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Cosmogenic 10Be and 36Cl geochronology of cryoplanation terraces in the Alaskan Yukon-Tanana Upland

Published online by Cambridge University Press:  14 May 2020

Kelsey E. Nyland Open the ORCID record for Kelsey E. Nyland [Opens in a new window] ,
Frederick E. Nelson  and
Paula M. Figueiredo
Kelsey E. Nyland*
Affiliation:
Department of Geography, Environment, and Spatial Sciences, Michigan State University, East Lansing, MI, 48824, USA Department of Geography, The George Washington University, Washington, DC, 20052, USA
Frederick E. Nelson
Affiliation:
Department of Geography, Environment, and Spatial Sciences, Michigan State University, East Lansing, MI, 48824, USA Department of Earth, Environmental, and Geographical Sciences, Northern Michigan University, Marquette, MI49855, USA
Paula M. Figueiredo
Affiliation:
Department of Geology, University of Cincinnati, Cincinnati, OH, 452221, USA Earth, Marine and Atmospheric Sciences Department, North Carolina State University, Raleigh, NC, 27695, USA
*
*Corresponding author e-mail address: knyland@gwu.edu (Kelsey Nyland).
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Abstract

Cryoplanation terraces are prominent but enigmatic landforms found in present and past periglacial environments. Geomorphologists have debated for more than a century over processes involved in the formation of these elevated, step-like, bedrock features. Presented here are the first numerical surface exposure ages and scarp retreat rates from cryoplanation terraces in the Yukon-Tanana Upland (YTU) in Alaska, part of unglaciated eastern Beringia, obtained from terrestrial cosmogenic nuclides (TCN) in surface boulders. Ages comprise six 10Be TCN ages from two terrace treads near Eagle Summit and six 36 Cl ages from two treads on Mt. Fairplay. Based on these exposure ages, scarps at both locations were last actively eroding from 49 to 22.4 ka. Both locations exhibit time-transgressive development, particularly near scarp-tread junctions. Boulder exposure ages and distances between sampled boulder locations were used to estimate scarp retreat rates of 0.11 to 0.56 cm/yr. These numerical exposure ages presented here demonstrate that the cryoplanation terraces in the YTU are diachronous surfaces actively eroding during multiple cold intervals. With these results, hypotheses for cryoplanation terrace formation are discussed and evaluated for the YTU, including those based on geologic structure, nivation, and the influence of permafrost.

Keywords

Cryoplanation terracesNivationCosmogenic exposure datingBeringiaAlaska
Type
Research Article
Information
Quaternary Research , Volume 97 , September 2020 , pp. 157 - 166
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Copyright
Copyright © University of Washington. Published by Cambridge University Press, 2020

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References

REFERENCES

Balco, G., Stone, J.O., Lifton, N.A., Dunai, T.J., 2008. A complete and easily accessible means of calculating surface exposure ages or erosion rates from 10Be and 26Al measurements. Quaternary Geochronology 3, 174195.Google Scholar
Ballantyne, C.K., 2018. Periglacial Geomorphology. John Wiley and Sons, New York.Google Scholar
Ballantyne, C.K., Black, N.M., Finlay, D.P., 1989. Enhanced boulder weathering under late–lying snowpatches. Earth Surface Processes and Landforms 14, 745750.CrossRefGoogle Scholar
Berrisford, M.S., 1991. Evidence for enhanced mechanical weathering associated with seasonally late-lying and perennial snow patches, Jotunheimen, Norway. Permafrost and Periglacial Processes 2, 331–40.CrossRefGoogle Scholar
Bloom, A.L., 2004. Geomorphology: A Systematic Analysis of Late Cenozoic Landforms. 3rd ed., Waveland Press, Long Grove, IL.Google Scholar
Briner, J.P., Kaufman, D.S., Manley, W.F., Finkel, R.C., Caffee, M.W., 2005. Cosmogenic exposure dating of late Pleistocene moraine stabilization in Alaska. Geological Society of America Bulletin 117, 11081120.Google Scholar
Brown, E.H. 1968. Planation surface. In: Fairbridge, R.W. (Ed.). The Encyclopedia of Geomorphology. Reinhold Book Corporation, New York, p. 856.CrossRefGoogle Scholar
Brozović, N., Burbank, D.W., Meigs, A.J., 1997. Climatic limits on landscape development in the northwestern Himalaya. Science 276, 571574.CrossRefGoogle Scholar
Brunnschweiler, D.H., 1965. The Morphology of Altiplanation in Interior Alaska. Unpublished report to the U.S. Army Cold Regions Research and Engineering Laboratory, Hanover, NH.Google Scholar
Cairnes, D.D., 1912. Differential erosion and equiplanation in portions of Yukon and Alaska. Bulletin of the Geological Society of America 23, 333348.CrossRefGoogle Scholar
Cockburn, H.A., Summerfield, M.A., 2004. Geomorphological applications of cosmogenic isotope analysis. Progress in Physical Geography 28, 142.CrossRefGoogle Scholar
Darvill, C.M., 2013. Cosmogenic nuclide analysis. In: Clark, L.E., Nield, J.M. (Eds.), Geomorphological Techniques. British Society for Geomorphology, London, pp. 125.Google Scholar
Davis, W.M., 1909. Geographical Essays. Ginn and Company, Boston.Google Scholar
Demek, J., 1969. Cryoplanation terraces, their geographical distribution, genesis and development. Rozpravy CÆeskoslovenské Akademie veÆd, RÆada matematickych a pírodních veÆd, 79.Google Scholar
Eakin, H.M., 1916. The Yukon-Koyukuk region, Alaska. U.S. Geological Survey Bulletin 631.Google Scholar
Foster, H.L., 1967. Geology of the Mount Fairplay area, Alaska. US Government Printing Office, Washington D.C. 1241-B, pp. B1-B18.Google Scholar
Foster, H.L., 1992. Geologic map of the eastern Yukon-Tanana region, Alaska. U.S. Geological Survey, Open-File Report No. 92–313.CrossRefGoogle Scholar
Foster, H.L., Weber, F.R., Forbes, R.B., Brabb, E.E., 1973. Regional geology of the Yukon-Tanana Upland, Alaska. In: Pitcher, M. G. (Ed.), Arctic Geology: American Association of Petroleum Geologists, Memoir 19, 388395.Google Scholar
Frankel, K.L., Finkel, R.C., Owen, L.A. 2010. Terrestrial cosmogenic nuclide geochronology data reporting standards needed. Eos, Transactions American Geophysical Union, 91 31–32.Google Scholar
French, H.M., 2016. Do periglacial landscapes exist? A discussion of the upland landscapes of northern interior Yukon, Canada. Permafrost and Periglacial Processes 27, 219228.Google Scholar
Gosse, J.C., Phillips, P.M., 2001. Terrestrial in situ cosmogenic nuclides: theory and application. Quaternary Science Reviews 20, 14751560.CrossRefGoogle Scholar
Hales, T., Roering, J., 2009. A frost “buzzsaw” mechanism for erosion of the eastern Southern Alps, New Zealand. Geomorphology 107, 241253.CrossRefGoogle Scholar
Hall, A.M., Kleman, J., 2014. Glacial and periglacial buzzsaws: fitting mechanisms to metaphors. Quaternary Research 81, 189192.CrossRefGoogle Scholar
Hall, K. 1993. Rock moisture data from Livingston Island (Maritime Antarctic) and implications for weathering processes. Permafrost and Periglacial Processes 4, 245253.CrossRefGoogle Scholar
Hall, K. 1998. Nivation or cryoplanation: different terms, same features? Polar Geography 22, 116.CrossRefGoogle Scholar
Hall, K., André, M.F., 2010. Some further observations regarding “cryoplanation terraces” on Alexander Island. Antarctic Science 22, 175.CrossRefGoogle Scholar
Hansen, V.L., Dusel-Bacon, C., 1998. Structural and kinematic evolution of the Yukon-Tanana Upland tectonites, East-Central Alaska: A record of Late Paleozoic to Mesozoic crustal assembly. Geological Society of America Bulletin 110, 211230.2.3.CO;2>CrossRefGoogle Scholar
Heyman, J., Stroeven, A.P., Harbor, J.M., Caffee, M.W., 2011. Too young or too old: evaluating cosmogenic exposure dating based on an analysis of compiled boulder exposure ages. Earth and Planetary Science Letters 302, 7180.CrossRefGoogle Scholar
Ivy–Ochs, S., Kerschner, H., Schlüchter, C., 2007. Cosmogenic nuclides and the dating of late glacial and early Holocene glacier variations: the alpine perspective. Quaternary International 164, 5363.Google Scholar
Kaufman, D.S., Manley, W.F., 2004. Pleistocene maximum and late Wisconsin glacier extents across Alaska, USA. In: Ehlers, J., Gibbard, P.L. (Eds.) Quaternary Glaciations – Extent and Chronology, Part II: North America. Elsevier, Amsterdam, pp. 927 (Developments in Quaternary Science 2B).CrossRefGoogle Scholar
Kaufman, D.S., Young, N.E., Briner, J.P., Manley, W.F., 2011. Alaska paleo-glacier atlas (Version 2). In: Ehlers, J., Gibbard, P.L., Hughes, P.D. (Eds.), Quaternary Glaciations—Extent and Chronology: A Closer Look. Elsevier, Amsterdam, pp. 427-445 (Developments in Quaternary Science 15).CrossRefGoogle Scholar
Kňažková, M., Nývlt, D., Hrbáček, F., 2018. Quantification of Holocene nivation rates on deglaciation surfaces of James Ross Island, Antarctica. In: 5th European Conference on Permafrost, June 23rd–July 1st, 2018, Chamonix, France, pp. 519520.Google Scholar
Kohl, C.P., Nishiizumi, K., 1992. Chemical isolation of quartz for measurement of in-situ–produced cosmogenic nuclides. Geochimica et Cosmochimica Acta 56, 35833587.CrossRefGoogle Scholar
Lal, D., 1991. Cosmic ray labeling of erosion surfaces: in situ nuclide production rates and erosion models. Earth and Planetary Science Letters 104, 424439.CrossRefGoogle Scholar
Lifton, N., Sato, T., Dunai, T.J., 2014. Scaling in situ cosmogenic nuclide production rates using analytical approximations to atmospheric cosmic-ray fluxes. Earth and Planetary Science Letters 386, 149160.Google Scholar
Lisiecki, L.E., Raymo, M.E., 2005. A Pliocene-Pleistocene stack of 57 globally distributed benthic δ18O records. Paleoceanography 20, PA1003.Google Scholar
Marrero, S.M., Phillips, F.M., Borchers, B., Lifton, N., Aumer, R., Balco, G., 2016. Cosmogenic nuclide systematics and the CRONUScalc program. Quaternary Geochronology 31, 160-187.CrossRefGoogle Scholar
Martin, L.C.P., Blard, P-H., Balco, G., Lavé, J., Delunel, R., Lifton, N., Laurent, V., 2017. The CREp program and the ICE-D production rate calibration database: A fully parameterizable and updated online tool to compute cosmic-ray exposure ages. Quaternary Geochronology 38, 2549.CrossRefGoogle Scholar
Matthes, F.E., 1900. Glacial sculpture of the Bighorn Mountains, Wyoming. U.S. Geological Survey 21st Annual Report, 1899–1900, pp. 167–190.Google Scholar
Matthews, J.A., Wilson, R., Winkler, S., Mourne, R.W., Hill, J.L., Owen, G., Geary, A.P., 2019. Age and development of active cryoplanation terraces in the alpine permafrost zone at Svartkmpan, Jotunheimen, southern Norway. Quaternary Research 92, 641664.CrossRefGoogle Scholar
Mertie, J.B., 1937. The Yukon-Tanana region, Alaska. U.S. Geological Survey Bulletin 872.Google Scholar
Moffit, F.H., 1905. The Fairhaven gold placers, Seward Peninsula, Alaska. U.S. Geological Survey Bulletin 247.Google Scholar
Mortensen, J.K., 1992. Pre-mid-Mesozoic tectonic evolution of the Yukon-Tanana Terrane, Yukon and Alaska. Tectonics 11, 836853.CrossRefGoogle Scholar
Nelson, F.E., 1989. Cryoplanation terraces: periglacial cirque analogs. Geografiska Annaler: Series, Physical Geography 71, 3141.Google Scholar
Nelson, F.E., 1998. Cryoplanation terrace orientation in Alaska. Geografiska Annaler: Series A, Physical Geography 80, 135151.Google Scholar
Nelson, F.E., Nyland, K.E., 2017. Periglacial cirque analogs: elevation trends of cryoplanation terraces in eastern Beringia. Geomorphology 293, 305317.Google Scholar
Nishiizumi, K., Imamura, M., Caffee, M.W., Southon, J.R., Finkel, R.C., Mcaninch, J., 2007. Absolute calibration of 10Be AMS standards. Nuclear Instruments and Methods in Physics Research Section B: Beam Interactions with Materials and Atoms 258, 403413.CrossRefGoogle Scholar
Nyland, K.E., Nelson, F.E., 2019. Time-transgressive cryoplanation terrace development through nivation-driven scarp retreat. Earth Surface Processes and Landforms, DOI: 10.1002/esp.4751.Google Scholar
Péwé, T.L., 1975. Quaternary Geology of Alaska. US Geological Survey Professional Paper No. 835. Washington, DC.CrossRefGoogle Scholar
Péwé, T.L., Burbank, L., Mayo, L.R., 1967. Multiple Glaciation of the Yukon-Tanana Upland, Alaska. U.S. Geological Survey Miscellaneous Geological Investigations, Map I-507.Google Scholar
Péwé, T.L., Reger, R.D., 1972. Modern and Wisconsinan snowlines in Alaska. Proceedings of the 24th International Geological Congress 12, 187197.Google Scholar
Porter, C., Morin, P., Howat, I., Noh, M. J., Bates, B., Peterman, K., Keesey, S. et al. . 2018. “ArcticDEM”, https://doi.org/10.7910/DVN/OHHUKH, Harvard Dataverse, V1.0, [December 15th, 2018].CrossRefGoogle Scholar
Prieznitz, K., 1988. Cryoplanation. In: Clark, M.J. (Ed.), Advances in Periglacial Geomorphology, John Wiley and Sons Ltd. Chichester, UK, pp. 4967.Google Scholar
Prindle, L.M., 1905. The gold placers of the Fortymile, Birch Creek, and Fairbanks regions, Alaska. U.S. Geological Survey Bulletin 251.Google Scholar
Prindle, L.M., 1913. A geological reconnaissance of the Circle quadrangle, Alaska. U.S. Geological Survey Bulletin 538.Google Scholar
Queen, C.W., 2018. Large-Scale Mapping and Geomorphometry of Upland Periglacial Landscapes in Eastern Beringia. Master's thesis, Michigan State University, East Lansing, MI.Google Scholar
Reger, R.D., 1975. Cryoplanation Terraces of Interior and Western Alaska. PhD dissertation, Arizona State University, Tempe, AZ.Google Scholar
Reger, R.D., Péwé, T.L., 1976. Cryoplanation terraces: indicators of a permafrost environment. Quaternary Research 6, 99109.CrossRefGoogle Scholar
Schaetzl, R.J., Thompson, M.L., 2015. Soils: Genesis and Geomorphology. New York: Cambridge University Press, New York.Google Scholar
Stone, J.O., 2000. Air pressure and cosmogenic isotope production. Journal of Geophysical Research: Solid Earth 105, 23, 753–23,759.CrossRefGoogle Scholar
Stone, J.O., Allan, G.L., Fifield, L.K., Cresswell, R.G., 1996. Cosmogenic Chlorine-36 from Calcium spallation. Geochimica et Cosmochimica Acta 60, 679692.CrossRefGoogle Scholar
Thorn, C.E., 1976. Quantitative evaluation of nivation in the Colorado Front Range. Geological Society of America Bulletin 87, 11691178.2.0.CO;2>CrossRefGoogle Scholar
Thorn, C.E. 1983. Seasonal snowpack variability and alpine periglacial geomorphology. Polarforschung 53, 3135.Google Scholar
Thorn, C.E., Hall, K., 1980. Nivation: an arctic-alpine comparison and reappraisal. Journal of Glaciology 25, 109–24.CrossRefGoogle Scholar
Thorn, C.E., Hall, K., 2002. Nivation and cryoplanation: the case for scrutiny and integration. Progress in Physical Geography 26, 533550.CrossRefGoogle Scholar
Wahrhaftig, C., 1965. Physiographic Divisions of Alaska. US Geological Survey Professional. Paper 482.CrossRefGoogle Scholar
Waters, R.S., 1962. Altiplanation terraces and slope development in Vest-Spitsbergen and southwest England. Biuletyn Peryglacjalny 11, 89101.Google Scholar
Weber, F.R., 1986. Glacial geology of the Yukon-Tanana Upland. In: Hamilton, T.D., Reed, K.M., Thorson, R.M. (Eds.), Glaciation in Alaska—The Geologic Record. Alaska Geological Society, Anchorage, AK.Google Scholar
Wiltse, M.A., Reger, R.D., Newberry, R.J., Pessel, G.H., Pinney, D.S., Robinson, M.S., Solie, D.N., 1995a. Geologic Map of the Circle Mining District, Alaska. Alaska Division of Geological and Geophysical Surveys Report of Investigation 95-2a.Google Scholar
Wiltse, M.A., Reger, R.D., Newberry, R.J., Pessel, G.H., Pinney, D.S., Robinson, M.S., Solie, D.N., 1995b. Bedrock Geologic Map of the Circle Mining District, Alaska. Alaska Division of Geological and Geophysical Surveys Report of Investigation 95-2b.Google Scholar
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