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46 - Cosmogenic-Isotope Based Erosion Rates along the Western Margin of the Dead Sea Fault

from Part V: - Quaternary Geomorphology

Published online by Cambridge University Press:  04 May 2017

Yehouda Enzel
Affiliation:
Hebrew University of Jerusalem
Ofer Bar-Yosef
Affiliation:
Harvard University, Massachusetts
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Summary

This is a compilation of bedrock and basin-wide average erosion rates determined from in-situ cosmogenic isotope concentrations in bedrock and sediments collected along the western margin of the Dead Sea fault. Bedrock erodes at rates ranging between <1 mm/ka to over >200 mm/ka (mean≈20 mm/ka). Chert and quartzolite in the arid environments erode the slowest. Carbonate rocks under hyperarid conditions also erode slowly (<2 mm/ka). Friable Lower Cretaceous sandstones in the Hazera erosional crater erode the fastest. Average basin-wide erosion ranges between 17.3±1.1 and 147±15 mm/ka (mean ≈56 mm/ka). Outlet channels yield average basin erosion rates of 19.4±2.6 to 70.9±2.9 mm/ka. However, five of the seven analyzed drainage basins yield similar average basin erosion rates ranging between 19.4±2.6 and 23.8±1.6 mm/ka. Comparisons with worldwide erosion rates indicate (1) most erosion rates along the western margin of the Dead Sea fault are within the average erosion rate range of Earth. (2) The tectonic, climatic and lithologic variations along the Dead Sea fault do not produce extreme (high or low) values of erosion rates.
Type
Chapter
Information
Quaternary of the Levant
Environments, Climate Change, and Humans
, pp. 391 - 400
Publisher: Cambridge University Press
Print publication year: 2017

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References

Avni, Y., Bartov, Y., Garfunkel, Z. & Ginat, H. 2000. Evolution of the Paran drainage basin and its relation to the Plio-Pleistocene history of the Arava Rift western margin, Israel. Israel Journal of Earth Sciences 49: 215–38.Google Scholar
Belton, D.X., Brown, R.W., Kohn, B.P., Fink, D. & Farley, K.A. 2004. Quantitative resolution of the debate over antiquity of the central Australian landscape: Implications for the tectonic and geomorphic stability of cratonic interiors. Earth and Planetary Science Letters 219: 2134.Google Scholar
Bierman, P.R. 1994. Using in situ produced cosmogenic isotopes to estimate rates of landscape evolution; a review from the geomorphic perspective. Journal of Geophysical Research, B, Solid Earth and Planets 99: 13885–96.Google Scholar
Bierman, P.R. & Caffee, M. 2001. Slow rates of rock surface erosion and sediment production across the Namib Desert and escarpment, southern Africa. American Journal of Science 301: 326–58.CrossRefGoogle Scholar
Bierman, P.R. & Caffee, M. 2002. Cosmogenic exposure and erosion history of Australian bedrock landforms. Geological Society of America Bulletin 114: 787803.Google Scholar
Bierman, P. & Steig, E. 1996. Estimating rates of denudation and sediment transport using cosmogenic isotope abundances in sediment. Earth Surface Processes and Landforms 21: 125–39.Google Scholar
Bierman, P.R. & Turner, J. 1995. 10Be and 26Al evidence for exceptionally low rates of Australian bedrock erosion and the likely existence of pre-Pleistocene landscapes. Quaternary Research 44: 378–82.Google Scholar
Binnie, S.A., Spotila, J.A., Phillips, W.M., Summerfield, M.A. & Fifield, K. 2003. The coexistence of steady and non-steady state topography in the San Bernardino Mountains, southern California, from cosmogenic 10Be and U–Th/He thermochronology. Geological Society of America, 2003 Annual Meeting. Abstracts with Programs 35: 63.Google Scholar
Bloom, A.L. 1998. Geomorphology: A Systematic Analysis of Late Cenozoic Landforms 3rd edn. Upper Saddle River: Prentice Hall.Google Scholar
Boaretto, E., Berkovits, D., Hass, M. et al. 2000. Dating of prehistoric caves sediments and flints using 10Be and 26Al in quartz from Tabun Cave (Israel): Progress report. Nuclear Instruments and Methods in Physics Research B 172: 767–71.Google Scholar
Boroda, R., Amit, R., Matmon, A. et al. 2011. Quaternary-scale evolution of sequences of talus flatirons in the hyperarid Negev. Geomorphology 127: 4152.Google Scholar
Boroda, R., Matmon, A., Amit, R. et al. 2014. Evolution and degradation of flat-top mesas in the hyper-arid Negev, Israel revealed from cosmogenic nuclides. Earth Surface Processes and Landforms 39: 1611–21.Google Scholar
Brown, E., Stallard, R.F., Larsen, M.C., Raisbeck, G.M. & Yiou, F. 1995. Denudation rates determined from the accumulation of in situ-produced 10Be in the Luquillo Experimental Forest, Puerto Rico. Earth and Planetary Science Letters 129: 193202.Google Scholar
Chappell, J., Zheng, H. & Fifield, K. 2006. Yangtse River sediments and erosion rates from source to sink traced with cosmogenic 10Be: sediments from major rivers. Palaeogeography, Palaeoclimatology, Palaeoecology 241: 7994.Google Scholar
Clapp, E., Bierman, P.R., Schick, A.P. et al. 2000. Sediment yield exceeds sediment production in arid region drainage basins. Geology 28: 995–8.2.0.CO;2>CrossRefGoogle Scholar
Duncan, C.C., Masek, J.G., Bierman, P., Larsen, J. & Caffee, M. 2001. Extraordinarily high denudation rates suggested by 10Be and 26Al analysis of river sediments, Bhutan Himalaya. Geological Society of America, Abstracts with Programs 33: A312.Google Scholar
Ewing, S.A., Sutter, B., Owen, J. et al. 2006. A threshold in soil formation at Earth's arid–hyperarid transition. Geochimica et Cosmochimica Acta 70: 5293–322.CrossRefGoogle Scholar
Fogwill, C.J., Bentley, M.J., Sugden, D.E., Kerr, A.R. & Kubik, P.W. 2004. Cosmogenic nuclides 10Be and 26Al imply limited Antarctic ice sheet thickening and low erosion in the Shackleton Range for >1 m.y. Geology 32: 265–8.Google Scholar
Fruchter, N., Matmon, A., Avni, Y. & Fink, D. 2011. Revealing sediment sources, mixing, and transport during erosional crater evolution in the hyperarid Negev Desert, Israel. Geomorphology 134: 363–77.Google Scholar
Gran, S.E., Matmon, A., Bierman, P.R. et al. 2001. Determination of displacement history from a limestone normal fault scarp using cosmogenic 36Cl, northern Israel. Journal of Geophysical Research 106: 4247–64.Google Scholar
Granger, D.E., Kirchner, J.W. & Finkel, R. 1996. Spatially averaged long-term erosion rates measured from in-situ produced cosmogenic nuclides in alluvial sediment. Journal of Geology 104: 249–57.CrossRefGoogle Scholar
Greensfelder, L. 2002. Subtleties of sand reveal how mountains crumble. Science 295: 256–8.CrossRefGoogle ScholarPubMed
Guralnik, B., Matmon, A., Avni, Y. & Fink, D. 2010. 10Be exposure ages of ancient desert pavements reveal Quaternary evolution of the Dead Sea drainage basin and rift margin tilting. Earth and Planetary Science Letters 290: 132–41.Google Scholar
Guralnik, B., Matmon, A., Avni, Y., Porat, N. & Fink, D. 2011. Constraining the evolution of river terraces with integrated OSL and cosmogenic nuclide data. Quaternary Geochronology 6: 2232.CrossRefGoogle Scholar
Hall, J.K. 1993. The GSI digital terrain model (DTM) project completed. Geological Survey of Israel Current Research 8: 4750.Google Scholar
Haviv, I. 2007. Mechanics, Morphology and Evolution of Vertical Knickpoints (Waterfalls) along the Bedrock Channels of the Dead Sea Western Tectonic Escarpment. Unpublished Ph.D. thesis, Hebrew University of Jerusalem.Google Scholar
Haviv, I., Enzel, Y., Zilberman, E. et al. 2006. Climatic control on erosion rates of dolo-limestone hilltops. The Israel Geological Society Annual Meeting Abstracts (Bet-Shean), p. 54.Google Scholar
Kober, F., Ivy-Ochs, S., Schlunegger, F. et al. 2007. Denudation rates and a topography-driven rainfall threshold in northern Chile: Multiple cosmogenic nuclide data and sediment yield budgets. Geomorphology 83: 97120.Google Scholar
Lal, D. & Peters, B. 1967. Cosmic ray produced radioactivity on the Earth. In Handbuch der Physik, ed. Sitte, K. New York: Springer-Verlag, pp. 551612.Google Scholar
Matmon, A., Bierman, P., Larsen, J. et al. 2003a. Temporally and spatially uniform rates of erosion in the southern Appalachian Mountains. Geology 31: 155–8.Google Scholar
Matmon, A., Bierman, P., Larsen, J. et al. 2003b. Erosion of an ancient mountain range, the Great Smoky Mountains, North Carolina and Tennessee. American Journal of Science 303: 817–55.CrossRefGoogle Scholar
Matmon, A., Shaked, Y., Porat, N. et al. 2005. Landscape development in an hyperarid sandstone environment along the margins of the Dead Sea fault: Implications from dated rock falls. Earth and Planetary Science Letters 240: 803–17.Google Scholar
Matmon, A., Simhai, O., Amit, R. et al. 2009. Where erosion ceases: Desert pavement coated surfaces in extreme deserts present the longest-lived landforms on Earth. Geological Society of America Bulletin 121: 688–97.Google Scholar
Matmon, A., Mushkin, A., Enzel, Y., Grodek, T. & ASTER Team. 2013. Erosion of a granite inselberg, Gross Spitzkoppe, Namib Desert. Geomorphology 201: 52–9.Google Scholar
Matmon, A., Quade, J., Placzek, C. et al. 2015. Seismic origin of the Atacama Desert boulder fields. Geomorphology 231: 2839.CrossRefGoogle Scholar
Milliman, J.D. & Syvitski, P.M. 1992. Geomorphic/tectonic control of sediment discharge to the ocean: The importance of small mountainous rivers. The Journal of Geology 100: 525–44.Google Scholar
Nishiizumi, K., Kohl, C.P., Arnold, J.R. et al. 1991. Cosmic ray produced 10Be and 26Al in Antarctic rocks; exposure and erosion history. Earth and Planetary Science Letters 104: 440–54.CrossRefGoogle Scholar
Nishiizumi, K., Caffee, M.W., Finkel, R.C., Brimhall, G. & Mote, T. 2005. Remnants of a fossil alluvial fan landscape of Miocene age in the Atacama Desert of northern Chile using cosmogenic nuclide exposure age dating. Earth and Planetary Science Letters 237: 499507.CrossRefGoogle Scholar
Nishiizumi, K., Imamura, M., Caffee, M.W. et al. 2007. Absolute calibration of 10Be AMS standards. Nuclear Instruments and Methods in Physics Research B 258: 403–13.Google Scholar
Placzek, C., Matmon, A., Granger, D.E., Quade, J. & Niedermann, S. 2010. Active landscape evolution in the hyperarid Atacama measured by multiple terrestrial cosmogenic nuclides. Earth and Planetary Science Letters 295: 1220.CrossRefGoogle Scholar
Placzek, C., Granger, D.E., Matmon, A., Quade, J. & Ryb, U. 2014. Geomorphic process rates in the central Atacama Desert, Chile: insights from cosmogenic nuclides and implications for the onset of hyperaridity. American Journal of Science 314: 14621512.CrossRefGoogle Scholar
Portenga, E.W. & Bierman, P.R. 2011. Understanding Earth's eroding surface with 10Be. GSA Today 21(8): 410.Google Scholar
Rinat, Y., Matmon, A., ASTER Team et al. 2014. Holocene rockfalls in the southern Negev Desert, Israel and their relation to Dead Sea fault earthquakes, Quaternary Research 82: 281–95.Google Scholar
Ryb, U., Matmon, A., Erel, Y. et al. 2014a. Controls on denudation rates in tectonically stable Mediterranean carbonate terrain. Geological Society of America Bulletin 126: 553–68.Google Scholar
Ryb, U., Matmon, A., Erel, Y. et al. 2014b. Styles and rates of long-term denudation in carbonate terrains under a Mediterranean to hyper-arid climatic gradient. Earth and Planetary Science Letters 406: 142152.Google Scholar
Safran, E.B., Bierman, P.R., Aalto, R. et al. 2005. Erosion rates driven by channel network incision in the Bolivian Andes. Earth Surface Processes and Landforms 30: 1007–24.CrossRefGoogle Scholar
Schaller, M., von Blanckenberg, F., Hovius, N. & Kubik, P.W. 2001. Large-scale erosion rates from in situ-produced cosmogenic nuclides in European river sediments. Earth and Planetary Science Letters 188: 441–58.Google Scholar
Small, E.E., Anderson, R.S. & Hancock, G.S. 1999. Estimates of the rate of regolith production using 10Be and 26Al from an alpine hillslope. Geomorphology 27: 131–50.Google Scholar
Summerfield, M.A., Stuart, F.M., Cockburn, H.A.P. et al. 1999. Long-term rates of denudation in the Dry Valleys, Transantarctic Mountains, southern Victoria Land, Antarctica based on in-situ-produced cosmogenic 21Ne. Geomorphology 27(1–2): 113–29.CrossRefGoogle Scholar
Vanacker, V., von Blanckenburg, F., Hewawasam, T. & Kubik, P.W. 2007. Constraining landscape development of the Sri Lankan escarpment with cosmogenic nuclides in river sediment. Earth and Planetary Science Letters 253: 402–14.Google Scholar
Vance, D., Bickle, M., Ivy-Ochs, S. & Kubik, P.W. 2003. Erosion and exhumation in the Himalaya from cosmogenic isotope inventories of river sediments. Earth and Planetary Science Letters 206: 273–88.CrossRefGoogle Scholar

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