This work is licensed under the Creative Commons Attribution 4.0 International License.
Allen D.J., Darling W.G., Gooddy D.C., Lapworth D.J., Newell A.J., Williams A.T., Allen D., Abesser C., 2010. Interaction between groundwater, the hyporheic zone and a Chalk stream: A case study from the River Lambourn, UK. Hydrogeology Journal 18: 1125–1141. DOI 10.1007/s10040-010-0592-2.AllenD.J.DarlingW.G.GooddyD.C.LapworthD.J.NewellA.J.WilliamsA.T.AllenD.AbesserC.2010Interaction between groundwater, the hyporheic zone and a Chalk stream: A case study from the River Lambourn, UK181125114110.1007/s10040-010-0592-2Open DOISearch in Google Scholar
Amoros C., Gilbert J., Greenwood M.T., 1996. Interactions between units of the fluvial hydrosystem. In: Petts G.E., Amoros C. (eds), Fluvial Hydrosystems. Chapman & Hall, London, New York: 84–210.AmorosC.GilbertJ.GreenwoodM.T.1996Interactions between units of the fluvial hydrosystemIn:PettsG.E.AmorosC.(eds),Chapman & HallLondon, New York8421010.1007/978-94-009-1491-9_9Search in Google Scholar
Battin T.J., Kaplan L.A., Newbold J.D., Hendricks S.P., 2003. A mixing model analysis of stream solute dynamics and the contribution of a hyporheic zone to ecosystem function. Freshwater Biology 48: 995–1014.BattinT.J.KaplanL.A.NewboldJ.D.HendricksS.P.2003A mixing model analysis of stream solute dynamics and the contribution of a hyporheic zone to ecosystem function48995101410.1046/j.1365-2427.2003.01062.xSearch in Google Scholar
Bencala K.E., 2000. Hyporheic zone hydrological processes. Hydrological Processes 14: 2797–2798.BencalaK.E.2000Hyporheic zone hydrological processes142797279810.1002/1099-1085(20001030)14:15<2797::AID-HYP402>3.0.CO;2-6Search in Google Scholar
Bestland E., George A., Greenc G., Olifenta V., Mackay D., Whalen M., 2017. Groundwater dependent pools in seasonal and permanent streams in the Clare Valley of South Australia. Journal of Hydrology, Regional Studies 9: 216–235. DOI 10.1016/j.ejrh.2016.12.087.BestlandE.GeorgeA.GreencG.OlifentaV.MackayD.WhalenM.2017Groundwater dependent pools in seasonal and permanent streams in the Clare Valley of South Australia921623510.1016/j.ejrh.2016.12.087Open DOISearch in Google Scholar
Bhaskar A.S., Harvey J.W., Henry E.J., 2012. Resolving hyporheic and groundwater components of streambed water flux using heat as a tracer. Water Resource Research 48: W08524. DOI 10.1029/2011WR011784.BhaskarA.S.HarveyJ.W.HenryE.J.2012Resolving hyporheic and groundwater components of streambed water flux using heat as a tracer48W0852410.1029/2011WR011784Open DOISearch in Google Scholar
Biksey T.M., Gross E.D., 2001. The Hyporheic zone: Linking groundwater and surface water – Understanding the Paradigm. Remediation 12(1): 55–62.BikseyT.M.GrossE.D.2001The Hyporheic zone: Linking groundwater and surface water – Understanding the Paradigm121556210.1002/rem.1025Search in Google Scholar
Błachuta J., Picińska-Fałtynowicz J., Czoch K., Kulesza K., 2010. Abiotyczne typy wód płynących w Polsce. Gospodarka Wodna 5.BłachutaJ.Picińska-FałtynowiczJ.CzochK.KuleszaK.2010Gospodarka Wodna5Search in Google Scholar
Boano F., Harvey J.W., Marion A., Packman A.I., Revelli R., Ridolfi L., Wörman A., 2014. Hyporheic flow and transport processes: Mechanisms, models, and biogeochemical implications. Reviews of Geophysics 52: 603–679. DOI 10.1002/2012RG000417.BoanoF.HarveyJ.W.MarionA.PackmanA.I.RevelliR.RidolfiL.WörmanA.2014Hyporheic flow and transport processes: Mechanisms, models, and biogeochemical implications5260367910.1002/2012RG000417Open DOISearch in Google Scholar
Boano F., Revelli R., Ridolfi L., 2007. Bedform-induced hyporheic exchange with unsteady flows. Advances in Water Resources 30: 148–156.BoanoF.RevelliR.RidolfiL.2007Bedform-induced hyporheic exchange with unsteady flows3014815610.1016/j.advwatres.2006.03.004Search in Google Scholar
Boulton A.J., 2007. Hyporheic rehabilitation in rivers: Restoring vertical connectivity. Freshwater Biology 52: 632–650.BoultonA.J.2007Hyporheic rehabilitation in rivers: Restoring vertical connectivity5263265010.1111/j.1365-2427.2006.01710.xSearch in Google Scholar
Boulton A.J., Datry T., Kasahara T., Mutz M., Stanford J.A., 2010. Ecology and management of the hyporheic zone: Stream-groundwater interactions of running waters and their floodplains. Journal of the North American Benthological Society 29: 26–40. DOI 10.1899/08-017.1.BoultonA.J.DatryT.KasaharaT.MutzM.StanfordJ.A.2010Ecology and management of the hyporheic zone: Stream-groundwater interactions of running waters and their floodplains29264010.1899/08-017.1Open DOISearch in Google Scholar
Briggs M.A., Lautz L.K., McKenzie J.M., Gordon R.P., Hare D., 2012. Using high-resolution distributed temperature sensing to quantify spatial and temporal variability in vertical hyporheic flux. Water Resource Research 48: W02527. DOI 10.1029/2011WR011227.BriggsM.A.LautzL.K.McKenzieJ.M.GordonR.P.HareD.2012Using high-resolution distributed temperature sensing to quantify spatial and temporal variability in vertical hyporheic flux48W0252710.1029/2011WR011227Open DOISearch in Google Scholar
Cardenas M.B., Wilson J.L., 2007. Exchange across a sediment–water interface with ambient groundwater discharge. Journal of Hydrology 346: 69–80.CardenasM.B.WilsonJ.L.2007Exchange across a sediment–water interface with ambient groundwater discharge346698010.1016/j.jhydrol.2007.08.019Search in Google Scholar
Czarnecka H., 2005. Atlas of the hydrographic division of Poland. Polish Institute of Meteorology and Water Management – National Research Institute, Warsaw, Poland.CzarneckaH.2005Polish Institute of Meteorology and Water Management – National Research InstituteWarsaw, PolandSearch in Google Scholar
Dahm C.N., Grimm N.B., Marmonier P., Valett H.M., Vervier P., 1998. Nutrient dynamics at the interface between surface waters and groundwaters. Freshwater Biology 40: 427–451.DahmC.N.GrimmN.B.MarmonierP.ValettH.M.VervierP.1998Nutrient dynamics at the interface between surface waters and groundwaters4042745110.1046/j.1365-2427.1998.00367.xSearch in Google Scholar
Dubaniewicz H., 1974. Climate of the Łódź Voivodeship. Acta Geographica Lodziensia, 34.DubaniewiczH.1974Climate of the Łódź Voivodeship34Search in Google Scholar
Fetter C.W., 2001. Applied hydrogeology. Prentice Hall, Upper Saddle River, NJ.FetterC.W.2001Prentice HallUpper Saddle River, NJSearch in Google Scholar
Gerecht K.E., Bayani Cardenas M., Guswa A.J., Sawyer A.H., Nowinski J.D., Swanson T.E., 2011. Dynamics of hyporheic flow and heat transport across a bed-to-bank continuum in a large regulated river. Water Resources Research 47: W03524. DOI 10.1029/2010WR009794.GerechtK.E.Bayani CardenasM.GuswaA.J.SawyerA.H.NowinskiJ.D.SwansonT.E.2011Dynamics of hyporheic flow and heat transport across a bed-to-bank continuum in a large regulated river47W0352410.1029/2010WR009794Open DOISearch in Google Scholar
Gooseff M.N., 2010. Defining Hyporheic zones – Advancing our conceptual and operational definitions of where stream water and groundwater meet. Geography Compass 4(8): 945–955. DOI 10.1111/j.1749-8198.2010.00364.x.GooseffM.N.2010Defining Hyporheic zones – Advancing our conceptual and operational definitions of where stream water and groundwater meet4894595510.1111/j.1749-8198.2010.00364.xOpen DOISearch in Google Scholar
Grodzka-Łukaszewska M., Pawlak Z., Sinicyn G., 2021. Spatial distribution of the water exchange through river cross-section – Measurements and the numerical model. Archives of Environmental Protection 47(1): 69–79. DOI 10.24425/aep.2021.136450.Grodzka-ŁukaszewskaM.PawlakZ.SinicynG.2021Spatial distribution of the water exchange through river cross-section – Measurements and the numerical model471697910.24425/aep.2021.136450Open DOISearch in Google Scholar
Grygoruk M., Szałkiewicz Ee., Grodzka-Łukaszewska M., Mirosław-Świątek D., Oglęcki P., Pusłowska-Tyszewska D., Sinicyn G. Okruszko T., 2021. Revealing the influence of hyporheic water exchange on the composition and abundance of bottom-dwelling macroinvertebrates in a temperate lowland river. Knowledge & Management of Aquatic Ecosystems 422 37: 1–9. DOI 10.1051/kmae/2021036.GrygorukM.SzałkiewiczEe.Grodzka-ŁukaszewskaM.Mirosław-ŚwiątekD.OglęckiP.Pusłowska-TyszewskaD.SinicynG.OkruszkoT.2021Revealing the influence of hyporheic water exchange on the composition and abundance of bottom-dwelling macroinvertebrates in a temperate lowland river422371910.1051/kmae/2021036Open DOISearch in Google Scholar
Harvey J.W., Drummond J.D., Martin R.L., McPhillips L.E., Packman A.I., Jerolmack D.J., Stonedahl S.H., Aubeneau A.F., Sawyer A.H., Larsen L.G., Tobias C.R., 2012. Hydrogeomorphology of the hyporheic zone: Stream solute and fine particle interactions with a dynamic streambed. Journal of Geophysical Research 117(G4), G00N11: 1–20. DOI 10.1029/2012JG002043.HarveyJ.W.DrummondJ.D.MartinR.L.McPhillipsL.E.PackmanA.I.JerolmackD.J.StonedahlS.H.AubeneauA.F.SawyerA.H.LarsenL.G.TobiasC.R.2012Hydrogeomorphology of the hyporheic zone: Stream solute and fine particle interactions with a dynamic streambed117G4G00N1112010.1029/2012JG002043Open DOISearch in Google Scholar
Harvey J.W., Wagner B.J., Bencala K.E., 1996. Evaluating the reliability of the stream tracer approach to characterize stream-subsurface water exchange. Water Resources Research 32: 2441–2451. DOI 10.1029/96WR01268.HarveyJ.W.WagnerB.J.BencalaK.E.1996Evaluating the reliability of the stream tracer approach to characterize stream-subsurface water exchange322441245110.1029/96WR01268Open DOISearch in Google Scholar
Hayashi M., Rosenberry D.O., 2002. Effects of ground water exchange on the hydrology and ecology of surface water. Ground Water 40: 309–316.HayashiM.RosenberryD.O.2002Effects of ground water exchange on the hydrology and ecology of surface water4030931610.1111/j.1745-6584.2002.tb02659.x12019646Search in Google Scholar
Jokiel P., 2004. Central Poland's water resources at the threshold of the 21st century. Publishing House of University of Łódź, Łódź.JokielP.2004Publishing House of University of ŁódźŁódźSearch in Google Scholar
Kamiński J., 1993. Late Pleistocene and Holocene transformation of the Moszczenica valley. Acta Geographica Lodziensia 64.KamińskiJ.1993Late Pleistocene and Holocene transformation of the Moszczenica valley64Search in Google Scholar
Kasahara T., Datry T., Mutz M., Boulton A.J., 2009. Treating causes not symptoms: Restoration of surface-groundwater interactions in rivers. Marine and Freshwater Research 60: 976–981.KasaharaT.DatryT.MutzM.BoultonA.J.2009Treating causes not symptoms: Restoration of surface-groundwater interactions in rivers6097698110.1071/MF09047Search in Google Scholar
Lewandowski J., Arnon S., Banks E., Batelaan O., Betterle A., Broecker T., Coll C., Drummond J.D., Gaona Garcia J., Galloway J., Gomez-Velez J., Grabowski R. C., Herzog S.P., Hinkelmann R., Höhne A., Hollender J., Horn M.A., Jaeger A., Krause S., Prats A.L., Magliozz C., Meinikmann K., Babak Mojarrad B., Mueller B.M., Peralta-Maraver I., Popp A.L., Posselt M., Putschew A., Radke M., Raza M., Riml J., Robertson A., Rutere C., Schaper J.L., Schirmer M., Schulz H., Shanafield M., Singh T., Ward A.S., Wolke P., Wörman A., Wu L., 2019. Is the hyporheic zone relevant beyond the scientific community? Water 11: 2230. DOI 10.3390/w11112230.LewandowskiJ.ArnonS.BanksE.BatelaanO.BetterleA.BroeckerT.CollC.DrummondJ.D.Gaona GarciaJ.GallowayJ.Gomez-VelezJ.GrabowskiR. C.HerzogS.P.HinkelmannR.HöhneA.HollenderJ.HornM.A.JaegerA.KrauseS.PratsA.L.MagliozzC.MeinikmannK.Babak MojarradB.MuellerB.M.Peralta-MaraverI.PoppA.L.PosseltM.PutschewA.RadkeM.RazaM.RimlJ.RobertsonA.RutereC.SchaperJ.L.SchirmerM.SchulzH.ShanafieldM.SinghT.WardA.S.WolkeP.WörmanA.WuL.2019Is the hyporheic zone relevant beyond the scientific community?11223010.3390/w11112230Open DOISearch in Google Scholar
Malzone J.M., Anseeuw S.K., Lowry Ch., S., Allen-King R., 2016. Temporal Hyporheic zone response to water table fluctuations. Groundwater 54: 274–285.MalzoneJ.M.AnseeuwS.K.LowryCh. S.Allen-KingR.2016Temporal Hyporheic zone response to water table fluctuations5427428510.1111/gwat.1235226096382Search in Google Scholar
Marciniak M., Chudziak Ł., 2015. A new method of measuring the hydraulic conductivity of the bottom sediment. Przegląd Geologiczny 63: 919–925.MarciniakM.ChudziakŁ.2015A new method of measuring the hydraulic conductivity of the bottom sediment63919925Search in Google Scholar
Marzadri A., Tonina D., Bellin A., Valli A., 2016. Mixing interfaces, fluxes, residence times and redox 1 conditions of the hyporheic zones induced by dune-like 2 bedforms and ambient groundwater flow. Advances in Water Resources 88: 139–151. DOI 10.1016/j.advwatres.2015.12.014.MarzadriA.ToninaD.BellinA.ValliA.2016Mixing interfaces, fluxes, residence times and redox 1 conditions of the hyporheic zones induced by dune-like 2 bedforms and ambient groundwater flow8813915110.1016/j.advwatres.2015.12.014Open DOISearch in Google Scholar
Pazdro Z., Kozerski B., 1990. General hydrogeology. Wydawnictwa Geologiczne, Warszawa.PazdroZ.KozerskiB.1990Wydawnictwa GeologiczneWarszawaSearch in Google Scholar
Song J., Jiang W., Xu S., Zhang G., Wang L., Wen M., Zhang B., Wang Y., Long Y., 2016. Heterogeneity of hydraulic conductivity and Darcian flux in the submerged streambed and adjacent exposed stream bank of the Beiluo River, northwest China. Hydrogeology Journal 24: 2049–2062. DOI 10.1007/s10040-016-1449-0.SongJ.JiangW.XuS.ZhangG.WangL.WenM.ZhangB.WangY.LongY.2016Heterogeneity of hydraulic conductivity and Darcian flux in the submerged streambed and adjacent exposed stream bank of the Beiluo River, northwest China242049206210.1007/s10040-016-1449-0Open DOISearch in Google Scholar
Sophocleous M., 2002. Interactions between groundwater and surface water: The state of the science. Hydrogeological Journal 10: 52–67.SophocleousM.2002Interactions between groundwater and surface water: The state of the science10526710.1007/s10040-001-0170-8Search in Google Scholar
Stelzer R.S., Bartsch L.A., Richardson W.B., Strauss E.A., 2011. The dark side of the hyporheic zone: Depth profiles of nitrogen and its processing in stream sediments. Freshwater Biology 56: 2021–2033. DOI 10.1111/j.1365-2427.2011.02632.x.StelzerR.S.BartschL.A.RichardsonW.B.StraussE.A.2011The dark side of the hyporheic zone: Depth profiles of nitrogen and its processing in stream sediments562021203310.1111/j.1365-2427.2011.02632.xOpen DOISearch in Google Scholar
Storey R.G., Howard K.W.F., Williams D.D., 2003. Factors controlling riffle-scale hyporheic exchange flows and their seasonal changes in a gaining stream: A three-dimensional groundwater flow model. Water Resources Research 39(2), 1034. DOI 10.1029/2002WR001367.StoreyR.G.HowardK.W.F.WilliamsD.D.2003Factors controlling riffle-scale hyporheic exchange flows and their seasonal changes in a gaining stream: A three-dimensional groundwater flow model392103410.1029/2002WR001367Open DOISearch in Google Scholar
Szczepański W., 1995. Atlas of water gauges for the needs of state environmental monitoring. Inspection for Environmental Protection, Warsaw.SzczepańskiW.1995Inspection for Environmental ProtectionWarsawSearch in Google Scholar
Tonina D., 2012. Surface water and streambed sediment interaction: The hyporheic exchange, in Fluid Mechanics of Environmental Interfaces. In: Gualtieri C., Mihailović D.T. (eds), Fluid mechanics of environmental interfaces. CRC Press, Taylor and Francis Group, London: 255–294.ToninaD.2012Surface water and streambed sediment interaction: The hyporheic exchange, in Fluid Mechanics of Environmental InterfacesIn:GualtieriC.MihailovićD.T.(eds),CRC Press, Taylor and Francis GroupLondon25529410.1201/b13079-13Search in Google Scholar
Tonina, D., Buffington J.M., 2007. Hyporheic exchange in gravel bed rivers with pool-riffle morphology: Laboratory experiments and three-dimensional modeling, Water Resources Research 43: W01421. DOI 10.1029/2005WR004328.ToninaD.BuffingtonJ.M.2007Hyporheic exchange in gravel bed rivers with pool-riffle morphology: Laboratory experiments and three-dimensional modeling43W0142110.1029/2005WR004328Open DOISearch in Google Scholar
Toth J., 1963. A theoretical analysis of groundwater flow in small drainage basins. Journal of Geophysical Research 68: 4795–4812. DOI 10.1029/JZ068i016p04795.TothJ.1963A theoretical analysis of groundwater flow in small drainage basins684795481210.1029/JZ068i016p04795Open DOISearch in Google Scholar
Triska F.T., Kennedy V.C., Avanzino R.J., Zellweger G.W., Bencala K.E., 1989. Retention and transport of nutrients in a third-order stream in northwestern California. Hyporheic processes. Ecology 70: 1893–1905.TriskaF.T.KennedyV.C.AvanzinoR.J.ZellwegerG.W.BencalaK.E.1989Retention and transport of nutrients in a third-order stream in northwestern California. Hyporheic processes701893190510.2307/1938120Search in Google Scholar
Winter T.C., Harvey J.W., Franke O.L., Alley W.M., 1998. Ground water and surface Water: A single resource. U.S. Geological Survey Circular 1139.WinterT.C.HarveyJ.W.FrankeO.L.AlleyW.M.1998U.S. Geological Survey Circular1139.10.3133/cir1139Search in Google Scholar
Wondzell S.M., 2011. The role of the Hyporheic zone across stream networks. Hydrological Processes 25(22): 3525–3532. DOI 10.1002/hyp.8119.WondzellS.M.2011The role of the Hyporheic zone across stream networks25223525353210.1002/hyp.8119Open DOISearch in Google Scholar
Wörman A., Packman A.I., Johansson H., Jonsson K., 2002. Effect of flow-induced exchange in Hyporheic zones on longitudinal transport of solutes in streams and rivers. Water Resources Research. 38(1): 2-1–2-15. DOI 10.1029/2001WR000769.WörmanA.PackmanA.I.JohanssonH.JonssonK.2002Effect of flow-induced exchange in Hyporheic zones on longitudinal transport of solutes in streams and rivers3812-12-1510.1029/2001WR000769Open DOISearch in Google Scholar
Wörman A., Wachniew P., 2007. Reach scale and evaluation methods as limitations for transient storage properties in streams and rivers. Water Resources Research. 43(10), W10405: 1–13. DOI 10.1029/2006WR005808.WörmanA.WachniewP.2007Reach scale and evaluation methods as limitations for transient storage properties in streams and rivers4310W1040511310.1029/2006WR005808Open DOISearch in Google Scholar
Wrzesiński D., 2016. Use of entropy in the assessment of uncertainty of river runoff regime in Poland. Acta Geophysica 64: 1825–1839. DOI 10.1515/acgeo-2016-0073.WrzesińskiD.2016Use of entropy in the assessment of uncertainty of river runoff regime in Poland641825183910.1515/acgeo-2016-0073Open DOISearch in Google Scholar
Wrzesiński D., 2017. Regimes of the Polish rivers. In: Jokiel P., Marszelewski W., Pociask-Karteczka J. (eds), Hydrology of Poland. PWN, Warsaw: 215–222.WrzesińskiD.2017Regimes of the Polish riversIn:JokielP.MarszelewskiW.Pociask-KarteczkaJ.(eds),PWNWarsaw215222Search in Google Scholar
Zimmer M.A., Lautz L.K., 2014. Temporal and spatial response of hyporheic zone geochemistry to a storm event. Hydrological Processes 28: 2324–2337. DOI 10.1002/hyp.9778.ZimmerM.A.LautzL.K.2014Temporal and spatial response of hyporheic zone geochemistry to a storm event282324233710.1002/hyp.9778Open DOISearch in Google Scholar