1. bookVolumen 70 (2022): Heft 3 (September 2022)
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1338-4333
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The soil moisture regime and groundwater recharge in aged forests in the Sand Ridge region of Hungary after a decline in the groundwater level: an experimental case study

Online veröffentlicht: 23 Aug 2022
Volumen & Heft: Volumen 70 (2022) - Heft 3 (September 2022)
Seitenbereich: 308 - 320
Eingereicht: 22 Apr 2022
Akzeptiert: 30 Jun 2022
Zeitschriftendaten
License
Format
Zeitschrift
eISSN
1338-4333
Erstveröffentlichung
28 Mar 2009
Erscheinungsweise
4 Hefte pro Jahr
Sprachen
Englisch

Aeschbach-Hertig, W., Gleeson, T., 2012. Regional strategies for the accelerating global problem of groundwater depletion. Nature Geosciences, 5, 853–861.10.1038/ngeo1617 Search in Google Scholar

Berényi, P., Erdélyi, M., 1990. A rétegvíz szintjének süllyedése a Duna–Tisza közén. [Sinking of the deep groundwater level in the Danube-Tisza interfluve]. Vízügyi közlemények, 72, 377–397. (In Hungarian.) Search in Google Scholar

Bolla, B., 2021. Erdészeti meteorológiai mérőhálózat, mint az erdővédelmi mérő- és megfigyelő rendszer alrendszere. [Forest meteorological monitoring system as the subsystem of forest protection, measuring and monitoring system.] Légkör, 66, 13–14. (In Hungarian.) Search in Google Scholar

Bolla, B., Németh, T.M., 2017. Monitoring of the hydrological balance in the area of the Kiskunság National Park Directorate. Acta Silvatica et Lignaria Hungarica, 13, 97–111.10.1515/aslh-2017-0007 Search in Google Scholar

Bolla, B., Szabó, A., 2020. A NAIK-ERTI hidro-meteorológiai monitoring rendszerének kezdeti eredményei a 2019. évi mérések alapján. [Early results of the naric-fri hydrological and meteorological monitoring system.] Erdészettudományi közlemények, 10, 41–54. (In Hungarian.)10.17164/EK.2020.004 Search in Google Scholar

Bosch, J.M.., Hewlett, J.D., 1982. A review of catchment experiments to determine the effect of vegetation changes on water yield and evapotranspiration. Journal of Hydrology, 55, 3–23.10.1016/0022-1694(82)90117-2 Search in Google Scholar

Csatári, B., 1994. A Duna-Tisza közi hátság településfejlődése és hatásai a vízháztartásra. In: Pálfai, I. (Ed.): A Duna-Tisza közi hátság vízgazdálkodási problémái. Nagyalföld Alapítvány, Békéscsaba, pp. 33–37. Search in Google Scholar

Calder, I.R., 1998. Water use by forests, limits and controls. Tree Physiology, 18, 625–631.10.1093/treephys/18.8-9.62512651351 Search in Google Scholar

Csáki, P., 2020. A klímaváltozás hatása a vízkészletekre a felszínborítás figyelembevételével. [Climate change impacts on water resources in the context of land cover types.] PhD Thesis. University of Sopron, Hungary. (In Hungarian.) Search in Google Scholar

Dean, J.F., Webb, J.A., Jacobsen, G.E., Chisari, R., Dresel, P.E., 2015. A groundwater recharge perspective on locating tree plantations within low-rainfall catchments to limit water resource losses. Hydrology and Earth System Sciences, 19, 1107–1123.10.5194/hess-19-1107-2015 Search in Google Scholar

Dean, A.J., Fielding, K.S., Newton, F.J., 2016. Community knowledge about water: Who has better knowledge and is this associated with water-related behaviors and support for water-related policies? PLoS ONE., 11, e0159063.10.1371/journal.pone.0159063494886227428372 Search in Google Scholar

Engel, V., Jobbágy, E.G., Stieglitz, M., Williams, M., Jackson, R.B., 2005. Hydrological consequences of Eucalyptus afforestation in the Argentine Pampas. Water Resources Research, 41, W10409.10.1029/2004WR003761 Search in Google Scholar

Fan, Y., Miguez-Macho, G., Jobbágy, E.G., Jackson, R.B., Otero-Casal, C., 2017. Hydrologic regulation of plant rooting depth. Proceedings of the National Academy of Sciences, 114, 10572.10.1073/pnas.1712381114563592428923923 Search in Google Scholar

Famiglietti, J.S., Lo, M., Ho, S.L., Bethune, J., Anderson, K.J., Syed, T.H., Swenson, S.C., de Linage, C.R., Rodell, M., 2011. Satellites measure recent rates of groundwater depletion in California’s Central Valley. Geophysical Research Letters, 38, L03403.10.1029/2010GL046442 Search in Google Scholar

Famiglietti, J.S., 2014. The global groundwater crisis. Nature Climate Change, 4, 945–948.10.1038/nclimate2425 Search in Google Scholar

Farley, K.A., Jobbagy, E.G., Jackson, R.B., 2005. Effects of afforestation on water yield: A global synthesis with implications for policy. Global Change Biology, 11, 1565–1576.10.1111/j.1365-2486.2005.01011.x Search in Google Scholar

Gácsi, Zs., 2000. A talajvízszint észlelés, mint hagyományos, s a vízforgalmi modellezés, mint új módszer Alföldi erdeink vízháztartásának vizsgálatában. [Groundwater monitoring as a traditional method and hydrological modeling as a new method in the investigation of the water balance of Great Hungarian Plain forests.] PhD Thesis. University of West Hungary, Sopron, Hungary. (In Hungarian.) Search in Google Scholar

Gőbölös, A., 2002. A „vízhiányos” erdőgazdálkodás kérdései a Duna Tisza közi homokháton. [The problems of “arid” forest management on the sand ridge of the Duanube-Tisza inter-fluve.] Hidrológiai Közlöny, 82, 324–326. (In Hungarian.) Search in Google Scholar

Gribovszki, Z., Kalicz, P., Balog K., Szabó A., Tóth, T., 2014. Comparison of groundwater uptake and salt dynamics of an oak forest and of a pasture on the Hungarian Great Plain. Acta Silvatica et Lignaria Hungarica, 10, 1, 103–114.10.2478/aslh-2014-0008 Search in Google Scholar

Horton, J., Hart, S.C., 1998. Hydraulic lift: a potentially important ecosystem process. Trends in Ecology & Evolution, 13, 232–235.10.1016/S0169-5347(98)01328-7 Search in Google Scholar

Ijjász, E., 1939. A fatenyészet és az altalajvíz, különös tekintettel a nagyalföldi viszonyokra. [Arboriculture and ground-water, with particular focus on the conditions of the Great Plain.] Erdészeti Kísérletek, 42, 1–107. (In Hungarian.) Search in Google Scholar

Ilstedt, U., Bargués Tobella, A., Bazié, H.R., Bayala, J., Verbeeten, E., Nyberg, G., Sanou, J., Benegas, L., Murdiyarso, D., Laudon, H., Sheil, D., Malmer, A., 2016. Intermediate tree cover can maximize groundwater recharge in the seasonally dry tropics. Scientific Reports, 6, 21930.10.1038/srep21930476494126908158 Search in Google Scholar

Jackson, R.B., 1999. The importance of root distributions for hydrology, biogeochemistry andecosystem functioning. In: Tenhunen, J.D., Kabat, P. (Eds.): Integrating Hydrology, Ecosystem Dynamics and Biogeochemistry in Complex Landscapes. John Wiley. Hoboken, N.J., USA, pp. 219–240. Search in Google Scholar

Járó, Z., 1981. A hazai erdôk vízfogyasztása. [Water consumption of Hungarian forests.] Agrártudományi közlemények, 40, 353–356. Search in Google Scholar

Járó, Z., 1992. A talaj szerepe az Alföldfásítás múltjában és jövőjében. In: Rakonczai, J. (Ed.): Az Alföld fásítása. A Nagyalföld alapítvány kötetei 2. Nagyalföld alapítvány, Békéscsaba, pp. 41–46. Search in Google Scholar

Jobbágy, E.G., Jackson, R.B., 2004. Groundwater use and salinization with grassland afforestation. Global Change Biology, 10, 1299–1312.10.1111/j.1365-2486.2004.00806.x Search in Google Scholar

Kárász, I., 1986. Gyökérvizsgálatok Magyarországon. [Root studies in Hungary.] Botanikai közlemények, 73, 19–23. (In Hungarian.) Search in Google Scholar

Kelliher, F.M., Leuning, R., Schultze, E.D., 1993. Evaporation and canopy characteristics of coniferous forests and grasslands. Oecologia, 95, 153–163.10.1007/BF0032348528312937 Search in Google Scholar

Kohán, B., 2014. GIS-alapú vizsgálat a Duna–Tisza közi homokhátság szárazodásának témakörében. [GIS-based Analyses of the Aridification of the Danube-Tisza Inter-fluve.] PhD Thesis. Eötvös Lóránd Science University, Budapest, Hungary. (In Hungarian.) Search in Google Scholar

Kovács, G., 1984. Az ásványi nyersanyagtermelés hatása a felszíni és felszínalatti vizekre. [Geographical and social impacts of production and utilisation of mineral raw materials.] Időjárás, 88, 345–358. (In Hungarian.) Search in Google Scholar

Li, Y., Zhao, M., Motesharrei, S., Mu, Q., Kalnay E., Li, S., 2015. Local cooling and warming effects of forests based on satellite observations. Nature Communications, 6, 6603.10.1038/ncomms7603438923725824529 Search in Google Scholar

Loheide, S.P., Butler, J.J., Gorelick, S.M., 2005. Estimation of groundwater consumption by phreatophytes using diurnal water table fluctuations: A saturated-unsaturated flow assessment. Water Resources Research, 41, W07030.10.1029/2005WR003942 Search in Google Scholar

Lu, C., Zhao, T., Shi, X., Cao, S., 2016. Ecological restoration by afforestation may increase groundwater depth and create potentially large ecological and water opportunity costs in arid and semiarid China. Journal of Cleaner Production, 176, 1213–1222.10.1016/j.jclepro.2016.03.046 Search in Google Scholar

Magyar, P., 1961. Alföldfásítás II. [Afforesttation of the Great Hungarian Plain. II.] Akadémiai Kiadó. Budapest, 622 p. (In Hungarian.) Search in Google Scholar

Major, P., Neppel, F., 1988. A Duna-Tisza közi talajvízszintsüllyedések. [Groundwater level decrease in the Duna-Tisza interfluve.] Vízügyi közlemények, 70, 605–626. (In Hungarian.) Search in Google Scholar

Major, P., 1993. A Nagy-Alföld talajvízháztartása. [Subsurface hydrological regime of the Great Hungarian Plain] Hidrológia Közlöny, 73, 40–43. (In Hungarian.) Search in Google Scholar

Major, P., 2002. Síkvidéki erdők hatása a vízháztartásra. [The effect of lowland forests on the hydrological regime.] Hidrológiai Közlöny, 82, 319–324. (In Hungarian.) Search in Google Scholar

Mattos, T.S., Oliveira, P.T.S.d., Lucas, M.C., Wendland, E., 2019. Groundwater recharge decrease replacing pasture by Eucalyptus plantation. Water, 2, 11, 1213. Search in Google Scholar

Mátyás, Cs., Sun, G., 2014. Forests in a water limited world under climate change. Environmental Research Letters, 9, 085001.10.1088/1748-9326/9/8/085001 Search in Google Scholar

Meier, R., Schwaab, J., Seneviratne, S.I., Sprenger, M., Lewis. E., Davin, E.L., 2021. Empirical estimate of forestation-induced precipitation changes in Europe. Nature Geoscience, 14, 473–478.10.1038/s41561-021-00773-6 Search in Google Scholar

Móricz, N., 2011. Egy erdő és parlagterület vízforgalmának összehasonlító vizsgálata. [Comparative Water Balance Study of Forest and Fallow Plots.] PhD Thesis. University of West Hungary, Sorpon, Hungary. (In Hungarian.) Search in Google Scholar

Móricz, N., Tóth, T., Balog, K., Szabó, A., Rasztovits, E., Gribovszki, Z., 2016. Groundwater uptake of forest and agricultural land covers in regions of recharge and discharge. iForest, 9, 696–701.10.3832/ifor1864-009 Search in Google Scholar

Musters, P.A.D., Bouten, W., 1999. Assessing rooting depths of an Austrian pine stand by inverse modeling soil water content maps. Water Resources Research, 35, 3041–3048.10.1029/1999WR900173 Search in Google Scholar

Nosetto, M.D., Esteban, E.G., Paruelo, J.M., 2005. Land use change and water losses. The case of grassland afforestation across a soil textural gradient in central Argentina. Global Change Biology, 11, 1101–1117.10.1111/j.1365-2486.2005.00975.x Search in Google Scholar

Nosetto, M.D., Jobbágy, E.G., Tóth, T., Di Bella, C.M., 2007. The effects of tree establishment on water and salt dynamics in naturally salt-affected grasslands. Oecologia, 152, 695–705.10.1007/s00442-007-0694-217356808 Search in Google Scholar

Ouyang, Y., Jin, W., Grace, J.M., Obalum, S.E., Zipperer, W.C., Huang, X., 2019. Estimating impact of forest land on groundwater recharge in a humid subtropical watershed of the Lower Mississippi River Alluvial Valley. Journal of Hydrology: Regional Studies, 26, 100631.10.1016/j.ejrh.2019.100631 Search in Google Scholar

Owuor, S.O., Butterbach-Bahl, K., Guzha, A.C., Rufino, M.C., Pelster, D.E., Díaz-Pinés, E., Breuer, L., 2016. Groundwater recharge rates and surface runoff response to land use and land cover changes in semi-arid environments. Ecological Processes, 5, 16.10.1186/s13717-016-0060-6 Search in Google Scholar

Pálfai, I., 1990. Alapozó szakvélemények a Duna – Tisza közi vízrendezések hatásvizsgálatához. [Fundational reports of experts for the examination of the water management works at the Duna-Tisza interfluve.] VITUKI, Budapest, Hungary. 67 p. (In Hungarian.) Search in Google Scholar

Pálfai, I., 1994. Összefoglaló tanulmány a Duna-Tisza közi talajvízszintsüllyedés okairól és a vízhiányos helyzet javításának lehetőségeiről. [Summary study on the casuses of groundwater decrease and the of improvement possibilities of water deficiency at the Duna-Tisza interfluve.] In: Pálfai, I. (Ed.): A Duna-Tisza közi hátság vízgazdálkodási problémái. [Water management problems of the ridge at the Duna-Tisza interfluve.] Nagyalföld Alapítvány, Békéscsaba, Hungary, pp. 111–126. (In Hungarian.) Search in Google Scholar

Pálfai, I., 2010. A Duna Tisza közi hátság vízgazdálkodási sajátosságai. [Hydrological specifics of the ridge on Duna-Tisza interfluve.] Hidrológiai közlemények, 90, 40–44. (In Hungarian.) Search in Google Scholar

Rakonczai, J., 2011. Az Alföld tájváltozásai és a klímaváltozás. [Landscape changes of the Great Hungarian Plain and the climate change.] In: Rakonczai, J. (Ed.): Környezeti változások és az Alföld. [Environmental changes and the Great Hungarian Plain.] Nagyalföld Alapítvány, Békéscsaba, Hungary, pp. 137–148. (In Hungarian.) Search in Google Scholar

Rakonczai, J., Bódis, K., 2002. A környezeti változások következményei az Alföld felszín alatti vízkészleteiben. [Consequences of environmental changes on the subsurface waters in the Great Hungarian Plain.] In: Mészáros, R., Schweitzer, F., Tóth, J. (Eds.): Jakucs László, a tudós, az ismeretterjesztő és a művész. [László Jakucs researcher, disseminator, artist.] MTA Földrajztudományi Kutatóintézet - SZTE Gazdaságés Társadalomföldrajzi Tanszék, Szeged, Hungary, pp. 227–232. (In Hungarian.) Search in Google Scholar

Radcliffe, D.E., Simunek, J., 2010. Soil Physics with HYDRUS: Modeling and Applications. CRC Press/Taylor & Francis, Boca Raton, FL, USA, 388 p. Search in Google Scholar

Rodell, M., Velicogna, I., Famiglietti, J.S., 2009. Satellite-based estimates of groundwater depletion in India. Nature 460, 999–1002.10.1038/nature0823819675570 Search in Google Scholar

Schenk, H.J., Jackson, R.B. 2002. Rooting depths, lateral root spreads, and belowground/aboveground allometries of plants in water-limited ecosystems. Journal of Ecology, 90, 480–494. Search in Google Scholar

Senitz, S., 2001. Untersuchung und anwendung kurzperiodischer schwankungen des grundwasserspiegels in Thüringen. Grundwasser, 4, 163–173.10.1007/s767-001-8392-6 Search in Google Scholar

Somogyi, S., 1961. Hazánk folyóhálózatának fejlődéstörténeti vázlata. [Development scheme of the river network in Hungary.] Földrajzi közlemények, 85, 25–50. (In Hungarian.) Search in Google Scholar

Sonnenborg, T.O., Christiansen, J.R., Pang, B., Bruge, A., Stisen, S., Gundersen, P., 2017. Analyzing the hydrological impact of afforestation and tree species in two catchments with contrasting soil properties using the spatially distributed model MIKE SHE SWET. Agricultural and Forest Meteorology, 239, 118–133.10.1016/j.agrformet.2017.03.001 Search in Google Scholar

Stefanovits, P., Filep, Gy., Füleky, Gy., 1999. Soil science (University textbook) Talajtan. Mezõgazda Kiadó, Budapest, Hungary, 470 p. Search in Google Scholar

Stokes, A., Fourcaud, T., Hruska, J., Cermak, J., Nadyezhdhina, N., Nadyezhdin, V., Praus L., 2002. An evaluation of different methods to investigate root systems architecture of urban trees in situ: I. Ground penetrating radar. Journal of Arbori-culture., 28, 1, 2–10.10.48044/jauf.2002.001 Search in Google Scholar

Szilágyi, J., Vörösmarty, Ch., 1993. A Duna–Tisza közi talajvízszint-süllyedések okainak vizsgálata. [Investigation of the causes behind the groundwater decline at Duna-Tisza interfluve.] Vízügyi közlemények, 75, 280–294. (In Hungarian.) Search in Google Scholar

Szilágyi, J., Kovács, Á., Józsa, J., 2012. Remote-sensing based groundwater recharge estimates in the Danube-Tisza sand plateau region of Hungary. Journal of hydromechanics, 60, 64−72.10.2478/v10098-012-0006-3 Search in Google Scholar

Szinetár, M.M., Csáki, P., Keve, G., Gribovszki, Z., 2018. Változó klimatikus viszonyok hatásai a vízháztartási mérlegre: Esettanulmány a Bácsbokodi-Kígyós vízgyűjtőjén. [Effects of the changing climatic conditions on the water balance - Case study on the Bácsbokodi-Kígyós watershed.] Hidrológiai Közlöny, 98, 50–59. (In Hungarian.) Search in Google Scholar

Szodfridt, I., 1990. Hozzászólás Major Pál és Neppel Ferenc: „A Duna–Tisza közi talajvízszint süllyedése” című cikkéhez. [Comments on paper “Groundwater decline at Duna-Tisza interfluve” by Pál Major and Ferenc Neppel.] Vízügyi közlemények, 72, 287–291. (In Hungarian.) Search in Google Scholar

Tóth, T., Balog, K., Szabó, A., Pásztor, L., Jobbágy, E.G., Nosetto, M.D., Gribovszki, Z., 2014. Influence of lowland forests on subsurface salt accumulation in shallow ground-water areas. AoB PLANTS, 6, plu054.10.1093/aobpla/plu054424025025228311 Search in Google Scholar

Tölgyesi, Cs., Török, P., Hábenczyus, A.A., Bátori, Z., Valkó, O., Deák, B., Tóthmérész, B., Erdős, L., Kelemen, A., 2020. Underground deserts below fertility islands? Woody species desiccate lower soil layers in sandy drylands. Ecography, 43, 848–859.10.1111/ecog.04906 Search in Google Scholar

UNEP, 1992. World Atlas of Desertification. Middleton, N., Thomas, D.S.G. (Eds.). Edward Arnold, London, UK, 69 p. Search in Google Scholar

Völgyesi, I., 2006. A Homokhátság felszín alatti vízháztartása – vízpótlási és vízvisszatartási lehetőségek. [Subsurface hydrological regime of the Homokhátság region - possibilities of water replacement and retention.] MHT XXIV. Országos Vándgyűlés Kiadványa, Pécs, Hungary. (In Hungarian.) Search in Google Scholar

Wang, G., Lin, N., Zhou, X., Li, Z., Deng, X., 2018. Three-stage data envelopment analysis of agricultural water use efficiency: A case study of the Heihe River basin. Sustainability, 10, 568.10.3390/su10020568 Search in Google Scholar

White, W.N., 1932. Method of estimating groundwater supplies based on discharge by plantsand evaporation from soil -results of investigation in Escalante Valley, Utah. US. Geological Survey, Water Supply Paper, 659-A, 1–105. Search in Google Scholar

Wilske, B., Lu, N., Wei, L., Chen, S., Zha, T., Liu, C., Xu, W., Noormets, A., Huang, J., Wei, Y., Chen, J., Zhang, Z., Ni, J., Sun, G., Guo, K., McNulty, S., John, R., Han, X., Lin, G., Chen, J., 2009. Poplar plantation has the potential to alter the water balance in semiarid Inner Mongolia. Journal of Environmental Management, 90, 2762–2770.10.1016/j.jenvman.2009.03.00419375215 Search in Google Scholar

Wu, W.Y., Lo, M.H., Wada, Y., Famiglietti, J.S., Reager, J.T., Yeh, P.J.F., Ducharne, A., Yang, Z.L., 2020. Divergent effects of climate change on future groundwater availability in key mid-latitude aquifers. Nature Communications, 11, 3710.10.1038/s41467-020-17581-y738246432709871 Search in Google Scholar

Xanke, J., Liesch, T., 2022. Quantification and possible causes of declining groundwater resources in the Euro-Mediterranean region from 2003 to 2020. Hydrogeology Journal, 30, 379–400.10.1007/s10040-021-02448-3 Search in Google Scholar

Zemp, D.C., Schleussner C.F., Barbosa, H.M.J., Hirota, M., Montade, V., Sampaio, G., Staal, A., Wang-Erlandsson, L., Rammig, A., 2017. Self-amplified Amazon forest loss due to vegetation – atmosphere feedbacks. Nature Communications, 8, 14681.10.1038/ncomms14681535580428287104 Search in Google Scholar

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