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Climate and material controls on periglacial soil processes: Toward improving periglacial climate indicators

Published online by Cambridge University Press:  20 January 2017

Norikazu Matsuoka*
Affiliation:
Graduate School of Life and Environmental Sciences, University of Tsukuba, Tsukuba 305-8572, Japan
*
E-mail address:[email protected]

Abstract

One of the distinguished efforts of A.L. Washburn was to reconstruct mean annual air temperature using periglacial features as climate indicators. This paper reviews existing periglacial indicators and proposes a strategy to improve their thermal resolution based on recent periglacial process studies, with a focus on solifluction and thermal contraction cracking and associated landforms/structures. Landforms resulting from solifluction reflect both the depth subjected to freeze–thaw and the thickness of frost-susceptible soils. The thickness of a solifluction structure can be used to infer the dominant freeze–thaw regime and minimum seasonal frost depth. Ice-wedge pseudomorphs have limited potential as a climate indicator because (1) they mainly reflect extreme winter temperatures, (2) their thermal thresholds depend on the host material, and (3) they need to be distinguished from frost wedges of other origin produced under different thermal and/or material conditions. Monitoring studies of currently active ice wedges suggest that ice-wedge cracking requires a combination of low temperature and large temperature gradients in the frozen active layer. Further field monitoring of periglacial processes and their controlling factors under various climate conditions and in various materials are needed, however, to improve the resolution of periglacial paleoclimate indicators.

Type
Research Article
Copyright
University of Washington

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References

Åkerman, H.J. Slow mass movements and climatic relationships, 1972–1994, Kapp Linné, West Spitsbergen. Anderson, M.G., Brooks, S.M. Advances in Hillslope Processes 2, (1996). Wiley, Chichester. 12191256.Google Scholar
Allard, M., and Kasper, J.N. Temperature conditions for ice wedge cracking: field measurements from Salluit, northern Québec. Lewkowicz, A.G., and Allard, M. Proceedings of Seventh International Conference on Permafrost. (1998). Centre d'études nordiques, Université Laval, Collection Nordicana, 57, Sainte-Foy. 511.Google Scholar
Anderson, R. Modeling the tor-dotted crests, bedrock edges, and parabolic profiles of high alpine surfaces of the Wind River Range, Wyoming. Geomorphology 46, (2002). 3558.Google Scholar
Ballantyne, C.K., and Harris, C. The Periglaciation of Great Britain. (1994). Cambridge University Press, Cambridge.Google Scholar
Benedict, J.B. Frost creep and gelifluction features: a review. Quaternary Research 6, (1976). 5576.CrossRefGoogle Scholar
Bertran, P., Francou, B., and Texier, J.P. Stratified slope deposits: the stone-banked sheets and lobes model. Slaymaker, O. Steepland Geomorphology. (1995). Wiley, Chichester. 147169.Google Scholar
Black, R.F. Growth of patterned ground in Victoria Land, Antarctica. Permafrost: The North American Contribution to the Second International Conference, Yakutsk, USSR. (1973). National Academy of Sciences, Washington DC. 193203.Google Scholar
Black, R.F. Periglacial features indicative of permafrost: ice and soil wedges. Quaternary Research 6, (1976). 326.CrossRefGoogle Scholar
Bockheim, J.G., Kurz, M.D., Soule, S.A., and Burke, A. Genesis of active sand-filled polygons in lower and central Beacon Valley, Antarctica. Permafrost and Periglacial Processes 20, (2009). 235313.CrossRefGoogle Scholar
Boelhouwers, J., Holness, S., and Sumner, P. The maritime Subantarctic: a distinct periglacial environment. Geomorphology 52, (2003). 3955.CrossRefGoogle Scholar
Burn, C.R. Implications for palaeoenvironmental reconstruction of recent ice-wedge development at Mayo, Yukon Territory. Permafrost and Periglacial Processes 1, (1990). 314.Google Scholar
Cheng, G. The mechanism of repeated segregation for the formation of thick-layered ground ice. Cold Regions Science and Technology 8, (1983). 5766.Google Scholar
Christiansen, H.H. Thermal regime of ice-wedge cracking in Adventdalen, Svalbard. Permafrost and Periglacial Processes 16, (2005). 8798.Google Scholar
Christiansen, H.H., Matsuoka, N., and Watanabe, T. Ice-wedge process research in Adventdalen. Berthling, I. Fieldguide for Excursions EUCOP III Svalbard, Norway 13–17 June 2010. (2010). Geological Survey of Norway, Trondheim. 4462.Google Scholar
Fortier, D., and Allard, M. Frost-cracking conditions, Bylot Island, eastern Canadian Arctic archipelago. Permafrost and Periglacial Processes 16, (2005). 145161.Google Scholar
Francou, B. Stratification mechanisms in slope deposits in high subequatorial mountains. Permafrost and Periglacial Processes 1, (1990). 249263.Google Scholar
Francou, B., Méhauté, N.L., and Jomelli, V. Factors controlling spacing distances of sorted stripes in a low-latitude, alpine environment (Cordillera Real, 16 °S, Bolivia). Permafrost and Periglacial Processes 12, (2001). 367377.Google Scholar
French, H.M. The Periglacial Environment. Third Edition (2007). Wiley, Chichester.Google Scholar
French, H.M. Recent contributions to the study of past permafrost. Permafrost and Periglacial Processes 19, (2008). 179194.Google Scholar
French, H.M., and Shur, Y. The principles of cryostratigraphy. Earth Science Reviews 101, (2010). 190206.Google Scholar
French, H.M., Demitroff, M., Forman, S.L., and Newell, W.R. A chronology of Late-Pleistocene permafrost events in Southern New Jersey, Eastern USA. Permafrost and Periglacial Processes 18, (2007). 4959.Google Scholar
Goehring, L., Sletten, R.S., and Hallet, B. Dynamics of polygonal terrain in the Dry Valleys, Antarctica. Eos, Transactions, AGU 89, 53 (2008). (Fall Meeting Supplement, Abstract C22A-08) Google Scholar
Grab, S. Characteristics and palaeoenvironmental significance of relict sorted patterned ground, Drakensberg plateau, southern Africa. Quaternary Science Reviews 21, (2002). 17291744.Google Scholar
Gruber, S., Hoelzle, M., and Haeberli, W. Permafrost thaw and destabilization of Alpine rock walls in the hot summer of 2003. Geophysical Research Letters 31, (2004). L13504 CrossRefGoogle Scholar
Haeberli, W. Permafrost–glacier relationships in the Swiss Alps today and in the past. Proceedings of the Fourth International Conference on Permafrost. (1983). National Academy Press, Washington D.C.. 415420.Google Scholar
Hales, T.C., and Roering, J.J. Climatic controls on frost cracking and implications for the evolution of bedrock landscapes. Journal of Geophysical Research 112, (2007). F02033 Google Scholar
Hallet, B. Measurement of soil motion in sorted circles, Western Spitsbergen. Lewkowicz, A.G., and Allard, M. Proceedings of Seventh International Conference on Permafrost. (1998). Centre d'études nordiques, Université Laval, Collection Nordicana, 57, Sainte-Foy. 415420.Google Scholar
Hallet, B., and Waddington, E.D. Buoyancy forces induced by freeze–thaw in the active layer: implications for diaprism and soil circulation. Dixon, J.C., and Abrahams, A.D. Periglacial Geomorphology. (1992). Wiley, Chichester. 251279.Google Scholar
Hallet, B., Walder, J.S., and Stubbs, C.W. Weathering by segregation ice growth in microcracks at sustained sub-zero temperatures: verification from an experimental study using acoustic emissions. Permafrost and Periglacial Processes 2, (1991). 283300.Google Scholar
Hamilton, T.D., Ager, T.A., and Robindon, S.V. Late Holocene ice wedges near Fairbanks, Alaska, U.S.A.: environmental setting and history of growth. Arctic and Alpine Research 15, (1983). 157168.Google Scholar
Harris, C. Periglacial Mass-Wasting: a Review of Research. BGRG Research Monograph 4, (1981). Geo Abstracts, Norwich.Google Scholar
Harris, S.A. Distribution of zonal permafrost landforms with freezing and thawing indices. Biuletyn Peryglacjalny 29, (1982). 163182.Google Scholar
Harris, S.A. Climatic zonality of periglacial landforms in mountain areas. Arctic 47, (1994). 184192.Google Scholar
Harris, C., and Davies, M.C.R. Gelifluction: observations from large-scale laboratory simulations. Arctic and Alpine Research 32, (2000). 202207.Google Scholar
Harris, C., and Lewkowicz, A.G. Form and internal structure of active-layer detachment slides, Fosheim Peninsula, Ellesmere Island, N.W.T., Canada. Canadian Journal of Earth Sciences 30, (1993). 17081714.Google Scholar
Harris, C., and Murton, J.B. Experimental simulation of ice-wedge casting processes, products and palaeoenvironmental significance. Harris, C., and Murton, J.B. Cryospheric Systems: Glaciers and Permafrost. Geological Society of London, Special Publication 242, (2005). 131143.CrossRefGoogle Scholar
Harris, C., Gallop, M., and Coutard, J.-P. Physical modelling of gelifluction and frost creep: some results of a large-scale laboratory experiment. Earth Surface Processes and Landforms 18, (1993). 383398.Google Scholar
Harris, C., Kern-Luetschg, M.A., Smith, F.W., and Isaksen, K. Solifluction processes in an area of seasonal ground freezing, Dovrefjell, Norway. Permafrost and Periglacial Processes 19, (2008). 3147.CrossRefGoogle Scholar
Harris, C., Smith, J.S., Davies, M.C.R., and Rea, B. An investigation of periglacial slope stability in relation to soil properties based on physical modelling in the Geotechnical centrifuge. Geomorphology 93, (2008). 437459.Google Scholar
Harris, C., Kern-Luetschg, M., Murton, J., Font, M., Davies, M., and Smith, F. Solifluction processes on permafrost and non-permafrost slopes: results of a large scale laboratory simulation. Permafrost and Periglacial Processes 19, (2008). 359378.Google Scholar
Harry, D.G., and Gozdzik, J.S. Ice wedges: growth, thaw transformation and palaeoenvironmental significance. Journal of Quaternary Science 3, (1988). 3955.Google Scholar
Hirakawa, K. Downslope movement of solifluction lobes in Iceland: a tephrostratigraphic approach. Geographical Reports of Tokyo Metropolitan University 24, (1989). 1530.Google Scholar
Hjort, J., Luoto, M., and Seppälä, M. Landscape scale determinants of periglacial features in subarctic Finland: a grid-based modelling approach. Permafrost and Periglacial Processes 18, (2007). 115127.Google Scholar
Huijzer, A.S., and Isarin, R.F.B. The reconstruction of past climates using multi-proxy evidence: an example of the Weichselian pleniglacial in northwest and central Europe. Quaternary Science Reviews 16, (1997). 513533.Google Scholar
Ikeda, A., Matsuoka, N., and Kääb, A. Fast deformation of perennially frozen debris in a warm rock-glacier in the Swiss Alps: an effect of liquid water. Journal of Geophysical Research 113, (2008). F01021 CrossRefGoogle Scholar
Jaesche, P., Huwe, B., Stingl, H., and Veit, H. Temporal variability of alpine solifluction: a modelling approach. Geographica Helvetica 57, (2002). 157169.Google Scholar
Jaesche, P., Veit, H., and Huwe, B. Snow cover and soil moisture controls on solifluction in an area of seasonal frost, eastern Alps. Permafrost and Periglacial Processes 14, (2003). 399410.Google Scholar
Karte, J. Periglacial phenomena and their significance as climatic and edaphic indicators. GeoJournal 7, (1983). 329340.Google Scholar
Kasse, C., Vandenberghe, J., Van Huissteden, J., Bohncke, S.J.P.J., and Bos, A.A. Sensitivity of Weichselian fluvial systems to climate change (Nochten mine, eastern Germany). Quaternary Science Reviews 22, (2003). 21412156.Google Scholar
Kessler, M.A., and Werner, B.T. Self-organization of sorted patterned ground. Science 299, (2003). 380383.Google Scholar
Kinnard, C., and Lewkowicz, A.G. Movement, moisture and thermal conditions at a turf-banked solifluction lobe, Kluane Range, Yukon Territory, Canada. Permafrost and Periglacial Processes 16, (2005). 261275.Google Scholar
Kinnard, C., and Lewkowicz, A.G. Frontal advance of turf-banked solifluction lobes, Kluane Range, Yukon Territory, Canada. Geomorphology 73, (2006). 261276.Google Scholar
Kirkbride, M.P., and Dugmore, A.J. Late Holocene solifluction history reconstructed using tephrochronology. Harris, C., and Murton, J.B. Cryospheric Systems: Glaciers and Permafrost. Geological Society, London, Special Publications 242, (2005). 145155.Google Scholar
Lachenbruch, A.H. Mechanics of thermal contraction cracks and ice-wedge polygons in permafrost. Geological Society of America Special Paper 70, (1962). 169.Google Scholar
Levy, J.S., Head, J.W., and Marchant, D.R. Thermal contraction crack polygons on Mars: classification, distribution, and climate implications from HiRISE observations. Journal of Geophysical Research 114, (2009). E01007 Google Scholar
Lewkowicz, A.G. Slope processes. Clark, M.J. Advances in Periglacial Geomorphology. (1988). Wiley, Chichester. 325368.Google Scholar
Lewkowicz, A.G., and Clarke, S. Late-summer solifluction and active layer depths, Fosheim Peninsula, Ellesmere Island, Canada. Lewkowicz, A.G., and Allard, M. Proceedings of Seventh International Conference on Permafrost. (1998). Centre d'études nordiques, Université Laval, Collection Nordicana 57, Sainte-Foy. 641666.Google Scholar
Lewkowicz, A.G., and Harris, C. Morphology and geotechnique of active-layer detachment failures in discontinuous and continuous permafrost, northern Canada. Geomorphology 69, (2005). 275297.Google Scholar
Mackay, J.R. Active layer slope movement in a continuous permafrost environment, Garry Island, Northwest Territories, Canada. Canadian Journal of Earth Sciences 18, (1981). 16661680.CrossRefGoogle Scholar
Mackay, J.R. The first 7 years (1978–1985) of ice wedge growth, Illisarvik experimental drained lake site, western Arctic coast. Canadian Journal of Earth Sciences 23, (1986). 17821795.Google Scholar
Mackay, J.R. The frequency of ice-wedge cracking (1967–1987) at Garry Island, western Arctic coast, Canada. Canadian Journal of Earth Sciences 29, (1992). 236248.Google Scholar
Mackay, J.R. Air temperature, snow cover, creep of frozen ground, and the time of ice-wedge cracking, western Arctic coast. Canadian Journal of Earth Sciences 30, (1993). 17201729.CrossRefGoogle Scholar
Mackay, J.R. Thermally induced movements in ice-wedge polygons, western Arctic coast: a long-term study. Géographie Physique et Quaternaire 54, (2000). 4168.Google Scholar
Mackay, J.R., and Burn, C.R. The first 20 years (1978–1979 to 1998–1999) of ice-wedge growth at the Illisarvik experimental drained lake site, western Arctic coast, Canada. Canadian Journal of Earth Sciences 39, (2002). 95111.Google Scholar
Matsumoto, H. Relationship between ground ice and solifluction: field measurements in the Daisetsu Mountains, Northern Japan. Permafrost and Periglacial Processes 21, (2010). 7889.Google Scholar
Matsuoka, N. Mechanisms of rock breakdown by frost action: an experimental approach. Cold Regions Science and Technology 17, (1990). 253270.CrossRefGoogle Scholar
Matsuoka, N. Modelling frost creep rates in an alpine environment. Permafrost and Periglacial Processes 9, (1998). 397409.3.0.CO;2-Q>CrossRefGoogle Scholar
Matsuoka, N. Monitoring of thermal contraction cracking at an ice wedge site, central Spitsbergen. Polar Geoscience 12, (1999). 258271.Google Scholar
Matsuoka, N. Direct observation of frost wedging in alpine bedrock. Earth Surface Processes and Landforms 26, (2001). 601614.Google Scholar
Matsuoka, N. Solifluction rates, processes and landforms: a global review. Earth-Science Reviews 55, (2001). 107133.Google Scholar
Matsuoka, N. Temporal and spatial variations in periglacial soil movements on alpine crest slopes. Earth Surface Processes and Landforms 30, (2005). 4158.Google Scholar
Matsuoka, N. Solifluction and mudflow on a limestone periglacial slope in the Swiss Alps: 14 years of monitoring. Permafrost and Periglacial Processes 21, (2010). 219240.Google Scholar
Matsuoka, N., and Christiansen, H.H. Ice-wedge polygon dynamics in Svalbard: high resolution monitoring by multiple techniques. Kane, D.L., and Hinkel, K.M. Ninth International Conference on Permafrost 2. (2008). Institute of Northern Engineering, University of Alaska Fairbanks, Fairbanks. 11491154.Google Scholar
Matsuoka, N., and Hirakawa, K. Solifluction resulting from one-sided and two-sided freezing: field data from Svalbard. Polar Geoscience 13, (2000). 187201.Google Scholar
Matsuoka, N., Hirakawa, K., Watanabe, T., and Moriwaki, K. Monitoring of periglacial slope processes in the Swiss Alps: the first two years of frost shattering, heave and creep. Permafrost and Periglacial Processes 8, (1997). 155177.Google Scholar
Matthews, J.A. Radiocarbon dating of buried soils with particular reference to Holocene solifluction. Frenzel, B. Solifluction and Climatic Variation in the Holocene. (1993). Gustav Fisher Verlag, Stuttgart. 309324.Google Scholar
Matthews, J.A., and Berrisford, M.S. Climatic controls on rates of solifluction: variation within Europe. Frenzel, B. Solifluction and Climatic Variation in the Holocene. (1993). Gustav Fisher Verlag, Stuttgart. 363382.Google Scholar
Matthews, J.A., Seppälä, M., and Dresser, P.Q. Holocene solifluction, climate variation and fire in a subarctic landscape at Pippokangas, Finnish Lapland, based on radiocarbon-dated buried charcoal. Journal of Quaternary Science 20, (2005). 533548.CrossRefGoogle Scholar
Mellon, M. Small-scale polygonal features on Mars: seasonal thermal contraction cracks in permafrost. Journal of Geophysical Research 102, E11 (1997). 2561725628.Google Scholar
Mellon, M.T., Arvidson, R.E., Sizemore, H.G., Searls, M.L., Blaney, D.L., Cull, S., Hecht, M.H., Heet, T.L., Keller, H.U., Lemmon, M.T., Markiewicz, W.J., Ming, D.W., Morris, R.V., Pike, W.T., and Zent, A.P. Ground ice at the Phoenix landing site: stability state and origin. Journal of Geophysical Research 114, (2009). E00E07 Google Scholar
Millar, S.W.S. Processes dominating macro-fabric generation in periglacial colluvium. Catena 67, (2006). 7987.Google Scholar
Murton, J.B. Ice wedges and ice-wedge casts. Elias, S.A. Encyclopedia of Quaternary Science 2, (2007). Elsevier, Amsterdam. 21532170.Google Scholar
Murton, J.B., and French, H.M. Thermokarst involutions, Summer Island, Pleistocene Mackenzie Delta, western Canadian Arctic. Permafrost and Periglacial Processes 4, (1993). 217229.Google Scholar
Murton, J.B., and Kolstrup, E. Ice-wedge casts as indicators of palaeotemperatures: precise proxy or wishful thinking?. Progress in Physical Geography 27, (2003). 155170.Google Scholar
Murton, J.B., Worsley, P., and Gozdzik, J. Sand veins and wedges in cold aeolian environments. Quaternary Science Reviews 19, (2000). 899922.Google Scholar
Murton, J.B., Coutard, J.-P., Lautridou, J.-P., Ozouf, J.-C., Robinson, D.A., and Williams, R.B.G. Physical modelling of bedrock brecciation by ice segregation in permafrost. Permafrost and Periglacial Processes 12, (2001). 255266.Google Scholar
Murton, J.B., Bateman, M.D., Baker, C.A., Knox, R., and Whiteman, C.A. The Devensian periglacial record on Thanet, Kent, UK. Permafrost and Periglacial Processes 14, (2003). 217246.Google Scholar
Ogino, Y., and Matsuoka, N. Involutions resulting from annual freeze–thaw cycles: a laboratory simulation based on observations in northeastern Japan. Permafrost and Periglacial Processes 18, (2007). 323335.Google Scholar
Oliva, M., Schulte, L., and Gómez Ortiz, A. Morphometry and Late Holocene activity of solifluction landforms in the Sierra Nevada, southern Spain. Permafrost and Periglacial Processes 20, (2009). 369382.Google Scholar
Péwé, T.L. Sand-wedge polygons (tessellations) in the McMurdo Sound region, Antarctica: a progress report. American Journal of Science 257, (1959). 545552.Google Scholar
Péwé, T.L. Paleoclimatic significance of fossil ice wedges. Biuletyn Peryglacjalny 15, (1966). 6573.Google Scholar
Renssen, H., and Vandenberghe, J. Investigation of the relationship between permafrost distribution in NW Europe and extensive sea-ice cover in the North Atlantic Ocean during the cold phases of the Last Glaciation. Quaternary Science Reviews 22, (2003). 209223.Google Scholar
Ridefelt, H., and Boelhouwers, J. Observations on regional variations in solifluction landform morphology and environment in the Abisko region, northern Sweden. Permafrost and Periglacial Processes 17, (2006). 253266.Google Scholar
Ridefelt, H., Etzelmüller, B., and Boelhouwers, J. Spatial analysis of solifluction landforms and process rates in the Abisko Mountains, northern Sweden. Permafrost and Periglacial Processes 21, (2010). 241255.Google Scholar
Romanovskij, N.N. Regularities in formation of frost-fissures and development of frost-fissure polygons. Biuletyn Peryglacjalny 23, (1973). 237277.Google Scholar
Shiklomanov, N.I., and Nelson, F. Active layer processes. Elias, S.A. Encyclopedia of Quaternary Science 2, (2007). Elsevier, Amsterdam. 21382147.Google Scholar
Sletten, R.S., and Hallet, B. Contraction crack dynamics in polygonal patterned ground and soil inflation in the Dry Valleys, Antarctica. Eighth International Conference on Permafrost Extended Abstracts, Reporting Current Research and Newly Available Information. (2003). 151152.Google Scholar
Sletten, R.S., Hallet, B., and Fletcher, R.C. Resurfacing time of terrestrial surfaces by the formation and maturation of polygonal patterned ground. Journal of Geophysical Research 108, E4 (2003). 8044 Google Scholar
Smith, D.J. Long-term rates of contemporary solifluction in the Canadian Rocky Mountains. Dixon, J.C., and Abrahams, A.D. Periglacial Geomorphology. (1992). Wiley, Chichester. 203221.Google Scholar
Smith, D.J. Solifluction and climate in the Holocene: a North American perspective. Frenzel, B. Solifluction and Climatic Variation in the Holocene. (1993). Gustav Fisher Verlag, Stuttgart. 123141.Google Scholar
Van Huissteden, K., Vandenberghe, J., and Pollard, D. Palaeotemperature reconstructions of the European permafrost zone during marine oxygen isotope Stage 3 compared with climate model results. Journal of Quaternary Science 18, (2003). 453464.Google Scholar
Van Steijn, H., Bertran, P., Francou, B., Hétu, B., and Texier, J.P. Models for the genetic and environmental interpretations of stratified slope deposits: review. Permafrost and Periglacial Processes 6, (1995). 125146.CrossRefGoogle Scholar
Vieira, G.T., Mora, C., and Ramos, M. Ground temperature regimes and geomorphological implications in a Mediterranean mountain (Serra da Estrela, Portugal). Geomorphology 52, (2003). 5772.Google Scholar
Walder, J.S., and Hallet, B. A theoretical model of the fracture of rock during freezing. Geological Society of America Bulletin 96, (1985). 336346.2.0.CO;2>CrossRefGoogle Scholar
Washburn, A.L. Instrumental observations of mass-wasting in the Mesters Vig district, Northeast Greenland. Meddelelser om Grønland 166, 4 (1967). (318 pp.)Google Scholar
Washburn, A.L. Geocryology: a Survey of Periglacial Processes and Environments. (1979). Edward Arnold, London.Google Scholar
Washburn, A.L. Permafrost features as evidence of climatic change. Earth Science Reviews 15, (1980). 327402.Google Scholar
Werner, B.T., and Hallet, B. Numerical simulation of self-organized stone stripes. Nature 361, (1993). 142145.Google Scholar
Williams, P.J., and Smith, M.W. The Frozen Earth: Fundamentals of Geocryology. (1989). Cambridge University Press, Cambridge.Google Scholar