PL EN


Preferencje help
Widoczny [Schowaj] Abstrakt
Liczba wyników
Tytuł artykułu

The hydrological role of biological topsoil crusts and water repellency in sandy dry-land areas

Autorzy
Treść / Zawartość
Identyfikatory
Warianty tytułu
Języki publikacji
EN
Abstrakty
EN
Dryland areas are regarded as highly sensitive to climatic changes. A positive relationship between rainfall and environmental factors is often assumed for areas with an average annual rainfall of 100–300 mm. This assumption disregards the fact that a climate change in arid areas is not limited to climatic factors. It is often accompanied by a pronounced spatial variability in surface characteristics. The present work deals with the complex relationships among average annual rainfall, surface properties and the spatial redistribution of water resources in sandy areas located in the Northern Negev Desert. Two case studies are considered. The first deals with the hydrological effects of biological topsoil crusts on the water regime, along a rainfall gradient (86–170 mm). This study is based on five monitoring sites. Data obtained show a decrease in water availability with increasing annual rainfall. The findings are attributed to the decisive role played by the non-uniform properties of the topsoil crust along the rainfall gradient. The second case refers to the non-uniform development, and survival, of planted trees. Trees planted on steep dunes are well developed, with a high survival rate, whereas trees planted on low angle dunes are small. This study focused on the role of a water repellent layer on the water regime. Data obtained show a striking difference between steep and low dunes in all aspects studied, namely the degree of water repellency, frequency and magnitude of runoff events, infiltration depth and soil moisture. All variables monitored were found higher on steep than on low dunes. The large trees shed a substantial amount of leaves, whose decay developed a water repellent layer. Runoff generation over the repellent layer enhanced deep water penetration, through the process of subsurface flow. The lack of a water repellent layer over the low dunes prevented runoff generation, with its positive effects.
Czasopismo
Rocznik
Tom
Strony
33--44
Opis fizyczny
Bibliogr. 54 poz., rys.
Twórcy
autor
  • Department of Geography, Hebrew University of Jerusalem, Israel
autor
  • Ministry of Environmental Protection, Jerusalem, Israel
autor
  • Zalul Environmental Association, Ramat Gan, Israel
Bibliografia
  • Allgaier A., 2008. Aeolian sand transport and vegetation cover. In: S.W. Breckle, A. Yair, M. Veste (eds), Arid Dune Ecosystems. Ecological Studies 200: 211–223.
  • Almog R., Yair A., 2007. Negative and positive effects of topsoil biological crusts on water availability along a rainfall gradient in a sandy arid area. Catena 70: 437–442.
  • Arbel Y., Yair A., Oz S., 2005. Effects of topography and a water repellent layer on the nob-uniform development of planted trees in sandy arid area. Journal of Arid Environments 60: 67–81.
  • Avnimelech Y, Nevo Z., 1964. Biological clogging of sands. Soil Science 98: 222–226.
  • Bauters T.W.J., Dicarlo D.A., Steenhuis T.S., Parlange J.Y., 1998. Preferential flow in water sands. Soil Science Society American Journal 62: 1185–1190.
  • Belnap J., Burkhard B., Lange O.L., 2001. Biological soil crusts: characteristics and distribution. In: J. Belnap, O.L. Lange (eds),Biological soil crusts: structure, function and management. Ecological Studies 150.
  • Berndtsson R., Nodomi K., Yasuda H., Persson T., Chen H., Jinno K., 1996. Soil water and temperature patterns in an arid desert dune sand. Journal of Hydrology 185: 221–240.
  • Bond R.D., Harris J.R., 1964. The influence of the microflora on the physical properties of sand. Effects associated with filamentous algae and fungi. Australian Journal of Soil Research 2: 111–122.
  • Brotherson J.D., Rushworth S.B., Johansen J.R., 1983. Influence of cryptogamic crusts on moisture relationship of soils in Navajo National Monument, Arizona. Great Basin Naturalist 43: 73–78.
  • Burcar S., Miller W.W., Tyler S.W., Johnson D.W., 1994. Seasonal preferential flow in two sierra Nevada soils. Soil Society American Journal 58: 1555–1561.
  • Burley J., 1990. The conservation and use of plant resources in dryland areas. In: A.S. Goudie (ed.), Techniques in Desert Reclamation. Wiley: 199–215.
  • Campbell S.E., 1979. Soil stabilization by prokaryotic crust. Implication for Precambrian land biota Origin of Life 9: 335–348.
  • Danin A., Bar-Or Y., Dor I., Yisraeli T., 1989. The role of cyanobacteria in stabilization of sand dunes in southern Israel. Ecologia Mediterranea 15: 55–64.
  • DeBano L.F., 2000. Water repellency in soils: a historical overview. Journal of Hydrology 231: 10–34.
  • Dekker L.W., Jungerius P.D., 1990. Water repellency in the dunes with special reference to the Netherland dunes of the European coast. Catena Suppl. 18: 173–183.
  • Dekker L.W., Ritsema C.J., 1994. How water moves in a water repellent soil. Potential and actual water repellency. Water Resources Research 30(9): 2507–2517.
  • Dekker L.W., Ritsema C.J., Wendorth O., Jarvis N., Oostindie K., Pohl W., Larson M., Gaudet J., 1999. Moisture distribution and wetting rates of soils at experimental fields in the Nethertlands, France, Sweden and Germany. Journal of Hydrology 215: 4–22.
  • Doerr D.H., 1998. On standardizing the “water drop penetration time” and the molarity of an ethanol droplet techniques to classify soil hydrophobicity: a case study using medium textural soils. Earth Surface Processes and Landforms 23: 663–668.
  • Doerr S.H., Shaksby R.A., Walsh R.P.D., 2000. Soil water repellency: its causes and hydro-geomorphological significance. Earth Surface Reviews 51: 33–65.
  • Eldridge D.E., 1993. Cryptogamic cover and soil surface conditions: Effects on hydrology on a semi-arid woodland soil. Arid Soil Research and Rehabilitation 7: 203–217.
  • Eldridge D.E., 2001. Biological soil crusts of Australia. In: J. Belnap, O.L. Lange (eds), Biological soil crusts: Structure, Function and Management. Ecological Studies 150: 119–132.
  • Eldridge D.E., Zaady E., Shachak M., 2000. Infiltration through three contrasting biological topsoil crusts in patterned landscapes in the Negev Desert, Israel. Catena 49: 323–336.
  • Hendricks J.M.H., Dekker L.W., Boersma O.H., 1993. Unstable wetting fronts in water-repellent field soils. Journal of Environmental Quality 22: 109–118.
  • Imeson A.C., Verstraten E.J., Van Muligen E.G., Sevink J., 1992. The effects of fire and water repellency on infiltration and runoff under Mediterranean type forest. Catena 17: 345–361.
  • Jungerius P.D., Dejong J.H., 1989. Variability of water repellence in the dunes along the Dutch coast. Catena 16: 491–497.
  • Kidron G.J., Yair A., 1997. Rainfall-runoff relationships over encrusted dunes surfaces, Nizzana, Western Negev, Israel. Earth Surface Processes and Landforms 22:169–1184.
  • Kidron G.J., Yair., A., Vonshak A., Abeliovich A., 2003. Microbiotic crust control of runoff generation in the Negev Desert. Water Resources Research 39(4): 1108.
  • Kidron G.J., 2015. The role of crust thickness in runoff generation from microbiotic crusts. Hydrological Processes 29: 1783–1792.
  • Krammes J.S., DeBano L.F., 1965. Soil wettability: a neglected factor in watershed management. Water Resources Research 1: 283–286.
  • Littmann T., Berkowicz S.M., 2008. The regional climating setting. In: S.W. Breckle, A. Yair, M. Veste (eds), Arid Dune Ecosystems. Ecological Studies 200: 49–63.
  • Mashum M., Farmer V.C., 1985. Origin and assessment of water repellency of a coastal South Australia soil. Australian Journal of Soil Research 23: 723–626.
  • Mazor G., Kidron G.J., Vonshak A., Abeliovitch A., 1996. The role of cyanobacterial exo-polysaccarides in structuring desert microbial crusts. FEMS Microbial Ecology 21: 121–130.
  • McCord J.T., Stephens D.D., 1987. Lateral moisture flow beneath a sandy hillslope without an apparent impeding layer. Hydrological Processes 1: 225–238.
  • Misak R.F., Draz M.Y., 1997. Sand drift control on selected coastal dunes and desert dunes in Egypt: case studies. Journal of Arid Environments 35: 17.28.
  • Rietveld J., 1978. soil non-wettability and its relevance as a contributing factor to surface runoff on sandy on sandy soils in Mali. Report of the project: Production Primaire au Sahel, Wageningen.
  • Ritsema J.C., Dekker L.W., 1994. How water moves in a water repellent sandy soil: dynamics of finger flow. Water Resources Research 20: 2519–2531.
  • Ritsema J.C., Dekker L.W., 1997. Three-dimensional fingered flow patterns in a water repellent sandy field soil. Soil Science 162: 79–90.
  • Roberts F.G., Carson B.A., 1971. water repellence in sandy soils of Southern Australia. Australian Journal of Soil Science 58: 35–42.
  • Rutin J., 1983. Erosional processes on a coastal sand dune, De blink, Noordwijkerhout. Physical Geography and Soil Laboratory Pub. 35. University of Amsterdam.
  • Savage S.M., Martin J.P., Letey J., 1969. Contribution of some soil fungi to natural and heat induced water repellency in sand. Soil Science Society America Proceedings 33: 405–409.
  • Stevens J.H., 1974. Sand stabilization in Saudi Arabia al-hasa oasis. Journal of Soil and Water Conservation 29: 33–129.
  • Tsoar H., Blumberg D.G., Wenkart R., 2008. Formation and Geomorphology of the North-Western Negev sand dunes. In: S.W. Breckle, A. Yair, M. Veste (eds), Arid Dune Ecosystems. Ecological Studies 200: 25–46.
  • Verrecchia E., Yair A., Kidron G.J., Verrecchia K., 1995. Physical properties of the psammophile cryptogamic crusts and their consequences on the water regime in sandy soils, north western Negev, Israel. Journal of Arid Environments 29: 427–437.
  • Waisel Y., 1960. Ecological studies on Tamarix Aphylla (L.) Karst. Plant and Soil 13(4): 356–364.
  • Wang Z., Wu O.J., Ritsema L.W., Dekker L.W., Feyen J., 2000. Effects of water repellency on infiltration rate and flow instability. Journal of Hydrology 231: 265–276.
  • Warren S.D., 2001. Biological soil crusts and hydrology in North American Deserts. In: J. Belnap, O.L. Lange (eds), Biological Soil Crusts: Structure, Function, and Management. Ecological Studies 150: 327–337.
  • Wessel A.T., 1998. On using the effective contact angle and the water penetration time for classification of water repellency in dune soils. Earth Processes and Landforms 13: 555–561.
  • Witter J.V., Jungerius P.D., Ten-Harkel M.J., 1991. Modeling water erosion and the impact of water repellency. Catena 18: 115–124.
  • Yair A., 1983. Hillslope hydrology, water harvesting and areal distribution of some ancient agricultural systems in the Negev. Journal of Arid Environments 6: 283–301.
  • Yair A., 1990. Runoff generation in a sandy area. The Nizzana sands, Western Negev. Earth Surface Processes and Landforms 15: 597–607.
  • Yair A., 1994. The ambiguous impact of climate change at a desert fringe: Northern Negev,Israel. In: A.C. Millington, K. Pye (eds), Environmental change in drylands: biogeographical and geomorphological perspectives. Chichester: 199–227.
  • Yair A., 2001. Effects of biological soil crusts on water redistribution in the Northern Negev, Israel. A case study in longitudinal dunes. In: J. Belnap, O.L. Lange (eds), Biological Soil Crusts: Structure, Function and Management, Ecological Studies 150: 303–314.
  • Yair A., Almog R., Veste M., 2011. Differential hydrological response of biological topsoil crusts along a rainfall gradient in a sandy arid area: Northern Negev desert, Israel. Catena 87: 326–333.
  • Yair A., Lavee H., Greitser., 1997. Spatial and temporal variability of water percolation and movement in a system of longitudinal dunes, Western Negev. Hydrological Processes 11: 43–58.
  • Yang H., Liu L., Li X., Wei Y., Li X., Jia R., 2014. Water repellency of biological soil crusts and influencing factors on the southeast fringe of the Tengger Desert, North-Central China. Soil Science 179: 424–432.
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-440aae51-d4a8-4adf-898c-913b9a4c562a
JavaScript jest wyłączony w Twojej przeglądarce internetowej. Włącz go, a następnie odśwież stronę, aby móc w pełni z niej korzystać.