Jökulhlaups from Kverkfjöll volcano, Iceland: modelling transient hydraulic phenomena

doi:10.1017/CBO9780511635632.015

15 - Jökulhlaups from Kverkfjöll volcano, Iceland: modelling transient hydraulic phenomena

Published online by Cambridge University Press: 04 May 2010

Jonathan L. Carrivick

Edited by

Devon M. Burr ,

Paul A. Carling and

Victor R. Baker

Show author details

Devon M. Burr: Affiliation:
University of Tennessee
Paul A. Carling: Affiliation:
University of Southampton
Victor R. Baker: Affiliation:
University of Arizona

Book contents

Get access

Summary

Jökulhlaups, or glacier outburst floods, are complex flood phenomena, with hydraulics that vary considerably spatially and temporally. However, jökulhlaups occur too suddenly, are too powerful and often too infrequent and remote for direct measurements of hydraulics to be made. Thus various palaeohydraulic methods have been applied to reconstruct jökulhlaup hydraulics from geomorphological and sedimentological evidence. However, these techniques fail to sufficiently characterise transient jökulhlaup hydraulic phenomena, in both space and time. A detailed understanding of these transient hydraulics is important for understanding rapid landscape change, high-magnitude flood mechanisms of erosion, transport and deposition, and hence jökulhlaup hazard management.

Therefore this paper reconstructs transient jökulhlaup flow phenomena using boulder clusters, the slope-area method and a depth-averaged two-dimensional (2D) hydrodynamic model. Kverkfjöll volcano on the northern edge of Vatnajökull, Iceland, provides the study site. Jökulhlaups inundated anastomosing bedrock valleys and exhibited transient hydraulic phenomena including sheet or unconfined flow, channel flow, flow around islands, hydraulic jumps, multi-directional flow including backwater areas and hydraulic ponding. Reconstructions of these jökulhlaups indicate peak discharges of 50–100 000 m3 s−1, which attenuated by ∼65% within 20 km. Frontal flow velocities were ∼1.6 m s−1 but as stage increased velocities reached 5–15 m s−1. Shear stress and stream power reached 1 × 104 N m−2 and 1 × 105 W m−2 respectively. Flows were largely supercritical due to steep channel gradients and shallow flows and highly turbulent due to high hydraulic roughness. Kverkfjöll jökulhlaups thus achieved geomorphological work comparable to that accomplished by ‘megafloods’.

Type: Chapter
Information: Megaflooding on Earth and Mars , pp. 273 - 289

DOI: https://doi.org/10.1017/CBO9780511635632.015 [Opens in a new window]

Publisher: Cambridge University Press

Print publication year: 2009

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.)

Book purchase

Temporarily unavailable

References

Agatz, H. (2002). EDV-gestützte paläohydrologische Modellierung der Ausbruchsflutwelle eines pleistozän gletschergestauten Sees im sibirischen Altai-Gebirge. Unpublished diploma thesis, Department of Geography, Universität Bochum.

Baker, V. R. (1988). Flood erosion. In Flood Geomorphology, eds. Baker, V. R., Kochel, R. C. and Patton, P. C.. New York: Wiley, pp. 81–95.Google Scholar

Baker, V. R. (2000). Palaeoflood hydrology and the estimation of extreme floods. In Inland Flood Hazards: Human, Riparian and Aquatic Communities, ed. Wohl, E. E.. Cambridge: Cambridge University Press, p. 498.Google Scholar

Baker, V. R. (2002). High-energy megafloods: planetary settings and sedimentary dynamics. In Flood and Megaflood Processes and Deposits: Recent and Ancient Examples, eds. Martini, P. I., Baker, V. R. and Garzon, G.. Special Publications International Association of Sedimentologists, 32, pp. 3–15.Google Scholar

Baker, V. R., Benito, G. and Rudoy, A. N. (1993). Palaeohydrology of Late Pleistocene superflooding, Altay Mountains, Siberia. Science, 259, 348–350.CrossRef Google Scholar

Benito, G. (1997). Energy expenditure and geomorphic work of the cataclysmic Missoula flooding in the Columbia River gorge, USA. Earth Surface Processes and Landforms, 22, 457–472.3.0.CO;2-Y>CrossRef Google Scholar

Björnsson, H. (2002). Subglacial lakes and jökulhlaups in Iceland. Global and Planetary Change, 35, 255–271.CrossRef Google Scholar

Brayshaw, A. C. (1984). Characteristics and origin of cluster bedforms in coarse-grained alluvial channels. In Sedimentology of Gravels and Conglomerates, eds. Koster, E. H. and Steel, R. J.. Canadian Society of Petroleum Geologists, pp. 77–85.Google Scholar

Carling, P. A., Hoffman, M. and Blatter, A. S. (2002). Initial motion of boulders in bedrock channels. In Ancient Floods, Modern Hazards: Principles and Applications of Palaeoflood Hydrology, eds. House, P. K., Webb, R. H., Baker, V. R. and Levish, D. R.. Washington, DC: American Geophysical Union, pp. 147–160.Google Scholar

Carling, P. A.et al. (2003). Palaeohydraulics of extreme flood events: reality and myth. In Palaeohydrology: Understanding Global Change, eds. Gregory, K. J. and Benito, G.. Chichester: Wiley.Google Scholar

Carrivick, J. L. (2005). Characteristics and impacts of jökulhlaups (glacial outburst floods) from Kverkfjöll, Iceland. Unpublished Ph.D. thesis, Keele University, UK.

Carrivick, J. L. (2006). 2D modelling of high-magnitude outburst floods: an example from Kverkfjöll, Iceland. Journal of Hydrology, 321, 187–199.CrossRef Google Scholar

Carrivick, J. L. (2007a). Hydrodynamics and geomorphic work of jökulhlaups (glacial outburst floods) from Kverkfjöll volcano, Iceland. Hydrological Processes, 21, 725–740.CrossRef Google Scholar

Carrivick, J. L. (2007b). Modelling coupled hydraulics and sediment transport of a high-magnitude flood and associated landscape change. Annals of Glaciology, 45, 143–154.CrossRef Google Scholar

Carrivick, J. L. and Rushmer, E. L. (2006). Understanding high-magnitude outburst floods. Geology Today, 22 (2), March–April 2006, 60–65.CrossRef Google Scholar

Carrivick, J. L. and Twigg, D. (2005). Jökulhlaup-influenced topography and geomorphology at Kverkfjöll, Iceland. Journal of Maps, 2005, 17–27.Google Scholar

Carrivick, J. L., Russell, A. J. and Tweed, F. S. (2004a). Geomorphological evidence for jökulhlaups from Kverkfjöll volcano, Iceland. Geomorphology, 63, 81–102. doi:10.1016/j.geomorph.2004.03.006.CrossRef Google Scholar

Carrivick, J. L., Russell, A. J., Tweed, F. S. and Twigg, D. (2004b). Palaeohydrology and sedimentology of jökulhlaups from Kverkfjöll, Iceland. Sedimentary Geology, 172, 19–40.CrossRef Google Scholar

Chincholle, L. (1994). A new basic principle for a new series of hydraulic measurements: erosion by abrasion, corrosion, cavitation and sediment concentration. In Fundamentals and Advancements in Hydraulic Measurements and Experimentation, ed. Pugh, C. A.. Proceedings of the Symposium held in Buffalo, New York, August 1–5, 1994. New York: ASCE, 0-7844-0036–9.Google Scholar

Clarke, G. K. C., Leverington, D. W., Teller, J. T. and Dyke, A. S. (2004). Paleohydraulics of the last outburst flood from glacial Lake Agassiz and the 8200 BP cold event. Quaternary Science Reviews, 23 (3–4). 389–407.CrossRef Google Scholar

Costa, J. E. (1983). Palaeohydraulic reconstruction of flash-flood peaks from boulder deposits in the Colorado front range. Geological Society of America Bulletin, 94, 986–1004.2.0.CO;2>CrossRef Google Scholar

Costa, J. E. and Schuster, R. L. (1988). The formation and failure of natural dams. GSA Bulletin, 100, 1054–1068.2.3.CO;2>CrossRef Google Scholar

Fenton, C. R., Webb, R. H. and Cerling, T. E. (2006). Peak discharge of a Pleistocene lava-dam outburst flood in Grand Canyon, Arizona, USA. Quaternary Research, 65 (2), 324–335.CrossRef Google Scholar

Gomez, B. S., Russell, A. J., Smith, L. C. and Knudsen, Ó. (2002). Erosion and deposition in the proglacial zone: the 1996 jökulhlaup on Skeiðarársandur, southeast Iceland. In The Extremes of the Extremes: Extraordinary Floods, eds. Snorrason, A., Finnsdóttir, A. P. and Moss, M.. Proceedings of a symposium at Reykjavík, July 2000. Publication 271, Wallingford, UK: IAHS Press, pp. 217–221.Google Scholar

Grant, G. E. (1997). Critical flow constrains flow hydraulics in mobile-bed streams: a new hypothesis. Water Resources Research, 33, 349–358.CrossRef Google Scholar

Herget, J. (2002). Reconstruction of ice-dammed lake outbursts, Altai Mountains (Siberia). Unpublished Habilitation thesis at Faculty of Earth Sciences, Ruhr-University Bochum.

Herget, J. (2005). Reconstruction of Pleistocene Ice-dammed Lake Outburst Floods in the Altai Mountains, Siberia. Geological Society of America Special Paper 386.CrossRef

Hiscott, R. N. (1994). Loss of capacity, not competence, as the fundamental process governing deposition from turbidity currents. Journal of Sedimentary Research, A64, 209–214.CrossRef Google Scholar

Jarrett, R. D. (1984). Hydraulics of high gradient streams. Journal of Hydraulic Engineering, 110, 1519–1539.CrossRef Google Scholar

Jarrett, R. D. and Malde, H. E. (1987). Palaeodischarge of the late Pleistocene Bonneville Flood, Snake River, Idaho, computed from new evidence. GSA Bulletin, 99, 127–134.2.0.CO;2>CrossRef Google Scholar

Jóhannesson, H. and Saemundsson, K. (1989). Geological Map of Iceland, 1:1500 000 Bedrock Geology. Reykjavík: Icelandic Museum of Natural History and Icelandic Geodetic Survey.

Karhunen, R. (1988). Eruption Mechanism and Rheomorphism During the Basaltic Fissure Eruption in Biskupsfell, Kverkfjoll, North-Central Iceland. Reykjavik: Nordic Volcanological Institute.Google Scholar

Komar, P. D. (1989). Flow-competence evaluations of the hydraulic parameters of floods: an assessment of the technique. In Floods: Hydrological, Sedimentological and Geomorphological Implications, eds. Bevan, K. and Carling, P.. Chichester: John Wiley and Sons Ltd., pp. 107–134.Google Scholar

Lee, W. and Hoopes, J. A. (1996). Prediction of cavitation damage for spillways. Journal of Hydraulic Engineering, 122 (9), 481–488.CrossRef Google Scholar

Limerinos, J. T. (1970). Determination of the Manning Coefficient from Measured Bed Roughness in Natural Channels. United States Geological Water Supply Paper, 1898-B.

Magilligan, F. J. (1992). Thresholds and extreme spatial variability of flood power during extreme floods. Geomorphology, 5, 373–390.CrossRef Google Scholar

Maizels, J. K. (1983). Palaeovelocity and palaeodischarge determination for coarse gravel deposits. In Background to Palaeohydrology, ed. Gregory, K. J.. Chichester: John Wiley and Sons Ltd.Google Scholar

Maizels, J. K. (1997). Jökulhlaup deposits in proglacial areas. Quaternary Science Reviews, 16, 793–819.CrossRef Google Scholar

Manville, V. R. and White, J. D. L. (2003). Incipient granular mass flows at the base of sediment-laden floods, and the roles of flow competence and flow capacity in the deposition of stratified bouldery sands. Sedimentary Geology, 155 (1–2), 157–173.CrossRef Google Scholar

Nie, Meng-Xi (2001). Cavitation prevention with roughened surface. Journal of Hydraulic Engineering, 127 (10), 878–880.CrossRef Google Scholar

O'Connor, J. E. (1993). Hydrology, Hydraulics and Geomorphology of the Bonneville Flood. Geological Society of America Special Paper 274.CrossRef

O'Connor, J. E. and Baker, V. R. (1992). Magnitudes and implications of peak discharges from glacial Lake Missoula. Geological Society of America Bulletin, 104, 267–279.2.3.CO;2>CrossRef Google Scholar

Rudoy, A. N. (2002). Glacier-dammed lakes and geological work of glacial superfloods in the late Pleistocene, southern Siberia, Altai mountains. Quaternary International, 87, 119–140.CrossRef Google Scholar

Rushmer, E. L. (2006). Sedimentological and geomorphological impacts of the jökulhlaup (glacial outburst flood) in January 2002 at Kverkfjöll, northern Iceland. Geografiska Annaler, 88A, 1–11.Google Scholar

Rushmer, E. L. (2007). Physical-scale modelling of jökulhlaups (glacial outburst floods) with contrasting hydrograph shapes. Earth Surface Processes and Landforms, 32, 954–963.CrossRef Google Scholar

Russell, A. J. and Marren, P. M. (1999). Proglacial fluvial sedimentary sequences in Greenland and Iceland: a case study from active proglacial environments subject to jökulhlaups. In The Description and Analysis of Quaternary Stratigraphic Field Sections, eds. Jones, A. P., Hart, J. K. and Tucker, M. E.. QRA Technical Guide 7, London: QRA, pp. 171–208.Google Scholar

Sleigh, P. A. and Goodwill, I. M. (2000). The St Venant equations. http://www.efm.leeds.ac.uk/CIVE/CIVE3400/stvenant. pdf, last visited 15 February 2007.

Strickler, A. (1923). Beiträge zur Frage der Geschwindigkeitsformel und der Rauhigkeitszahlen Für Ströme, Kanäle und geschlossene Leitungen. Mitteilungen des Eidgenössischen Amtes für Wasserwirtschaft, Bern, Switzerland, 16.Google Scholar

Thompson, S. M. and Campbell, P. L. (1979). Hydraulics of a large channel paved with boulders. Journal of Hydraulic Research, 17, 341–354.CrossRef Google Scholar

Tómasson, H. (1996). The jökulhlaup from Katla in 1918. Annals of Glaciology, 22, 249–254.CrossRef Google Scholar

Tweed, F. S. and Russell, A. J. (1999). Controls on the formation and sudden drainage of glacier-impounded lakes: implications for jökulhlaup characteristics. Progress in Physical Geography, 23, 79–110.CrossRef Google Scholar

Whipple, K. X., Hancock, G. S. and Anderson, R. S. (2000). River incision into bedrock: mechanics and relative efficacy of plucking, abrasion, and cavitation. GSA Bulletin, 112 (3), 490–503.2.0.CO;2>CrossRef Google Scholar

Williams, G. P. (1984). Palaeohydraulic equations for rivers. In Developments and Applications of Geomorphology, eds. Costa, J. E. and Fleisher, P. J.. Berlin Heidelberg: Springer-Verlag, pp. 343–367.CrossRef Google Scholar

Zingg, T. H. (1935). Beträge zur Schotteranalyse. Schweizerische Mineralogische und Petrographische Mitteilungen, 15, 39–140.Google Scholar