Professional Paper 575-D, 203213.Google Scholar
Salmon, D. K. (1992). “On Interannual Variability and Climatic Change in the North Pacific.” Unpublished Ph.D. dissertation, University of Alaska.Google Scholar
Sandweiss, D. H. (1986). The beach ridges at Santa, Peru: El Nino, uplift and prehistory. Geoarchaeology I, 1728.CrossRefGoogle Scholar
Schaaf, J. (Ed.) (1988). “The Bering Land Bridge: An Archaeological Survey, Volume I.” Resources/Management Report 14, National Park Service, Alaska Region, Anchorage.Google Scholar
Scholl, D. W., and Sainsbury, C. L. (1966). Marine geology of the Ogo-toruk Creek Region. In “Environment of the Cape Thompson Region, Alaska” (Wilimovsky, N. and Wolfe, J. N., Eds.), pp. 787806. Atomic Energy Commission, Oak Ridge.Google Scholar
Shepard, F. P. (1973). “Submarine Geology.” Harper and Row, New York.Google Scholar
Spiker, E. Kelley, L., and Meyer, R. (1978). U.S. Geological Survey Radiocarbon Dates XIII. Radiocarbon 20, 139156.Google Scholar
Stuckenrath, R. Coe, W. R., and Ralph, E. K. (1966). University of Pennsylvania Radiocarbon Dates IX. Radiocarbon 8, 348385.Google Scholar
Stuiver, M., and Reimer, P. J. (1986). A computer program for radiocarbon age calibration. Radiocarbon 28, 10221030.Google Scholar
Wilson, J. G., and Overland, J. E. (1987). Meteorology. In “The Gulf of Alaska: Physical Environment and Biological Resources” (Hood, D. W. and Zimmerman, S. T., Eds.), pp. 3156. National Oceanic and Atmospheric Administration, Minerals Management Study OC 860095.Google Scholar
Wise, J. L. Comiskey, A. L., and Becker, R. (1981). “Storm Surge Climatology and Forecasting in Alaska,” Arctic Environmental In-formation and Data Center, University of Alaska, Anchorage.Google Scholar