Hostname: page-component-586b7cd67f-2plfb Total loading time: 0 Render date: 2024-11-20T06:25:49.499Z Has data issue: false hasContentIssue false

Post-glacial landscape response to climate variability in the southeastern San Juan Mountains of Colorado, USA

Published online by Cambridge University Press:  20 January 2017

Bradley G. Johnson*
Affiliation:
Environmental Studies Program, Davidson College, Box 7056, Davidson, NC 28035-7056, USA
Martha Cary Eppes
Affiliation:
Department of Geography and Earth Sciences, University of North Carolina Charlotte, McEniry 324, 9201 University City Blvd, Charlotte, NC 28223–0001, USA
John A. Diemer
Affiliation:
Department of Geography and Earth Sciences, University of North Carolina Charlotte, McEniry 324, 9201 University City Blvd, Charlotte, NC 28223–0001, USA
Gonzalo Jiménez-Moreno
Affiliation:
Departamento de Estratigrafía y Paleontología, Facultad de Ciencias, Universidad de Granada, Avda. Fuente Nueva S/N, 18002 Granada, Spain
Anthony L. Layzell
Affiliation:
Department of Geography, University of Kansas, Lawrence, KS 66045, USA
*
Corresponding author. E-mail address:[email protected] (B. G. Johnson).

Abstract

Geomorphic mapping in the upper Conejos River Valley of the San Juan Mountains has shown that three distinct periods of aggradation have occurred since the end of the last glacial maximum (LGM). The first occurred during the Pleistocene–Holocene transition (~ 12.5–9.5 ka) and is interpreted as paraglacial landscape response to deglaciation after the LGM. Evidence of the second period of aggradation is limited but indicates a small pulse of sedimentation at ~ 5.5 ka. A third, more broadly identifiable period of sedimentation occurred in the late Holocene (~ 2.2–1 ka). The latest two periods of aggradation are concurrent with increases in the frequency of climate change in the region suggesting that Holocene alpine and sub-alpine landscapes respond more to rapid changes in climate than to large singular climatic swings. Soil development and radiocarbon dating indicate that hillslopes were stable during the Holocene even while aggradation was occurring in valley bottoms. Thus, we can conclude that erosion does not occur equally throughout the landscape but is focused upslope of headwater streams, along tributary channels, or on ridge tops. This is in contrast to some models which assume equal erosion in headwater basins.

Type
Research Article
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

Adams, D.K., and Comrie, A.C. The North American monsoon. Bulletin of the American Meteorological Society 78, (1997). 2197 2.0.CO;2>CrossRefGoogle Scholar
Alexander, E.B. Extractable iron in relation to soil age on terraces along the Truckee River, Nevada. Soil Science Society of America Proceedings 38, (1974). 121124.CrossRefGoogle Scholar
Andrews, J.T., Carrara, P.E., King, F.B., and Stuckenrath, R. Holocene environmental changes in the alpine zone, northern San Juan Mountains, Colorado: Evidence from bog stratigraphy and palynology. Quaternary Research 5, (1975). 173197.CrossRefGoogle Scholar
Atwood, W.W., and Mather, K.F. Physiography and quaternary geology of the San Juan Mountains, Colorado. U.S. Geological Survey Professional Paper vol. 166, (1932). 176 Google Scholar
Bacon, S.N., McDonald, E.V., Caldwell, T.G., and Dalldorf, G.K. Timing and distribution of alluvial fan sedimentation in response to strengthening of late Holocene ENSO variability in the Sonoran Desert, southwestern Arizona, USA. Quaternary Research 73, (2010). 425438.CrossRefGoogle Scholar
Ballantyne, C.K. Paraglacial geomorphology. Quaternary Science Reviews 21, (2002). 19352017.CrossRefGoogle Scholar
Benedict, J.B. Radiocarbon dates from a stone-banked terrace in the Colorado Rocky Mountains, U. S. A. Geografiska Annaler. Series A. Physical Geography 48, (1966). 2431.Google Scholar
Benedict, J.B. Downslope soil movement in a Colorado alpine region: rates, processes, and climatic significance. Arctic and Alpine Research 2, (1970). 165226.CrossRefGoogle Scholar
Benedict, J.B. Chronology of cirque glaciation, Colorado Front Range. Quaternary Research 3, (1973). 584600.CrossRefGoogle Scholar
Birkeland, P.W. Soils and Geomorphology. (1999). Oxford University Press, New York.Google Scholar
Carrara, P.E., Mode, W.N., and Rubin, M. Deglaciation and postglacial timberline in the San Juan Mountains, Colorado. Quaternary Research 21, (1984). 4255.CrossRefGoogle Scholar
Carrara, P.E., Trimble, D.A., and Rubin, M. Holocene treeline fluctuations in the northern San Juan Mountains, Colorado, U.S.A., as indicated by radiocarbon-dated conifer wood. Arctic and Alpine Research 23, (1991). 233246.CrossRefGoogle Scholar
Church, M., and Ryder, J.M. Paraglacial sedimentation: a consideration of fluvial processes conditioned by glaciation. Geological Society of America Bulletin 83, (1972). 30593072.CrossRefGoogle Scholar
Curry, A.M., and Morris, C.J. Lateglacial and Holocene talus slope development and rockwall retreat on Mynydd Du, UK. Geomorphology 58, (2004). 85106.CrossRefGoogle Scholar
Dixon, J.L., Heimsath, A.M., Kaste, J., and Amundson, R. Climate-driven processes of hillslope weathering. Geology 37, (2009). 975979.CrossRefGoogle Scholar
Faegri, K., and Iversen, J. Textbook of Pollen Analysis. (1989). Wiley, New York.Google Scholar
Feiler, E.J., Anderson, R.S., and Koehler, P.A. Late Quaternary paleoenvironments of the White River Plateau, Colorado, U.S.A. Arctic and Alpine Research 29, (1997). 5362.CrossRefGoogle Scholar
Guido, Z.S., Ward, D.J., and Anderson, R.S. Pacing the post–Last Glacial Maximum demise of the Animas Valley glacier and the San Juan Mountain ice cap, Colorado. Geology 35, (2007). 739742.CrossRefGoogle Scholar
Janke, J.R. The occurrence of alpine permafrost in the Front Range of Colorado. Geomorphology 67, (2005). 375389.CrossRefGoogle Scholar
Janke, J. Colorado Front Range rock glaciers: distribution and topographic characteristics. Arctic, Antarctic, and Alpine Research 39, (2007). 7483.CrossRefGoogle Scholar
Janke, J., and Frauenfelder, R. The relationship between rock glacier and contributing area parameters in the Front Range of Colorado. Journal of Quaternary Science 23, (2008). 153163.CrossRefGoogle Scholar
Jiménez-Moreno, G., Fawcett, P.J., and Scott Anderson, R. Millennial- and centennial-scale vegetation and climate changes during the late Pleistocene and Holocene from northern New Mexico (USA). Quaternary Science Reviews 27, (2008). 14421452.CrossRefGoogle Scholar
Johnson, B.G. Alpine and sub-alpine landscape response to post-glacial climate change in the San Juan Mountains: a comparison of new landscape and climate records. (2010). University of North Carolina — Charlotte, Google Scholar
Johnson, B.G., Eppes, M.C., and Diemer, J.A. Surficial geologic map of the upper Conejos River drainage, southeastern San Juan Mountains, southern Colorado. Journal of Maps v2010, (2010). 3039.CrossRefGoogle Scholar
Johnson, B.G., Thackray, G.D., and Van Kirk, R. The effect of topography, latitude, and lithology on rock glacier distribution in the Lemhi Range, central Idaho, USA. Geomorphology 91, (2007). 3850.CrossRefGoogle Scholar
Knox, J.C. Valley alluviation in southwestern Wisconsin. Annals of the Association of American Geographers 62, (1972). 401410.CrossRefGoogle Scholar
Layzell, A.L. Soils and Geomorphology of central Conejos River Valley: Fluvial Response to Post Last Glacial Maximum Climates and Sediment Supply. (2010). University of North Carolina — Charlotte, Google Scholar
Lipman, P.W. Geologic map of the Platoro Caldera area, southeastern San Juan Mountains, southwestern Colorado. Miscellaneous Investigations Series. (1974). Department of the Interior, United States Geological Survey, Google Scholar
Mann, D.H., and Meltzer, D.J. Millennial-scale dynamics of valley fills over the past 12,000 14 C yr in northeastern New Mexico, USA. Geological Society of America Bulletin 119, (2007). 14331448.CrossRefGoogle Scholar
Markgraf, V., and Scott, L. Lower timberline in central Colorado during the past 15,000 yr. Geology 9, (1981). 231243.2.0.CO;2>CrossRefGoogle Scholar
Marston, R.A. Geomorphology and vegetation on hillslopes: interactions, dependencies, and feedback loops. Geomorphology 116, (2010). 206217.CrossRefGoogle Scholar
Matsuoka, N., and Sakai, H. Rockfall activity from an alpine cliff during thawing periods. Geomorphology 28, (1999). 309328.CrossRefGoogle Scholar
McDonald, E.V., McFadden, L.D., Wells, S.G. Enzel, Y., Wells, S.G., and Lancaster, N. Regional Response of Alluvial Fans to the Pleistocene–Holocene Climatic Transition, Mojave Desert, California. Paleoenvironments and paleohydrology of the Mojave and southern Great Basin Deserts, Geological Society of America Special Paper (2003). Geological Society of America, Boulder, Colorado.CrossRefGoogle Scholar
McFadden, L.D., and Hendricks, D.M. Changes in the content and composition of pedogenic iron oxyhydroxides in a chronosequence of soils in southern California. Quaternary Research 23, (1985). 189204.CrossRefGoogle Scholar
McKeague, J.A., Brydon, J.E., and Miles, N.M. Differentiation of forms of extractable iron and aluminum in soils. Soil Science Society of America Journal 35, (1971). 3338.CrossRefGoogle Scholar
Miller, J., Germanoski, D., Waltman, K., Tausch, R., and Chambers, J. Influence of late Holocene hillslope processes and landforms on modern channel dynamics in upland watersheds of central Nevada. Geomorphology 38, (2001). 373391.CrossRefGoogle Scholar
Outcalt, S.I., and Benedict, J.B. Photo interpretation of two types of rock glaciers in the Colorado Front Range. Journal of Glaciology 5, (1965). 849856.CrossRefGoogle Scholar
Riebe, C.S., Kirchner, J.W., Granger, D.E., and Finkel, R.C. Minimal climatic control on erosion rates in the Sierra Nevada, California. Geology 29, (2001). 447450.2.0.CO;2>CrossRefGoogle Scholar
Rodbell, D.T., Seltzer, G.O., Anderson, D.M., Abbott, M.B., Enfield, D.B., and Newman, J.H. An 15,000-year record of El Niño-driven alluviation in southwestern Ecuador. Science 283, (1999). 516520.CrossRefGoogle ScholarPubMed
Roering, J.J., Kirchner, J.W., Sklar, L.S., and Dietrich, W.E. Hillslope evolution by nonlinear creep and landsliding: an experimental study. Geology 29, (2001). 143146.2.0.CO;2>CrossRefGoogle Scholar
Schoeneberger, P.J., Wysocki, D.A., Benham, E.C., and Broderson, W.D. Field Book for Describing and Sampling Soils: Version 2.0. (2002). Natural Resources Conservation Service, National Soil Survey Center, Lincoln, NE.Google Scholar
Vierling, L.A. Palynological evidence for late- and postglacial environmental change in central Colorado. Quaternary Research 49, (1998). 222232.CrossRefGoogle Scholar
von Blanckenburg, F. The control mechanisms of erosion and weathering at basin scale from cosmogenic nuclides in river sediment. Earth and Planetary Science Letters 237, (2005). 462479.CrossRefGoogle Scholar
Wells, S.G., McFadden, L.D., and Dohrenwend, J.C. Influence of late Quaternary climatic change on geomorphic and pedogenic processes on a desert piedmont, eastern Mojave Desert, California. Quaternary Research 27, (1987). 130146.CrossRefGoogle Scholar
White, S.E. Rock glacier studies in the Colorado Front Range, 1961 to 1968. Arctic and Alpine Research 3, (1971). 4364.CrossRefGoogle Scholar