Hostname: page-component-cd9895bd7-q99xh Total loading time: 0 Render date: 2024-12-23T04:57:46.210Z Has data issue: false hasContentIssue false

Glacial and periglacial buzzsaws: fitting mechanisms to metaphors

Published online by Cambridge University Press:  20 January 2017

Adrian M. Hall*
Affiliation:
School of Geography and GeoSciences, University of St Andrews, Irvine Building, North Street, St Andrews KY16 9AL, Fife, Scotland, UK
Johan Kleman
Affiliation:
Department of Physical Geography and Quaternary Geology, Stockholm University, S-10691 Stockholm, Sweden
*
*Corresponding author.

Abstract

The buzzsaw hypothesis refers to the potential for glacial and periglacial processes to rapidly denude mountains at and above glacier Equilibrium Line Altitudes (ELAs), irrespective of uplift rates, rock type or pre-existing topography. Here the appropriateness of the buzzsaw metaphor is examined alongside questions of the links between glacial erosion and ELAs, and whether the glacial system can produce low-relief surfaces or limit summit heights. Plateau fragments in mountains on both active orogens and passive margins that have been cited as products of glacial and periglacial buzzsaw erosion instead generally represent dissected remnants of largely inherited, pre-glacial relief. Summit heights may correlate with ELAs but no causal link need be implied as summit erosion rates are low, cirque headwalls may not directly abut summits and on passive margins, cirques are cut into pre-existing mountain topography. Any simple links between ELAs and glacial erosion break down on passive margins due to topographic forcing of ice-sheet growth, and to the km-scale vertical swaths through which ELAs have shifted through the Quaternary. Glaciers destroy rather than create low-relief rock surfaces through the innate tendency for ice flow to be faster, thicker and warmer along valleys. The glacial buzzsaw cuts down.

Type
Forum 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

Anderson, R.S. 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
Anderson, R. Teflon peaks: The evolution of high local relief in glaciated mountain ranges. AGU Fall Meeting Abstracts. (2005). 04 Google Scholar
Battiau-Queney, Y. Preservation of old palaeosurfaces in glaciated areas: examples from the French western Alps. Geological Society of London, Special Publication 120, (1997). 125132.Google Scholar
Bonow, J.M., Lidmar-Bergström, K., and Näslund, J.O. Palaeosurfaces and major valleys in the area of the Kjølen Mountains, southern Norway - consequences of uplift and climatic change. Norsk Geografisk Tidsskrift 57, (2003). 83101.Google Scholar
Briner, J.P., Miller, G.H., Davis, P.T., and Finkel, R.C. Cosmogenic radionuclides from fiord landscapes support differential erosion by overriding ice sheets. Geological Society of America Bulletin 118, (2006). 406420.Google Scholar
Brocklehurst, S.H., and Whipple, K.X. Hypsometry of glaciated landscapes. Earth Surface Processes and Landforms 29, (2004). 907926.Google Scholar
Brozović, N., Burbank, D., and Meigs, A. Glacial buzzsaws, topographic lightning rods and landscape development in the northwestern Himalaya and Karakoram. EOS 77, (1996). 252 Google Scholar
Brozović, N., Burbank, D.W., and Meigs, A.J. Climatic limits on landscape development in the northwestern Himalaya. Science 276, (1997). 571574.Google Scholar
Corbett, L.B., Bierman, P.R., Graly, J.A., Neumann, T.A., and Rood, D.H. Constraining landscape history and glacial erosivity using paired cosmogenic nuclides in Upernavik, northwest Greenland. Geological Society of America Bulletin (2013). http://dx.doi.org/10.1130/B30813.1Google Scholar
Daly, R.A. The accordance of summit levels among alpine mountains: the fact and its significance. Journal of Geology 13, (1905). 105125.Google Scholar
Dowdeswell, J.A., Ottesen, D., and Rise, L. Rates of sediment delivery from the Fennoscandian Ice Sheet through an ice age. Geology 38, (2010). 36.Google Scholar
Ebert, K., Hättestrand, C., Hall, A.M., and Alm, G. DEM identification of macro-scale stepped relief in arctic northern Sweden. Geomorphology 132, (2011). 339350.Google Scholar
Egholm, D., Nielsen, S., Pedersen, V.K., and Lesemann, J.E. Glacial effects limiting mountain height. Nature 460, (2009). 884887.Google Scholar
Evans, I.S. Allometric development of glacial cirque form: geological, relief and regional effects on the cirques of Wales. Geomorphology 80, (2006). 245266.Google Scholar
Evans, S., Mugnozza, G.S., Strom, A., Hermanns, R., Ischuk, A., and Vinnichenko, S. Landslides from massive rock slope failure and associated phenomena. Landslides from Massive Rock Slope Failure. (2006). Springer, 352.Google Scholar
Fjellanger, J., and Etzelmüller, B. Stepped palaeosurfaces in southern Norway - interpretation of DEM-derived topographic profiles. Norsk Geografisk Tidsskrift 57, (2003). 102110.Google Scholar
Fjellanger, J., Sorbel, L., Linge, H., Brook, E.J., Raisbeck, G.M., and Yiou, F. Glacial survival of blockfields on the Varanger Peninsula, northern Norway. Geomorphology 82, (2006). 255272.Google Scholar
Gjessing, J. Norway's Paleic Surface. Norsk Geografisk Tidsskrift 21, (1967). 69132.Google Scholar
Godard, A. Recherches en géomorphologie en Écosse du Nord-Ouest. (1965). Masson et Cie, Paris.Google Scholar
Goodfellow, B.W. A granulometry and secondary mineral fingerprint of chemical weathering in periglacial landscapes and its application to blockfield origins. Quaternary Science Reviews 57, (2012). 121135.Google Scholar
Hales, T.C., and Roering, J.J. Climate-controlled variations in scree production, Southern Alps, New Zealand. Geology 33, (2005). 701704.Google Scholar
Hales, T., and Roering, J. A frost “buzzsaw” mechanism for erosion of the eastern Southern Alps, New Zealand. Geomorphology 107, (2009). 241253.Google Scholar
Hall, A.M., and Glasser, N.F. Reconstructing former glacial basal thermal regimes in a landscape of selective linear erosion: Glen Avon, Cairngorm Mountains, Scotland. Boreas 32, (2003). 191207.Google Scholar
Hall, A.M., Ebert, K., and Hättestrand, C. Pre-glacial landform inheritance in a glaciated shield landscape. Geografiska Annaler Series A, Physical Geography 95, (2013). 3349.Google Scholar
Hall, A.M., Ebert, K., Kleman, J., Nesje, A., and Ottesen, D. Selective glacial erosion on the Norwegian passive margin. Geology (2013). http://dx.doi.org/10.1130/G34806.1Google Scholar
Hallet, B., and Roche, J. Rapid frost weathering and its potential role as a periglacial buzzsaw. EGU General Assembly Conference Abstracts. (2010). 13964 Google Scholar
Hallet, B., Zeitler, P.K., Koons, P.O., Finnegan, N.J., and Barker, A.D. Erosion rates at the crest of the Himalaya: slow or fast?. 25th Himalayan-Karakoram-Tibet Workshop, San Francisco. (2010). 2 Google Scholar
Haynes, V.M. The modification of valley patterns by ice sheet activity. Geografiska Annaler 59A, (1977). 195207.Google Scholar
Jamieson, S.S.R., Hulton, N.R.J., and Hagdorn, M. Modelling landscape evolution under ice sheets. Geomorphology 97, (2008). 91108.Google Scholar
Kessler, M.A., Anderson, R.S., and Stock, G.M. Modeling topographic and climatic control of east-west asymmetry in Sierra Nevada glacier length during the Last Glacial Maximum. Journal of Geophysical Research 111, (2006). F02002 Google Scholar
Kessler, M.A., Anderson, R.S., and Briner, J.P. Fjord insertion into continental margins driven by topographic steering of ice. Nature Geoscience 1, (2008). 365369.Google Scholar
Kleman, J. Geomorphology: where glaciers cut deep. Nature Geoscience 1, (2008). 343344.Google Scholar
Kleman, J., and Glasser, N.F. The subglacial thermal organisation (STO) of ice sheets. Quaternary Science Reviews 26, (2007). 585597.Google Scholar
Kleman, J., and Stroeven, A.P. Preglacial surface remnants and Quaternary glacial regimes in northwestern Sweden. Geomorphology 19, (1997). 3554.Google Scholar
Kleman, J., Stroeven, A.P., and Lundqvist, J. Patterns of Quaternary ice sheet erosion and deposition in Fennoscandia and a theoretical framework for explanation. Geomorphology 97, (2008). 7390.Google Scholar
Lidmar-Bergström, K., Näslund, J.-O., Ebert, K., Neubeck, T., and Bonow, J. Cenozoic landscape development on the passive margin of northern Scandinavia. Norwegian Journal of Geology 87, (2007). 181196.Google Scholar
Medvedev, S., Hartz, E.H., and Podladchikov, Y.Y. Vertical motions of the fjord regions of central East Greenland: impact of glacial erosion, deposition, and isostasy. Geology 36, (2008). 539542.Google Scholar
Mitchell, S.G., and Montgomery, D.R. Influence of a glacial buzzsaw on the height and morphology of the Cascade Range in central Washington State, USA. Quaternary Research 65, (2006). 96107.Google Scholar
Molnar, P., and England, P. Late Cenozoic uplift of mountain ranges and global climate change: chicken or egg?. Nature 346, (1990). 2934.Google Scholar
Montgomery, D.R. Valley incision and the uplift of mountain peaks. Journal of Geophysical Research 99, (1994). 1391313921.Google Scholar
Montgomery, D.R., Balco, G., and Willett, S.D. Climate, tectonics, and the morphology of the Andes. Geology 29, (2001). 579582.Google Scholar
Nesje, A., and Whillans, I.M. Erosion of Sognefjord, Norway. Geomorphology 9, (1994). 3345.Google Scholar
Nielsen, S.B., Gallagher, K., Leighton, C., Balling, N., Svenningsen, L., Jacobsen, B.H., Thomsen, E., Nielsen, O.B., Heilmann-Clausen, C., and Egholm, D.L. The evolution of western Scandinavian topography: a review of Neogene uplift versus the ICE (isostasy–climate–erosion) hypothesis. Journal of Geodynamics 47, (2009). 7295.Google Scholar
Palumbo, L., Hetzel, R., Tao, M., Li, X., and Guo, J. Deciphering the rate of mountain growth during topographic presteady state: an example from the NE margin of the Tibetan Plateau. Tectonics 28, (2009). TC4017 Google Scholar
Pedersen, V.K., Egholm, D., and Nielsen, S. Alpine glacial topography and the rate of rock column uplift: a global perspective. Geomorphology 122, (2010). 129139.Google Scholar
Phillips, W.M., Hall, A.M., Mottram, R., Fifield, K., and Sugden, D.E. Cosmogenic exposure ages of tors and erratics on the Cairngorm plateau, Scotland: timescales for the development of a classic landscape of selective linear glacial erosion. Geomorphology 73, (2006). 222245.Google Scholar
Porter, S.C. Some geological implications of average Quaternary conditions. Quaternary Research 32, (1989). 245261.Google Scholar
Refsnider, K.A., and Miller, G.H. Ice-sheet erosion and the stripping of Tertiary regolith from Baffin Island, eastern Canadian Arctic. Quaternary Science Reviews 67, (2013). 176189.Google Scholar
Robinson, G., Peterson, J.A., and Anderson, P.M. Trend surface analysis of corrie altitudes in Scotland. Scottish Geographical Magazine 87, (1971). 142146.Google Scholar
Rudberg, S. Glacial cirques in Scandinavia. Norsk Geografisk Tidsskrift 48, (1994). 179197.Google Scholar
Schlunegger, F., and Norton, K.P. Water versus Ice: the competing roles of modern climate and Pleistocene glacial erosion in the Central Alps of Switzerland. Tectonophysics 602, (2013). 370381.Google Scholar
Shuster, D.L., Cuffey, K.M., Sanders, J.W., and Balco, G. Thermochronometry reveals headward propagation of erosion in an alpine landscape. Science 332, (2011). 8488.Google Scholar
Small, E.E., Anderson, R.S., Repka, J.L., and Finkel, R. Erosion rates of alpine bedrock summit surfaces deduced from in situ 10Be and 26Al. Earth and Planetary Science Letters 150, (1997). 413425.Google Scholar
Spotila, J.A., Buscher, J.T., Meigs, A.J., and Reiners, P.W. Long-term glacial erosion of active mountain belts: example of the Chugach-St. Elias Range, Alaska. Geology 32, (2004). 501504.Google Scholar
Steer, P., Huismans, R.S., Valla, P.G., Gac, S., and Herman, F. Bimodal Plio-Quaternary glacial erosion of fjords and low-relief surfaces in Scandinavia. Nature Geoscience 5, (2012). 635639.Google Scholar
Sternai, P., Herman, F., Fox, M., and Castelltort, S. Hypsometric analysis to identify spatially variable glacial erosion. Journal of Geophysical Research 116, (2011). F03001 Google Scholar
Sugden, D.E. The selectivity of glacial erosion in the Cairngorm Mountains, Scotland. Transactions of the Institute of British Geographers 45, (1968). 7992.Google Scholar
Tomkin, J.H. Numerically simulating alpine landscapes: the geomorphologic consequences of incorporating glacial erosion in surface process models. Geomorphology 103, (2009). 180188.Google Scholar
Valla, P.G., Shuster, D.L., and van der Beek, P.A. Significant increase in relief of the European Alps during mid-Pleistocene glaciations. Nature Geoscience 4, (2011). 688692.Google Scholar
Van Der Beek, P., Van Melle, J., Guillot, S., Pêcher, A., Reiners, P.W., Nicolescu, S., and Latif, M. Eocene Tibetan plateau remnants preserved in the northwest Himalaya. Nature Geoscience 2, (2009). 364368.Google Scholar
Whipple, K.X., Kirby, E., and Brocklehurst, S.H. Geomorphic limits to climate-induced increases in topographic relief. Nature 401, (1999). 3943.Google Scholar
White, W.A. Erosion of cirques. Journal of Geology 78, (1970). 123126.Google Scholar