[Bachmann J., Ellies A., Hartge K.H. 2003. Sessile drop contact angle method. In: Soil Water Repellency. Origin, assessment, occurrence, consequences, modeling, and amelioration (eds.: C.J. Ritsema, L.W. Dekker), Elsevier, The Netherlands, 57–65.]Search in Google Scholar
[Bayer J., Schaumann G.E. 2007. Development of soil water repellency in course of isothermal drying and upon pH changes in two urban soils. Hydrological Processes, 21, 2266–2275.]Search in Google Scholar
[Bisdom E.B.A., Dekker L.W., Schoute J.F.T. 1993. Water repellency of sieve fractions from sandy soils and relationships with organic material and soil structure. Geoderma, 56, 105–118.]Search in Google Scholar
[Campbell R.E., Baker M.B. Jr., Ffolliott P.F., Larson F.R., Avery C.C. 1977. Wildfire effects on a ponderosa pine ecosystem: an Arizona case study. USDA Forest Service Research Paper, RM-191, 1–12.]Search in Google Scholar
[Cerdà A., Pelayo Ó.G., Orenes F.G., Jordán A., Pereira P., Novara A., Neris J. 2015. Long-term water repellency in organic olive orchards in the Cànyoles River watershed. The impact of land management. Geophysical Research Abstracts, 17, EGU2015-15079-1.]Search in Google Scholar
[Czachor H., Hallett P., Lichner L., Jozefaciuk G. 2013. Pore shape and organic compounds drive major changes in the hydrological characteristics of agricultural soils. European Journal of Soil Science, 64, 334–344.]Search in Google Scholar
[Das D.K., Das B. 1972. Characterization of water-repellency in Indian soils. Indian Journal of Agricultural Science, 42, 1099–1102.]Search in Google Scholar
[Dekker L.W., Doerr S.H., Oostindie K., Ziogas A.K., Ritsema C.J. 2001. Water repellency and critical soil water content in a dune sand. Soil Science Society of America Journal, 65 (6), 1667–1674.]Search in Google Scholar
[Diehl D., Bayer J.V., Woche S.K., Bryant R., Doerr S.H., Schaumann G.E. 2010. Reaction of soil water repellency to artificially induced changes in soil pH. Geoderma, 158 (3/4), 375–384.]Search in Google Scholar
[Dlapa P., Ďuriš M. 2006. Diverzita pôdneho krytu a jeho vlastností ako súčasť životného prostredia Bielych Karpát a Myjavskej pahorkatiny. Acta Environmentalica Universitatis Comenianae, 14 (2), 19–30.]Search in Google Scholar
[Doerr S.H., 1998. On standardizing the water drop penetration time and the molarity of an ethanol droplet technique to classify soil hydrophobicity: a case study using medium textured soils. Earth Surface Processes and Landforms, 23 (7), 663–668.10.1002/(SICI)1096-9837(199807)23:7<663::AID-ESP909>3.0.CO;2-6]Search in Google Scholar
[Doerr S.H., Blake W.H., Shakesby R.A., Stagnitti F., Vuurens S.H., Humphreys G.S., Wallbrink P. 2004. Heating effects on water repellency in Australian eucalypt forest soils and their value in estimating wildfire soil temperatures. International Journal of Wildland Fire, 13 (2), 157–163.]Search in Google Scholar
[Doerr S.H., Shakesby R.A., Walsh R.P.D. 2000. Soil water repellency: its causes, characteristics and hydro-geomorphological significance. Earth Science Reviews, 51, 33–65.]Search in Google Scholar
[Doerr S.H., Shakesby R.A., Dekker L.W., Ritsema C.J. 2006. Occurrence, prediction and hydrological effects of water repellency amongst major soil and land-use types in a humid temperate climate. European Journal of Soil Science, 57, 741–754.]Search in Google Scholar
[Doerr S.H., Thomas A.D. 2000. The role of soil moisture in controlling water repellency: new evidence from forest soils in Portugal. Journal of Hydrology, 231–232, 134–147.]Search in Google Scholar
[FAO 2006. Guidelines for soil description. 4th edition. Rome, Italy: Food and Agriculture Organization of the United Nations.]Search in Google Scholar
[Feeney D.S., Crawford J.W., Daniell T., Hallett P.D., Nunan N., Ritz K., Rivers M., Young I.M. 2006. Three-dimensional microorganization of the soil-root-microbe system. Microbial Ecology, 52, 151–158.]Search in Google Scholar
[Franco C.M.M., Clarke P.J., Tate M.E., Oades J.M. 2000a. Studies on non-wetting sands: II. Hydrophobic properties and chemical characterization of natural water-repellent materials in Australian sands. Journal of Hydrology, 231/232, 47–58.]Search in Google Scholar
[Franco C.M.M., Michelsen P.P., Oades J.M. 2000b. Amelioration of water repellency: application of slow-release fertilisers to stimulate microbial breakdown of waxes. Journal of Hydrology, 231/232, 342–351.]Search in Google Scholar
[Hammond L.C., Yuan T.L. 1969. Methods of measuring water repellency of soils. In: Proceedings of a symposium on water repellent soils (eds.: L.F. DeBano, J. Letey), May 6–10, 1968, Riverside, CA., 49–60.]Search in Google Scholar
[Harper R.J., McKissock I., Gilkes R.J., Carter D.J., Blackwell P.S. 2000. A multivariate framework for interpreting the effects of soil properties, soil management and landuse on water repellency. Journal of Hydrology, 231/232, 371–383.]Search in Google Scholar
[Henderson G.S., Golding D.L. 1983. The effect of slash burning on the water repellency of forest soils at Vancouver, British Columbia. Canadian Journal of Forestry Research, 13, 353–355.]Search in Google Scholar
[Hudson R.A., Traina S.J., Shane W.W. 1994. Organic matter comparison of wettable and non-wettable soils from bentgrass sand greens. Soil Science Society of America Journal, 58, 361–367.]Search in Google Scholar
[Johnson M.S., Lehmann J., Steenhuis T.S., de Oliveira L.V., Fernandes E.C.M. 2005. Spatial and temporal variability of soil water repellency of Amazonian pastures. Australian Journal of Soil Research, 43, 319–326.]Search in Google Scholar
[King P.M. 1981. Comparison of methods for measuring severity of water repellence of sandy soils and assessment of some factors that affect its measurement. Australian Journal of Soil Research, 19, 275–285.]Search in Google Scholar
[Kobayashi M., Shimizu T. 2007. Soil water repellency in a Japanese cypress plantation restricts increases in soil water storage during rainfall events. Hydrological Processes, 21 (17), 2356–2364.]Search in Google Scholar
[Kostka S.J., Dekker L.W., Oostindie K., Ritsema C.J., Miller C.M., Karcher D.E. 2002. Advances in understanding and managing water repellent soils. In: Understanding and addressing conservation and recycled water irrigation. Conference proceedings, S.l., Irrigation Association/Omnipress, (cd-rom).]Search in Google Scholar
[Kuča P., Májsky J., Kopeček F., Jongepierová I. 1992. Biele Karpaty. Vydavateľstvo Ekológia. Bratislava.]Search in Google Scholar
[ Lennartz B., Louchart X., Voltz M., Andrieux P. 1997. Diuron and simazine losses to runoff water in Mediterranean vineyards. Journal of Environmental Quality, 26, 1493–1502.]Search in Google Scholar
[Letey J., Carrillo M.L.K., Pang X.P. 2000. Approaches to characterize the degree of water repellency. Journal of Hydrology, 231/232, 61–65.]Search in Google Scholar
[Lewis S.A., Wu J.Q., Robichaud P.R. 2006. Assessing burn severity and comparing soil water repellency, Hayman Fire, Colorado. Hydrological Processes, 20, 1–16.]Search in Google Scholar
[Lichner Ľ., Babejová N., Dekker L.W. 2002. Effects of kaolinite and drying temperature on the persistence of soil water repellency induced by humic acids. Rostlinná výroba, 48 (5), 203–207.]Search in Google Scholar
[Lozano E., Jiménez-Pinilla P., Mataix-Solera J., Arcenegui V., Bárcenas G.M., González-Pérez J.A., García-Orenes F., Torres M.P., Mataix-Beneyto J. 2013. Biological and chemical factors controlling the patchy distribution of soil water repellency among plant species in a Mediterranean semiarid forest. Geoderma, 207/208, 212–220.10.1016/j.geoderma.2013.05.021]Search in Google Scholar
[Ma’shum M., Tate M.E., Jones G.P., Oades J.M. 1988. Extraction and characterization of water-repellent materials from Australian soils. Journal of Soil Science, 39, 99–110.]Search in Google Scholar
[Mataix-Solera J., Arcenegui V., Guerrero C., Mayoral A.M., Morales J., González I., García-Orenes F., Gómez I. 2007. Water repellency under different species in a calcareous forest soil in a semiarid Mediterranean environment. Hydrological Processes, 58, 1254–1259.]Search in Google Scholar
[Mataix-Solera J., Arcenegui V., Tessler N., Zornoza R., Wittenberg L., Martínez C., Caselles P., Pérez-Bejarano A., Malkinson D., Jordán M.M. 2013. Soil properties as key factors controlling water repellency in fire-affected areas: Evidences from burned sites in Spain and Israel. Catena, 108, 6–13.10.1016/j.catena.2011.12.006]Search in Google Scholar
[Meeuwig R.O. 1971. Infiltration and water repellency in granitic soils. USDA Forest Service Research Paper, INT-111, 1–20.]Search in Google Scholar
[Orzechowski M., Smólczyński S. Sowiński P., Rybińska B. 2013. Water repellency of soils with various content of organic mater in north-eastern Poland. Soil Science Annual, 64 (2), 30–33.]Search in Google Scholar
[Rodríguez-Alleres M., Varela M.E., Benito E. 2012. Natural severity of water repellency in pine forest soils from NW Spain and influence of wildfire severity on its persistence. Geoderma, 191, 125–131.10.1016/j.geoderma.2012.02.006]Search in Google Scholar
[Roper M.M. 2005. Managing soils to enhance the potential for bioremediation of water repellency. Australian Journal of Soil Research, 43, 803–810.]Search in Google Scholar
[Shakesby R.A., Doerr S.H., Walsh R.P.D. 2000. The erosional impact of soil hydrophobicity: current problems and future research directions. Journal of Hydrology, 231/232, 178–191.]Search in Google Scholar
[Societas Pedologica Slovaca 2000. Morphogenetic Soil Classification System of Slovakia. Basal Reference Taxonomy. Soil Science and Conservation Research Institute, Bratislava.]Search in Google Scholar
[Szatyłowicz J., Oleszczuk R., Gnatowski T., Mączyńska E. 2006. Ocena zwilżalności utworów torfowych i murszowych na podstawie pomiarów kąta zwilżania pomiędzy fazą stałą gleby a wodą. In: Właściwości fizyczne i chemiczne gleb organicznych (eds.: T. Brandyk, L. Szajdak, J. Szatyłowicz). Wyd. SGGW, Warszawa, 85–94.]Search in Google Scholar
[Šimkovic I., Dlapa P., Šimonovičová A., Ziegler W. 2009. Water repellency of mountain forest soils in relation to impact of the katabatic windstorm and subsequent management practices. Polish Journal of Environmental Studies, 18 (3), 443–454.]Search in Google Scholar
[Thorsen M.K., Hopkins D., McKenzie B. 2010. Sources and characteristics of water repellency in machair soil. Poster. University of Aberdeen and Scottish Crop Research Institute.]Search in Google Scholar
[Wahl N.A. 2008. Variability of water repellency in sandy forest soils under broadleaves and conifers in north-western Jutland/Denmark. Soil and Water Research, 3 (1), 155–164.]Search in Google Scholar
[Walkley A., Black I.A. 1934. An examination of the Degtjareff method for determining soil O.M. and a proposed modification of the chromic acid titration method. Soil Science, 37, 29–38.]Search in Google Scholar
[Wang Z., Wu Q.J., Wu L., Ritsema C.J., Dekker L.W., Feyen J. 2000. Effects of soil water repellency on infiltration rate and flow instability. Journal of Hydrology, 231/232, 265–276.]Search in Google Scholar
[Wylie L., Allinson G., Stagnitti F. 2001. Guidelines for the standardisation of the water drop penetration time test. 26th General Assembly of the European Geophysical Society, EGS Nice France, 26–30 March 2001, Abstracts 3, 631–633.]Search in Google Scholar
[Zavala L.M., Cerdà A., Alanís N. 2015. Soil water repellency: current knowledge and future insights. European Geosciences Union, General Assembly 2015, 12–17 April 2015, Vienna, Austria.]Search in Google Scholar