EEA Report No 2/2009: Water Resources Across Europe—Confronting Water Scarcity and Drought. https://doi.org/10.2800/16803 (Office for Official Publications of the European Communities, 2009).
Ochrona środowiska 2020 (Environmental Protection 2020). Główny Urząd Statystyczny, Warszawa (2021).
Łabędzki, L. Actions and measures for mitigation drought and water scarcity in agriculture. J. Water Land Dev. 29, 3–10. https://doi.org/10.1515/jwld-2016-0007 (2016).
National Water Management Authority (Krajowy Zarząd Gospodarki Wodnej). Diagnoza Aktualnego Stanu Gospodarki Wodnej. Załącznik 1 do Projektu Polityki Wodnej Państwa 2030 (Z Uwzględnieniem Etapu 2016) (Diagnosis of the Current State of Water Management. Annex 1 to the Draft National Water Policy 2030 (Including the 2016 Stage). Krajowy Zarząd Gospodarki Wodnej, Warszawa. http://web.archive.org/web/20170224005129/http://kzgw.gov.pl/files/file/Programy/PPWP2030/ZALACZNIK_tabela.pdf Accessed 29 Dec 2019. (2010).
Drabiński, A., Radczuk, L., Mokwa, M., Nyc, K., Markowska, J., Jawecki, B. & Maczewska B. Program Małej Retencji Wodnej w Województwie Dolnośląskim (Programme of Small-Scale Water Retention in the Lower Silesian Voivodeship). Monografia. (eds. Drabiński, A., Mokwa, M., Radczuk, L.) (UP we Wrocławiu, Centrum Modelowania Procesów Hydrologicznych, 2008).
Mioduszewski, W. Small (natural) water retention in rural areas. J. Water Land Dev. 20, 19–29 (2014).
Mosiej, J. Sustainable rural development policy in Poland—Environmental aspects. Acta Region. Environ. 2, 65–75 (2014).
Ochrona Środowiska 2018 (Environmental Protection 2018). Główny Urząd Statystyczny, Warszawa (2019).
Mioduszewski, W., Querner, E. P. & Kowalewski, Z. The analysis of the impact of small retention on water resources in the catchment. J. Water Land Dev. 23, 41–51. https://doi.org/10.1515/jwld-2014-0028 (2014).
Patro, M. & Zubala, T. Possibilities of shaping the water retention in agricultural landscape. Teka Kom. Ochr. Kszt. Środ. Przyr.-OL PAN 9, 143–152 (2012).
Ciupa, T., Suligowski, R. & Biernat, T. The conditions for the location of small water retention reservoirs in Świętokrzyskie Mountains (Poland). Гiдpoлoгiя, гiдpoxiмiя i гiдpoeкoлoгiя (Hydrol. Hydrochem. Hydroecol.) 31, 16–24 (2013).
EC. Natural Water Retention Measures. Science for Environment Policy. Iss. 32. 1–42 (2012).
Gomez, C.M., Colentine, D., Delacamara, G., Strosspr, P., Iacovides, A., Kinell, G., Söderquist, T., Ungvari, G. & Fribourg-Blanc, B. Concept Note. Natural Water Retention Measures (NWRM) and the WFD and Other Daughter Directives (Online). http://nwrm.eu/sites/default/files/documents-docs/nwrmconceptnote_to_regional_stakeholders.pdf . Accessed 29 Dec 2016 (2013).
Jawecki, B., Dąbek, P. B., Pawęska, K. & Wei, X. Estimating water retention in post-mining excavations using LiDAR ALS data for the Strzelin Quarry, Lower Silesia. Mine Water Environ. 37, 744–753. https://doi.org/10.1007/s10230-018-0526-0 (2018).
Cherlet, M. et al. (eds) World Atlas of Desertification (Publication Office of the European Union, 2018).
Cao, X. Regulating mine land reclamation in developing countries: The case of China. Land Use Policy 24, 472–483 (2007).
Kaźmierczak, U., Lorenc, M. W. & Strzałkowski, P. The analysis of the existing terminology related to a post-mining land use: A proposal for new classification. Environ. Earth Sci. 76, 693. https://doi.org/10.1007/s12665-017-6997-7 (2017).
Kemmis, T.J., Bauer, R.A. & Lasemi III, Z. (Eds.) Surface mine reclamation. in Geology of Illinois (Dennis, R., Kolata, C., Nimz, K. Eds.) (Illinois State Geological Survey, 2010).
Ostręga, A. & Uberman, R. Kierunki rekultywacji i zagospodarowania—Sposób wyboru, klasyfikacja i przykłady (Modes of reclamation and redevelopment—Manner of choice, classification and examples). Górnictwo Geoinżyn. 34, 445–461 (2010).
Paulo, A. Przyrodnicze ograniczenia wyboru kierunku zagospodarowania terenów pogórniczych (Natural constraints of choosing determined directions of post-mining development). Gospod. Surowcami Miner. 24, 9–40 (2008).
Kasztelewicz, Z. & Sypniowski, S. Rekultywacja w polskim górnictwie odkrywkowym węgla brunatnego (Reclamation in Polish opencast brown coal mining). Górnictwo Geoinżyn. 34(4), 289–304 (2010).
Hüttl, R. F. & Weber, E. Forest ecosystem development in post-mining landscapes: A case study of the Lusatian lignite district. Naturwissenschaften 88, 322–329. https://doi.org/10.1007/s001140100241 (2001).
Castendyk, D. & Eary, T. The nature and global distribution of pit lakes. in Mine Pit Lakes: Characteristics, Predictive Modeling, and Sustainability (Castendyk, D., Eary, T., Park, B., Eds.). 1–11. (Society for Mining Engineering, 2009).
Dong-Dong, Z., Yu-shan, S. & Le, L. Study on sustainable landscape design of abandoned quarries: An example: Zhushan ecological park in Xuzhou. Proc. Earth Planet. Sci. 1, 1107–1113. https://doi.org/10.1016/j.proeps.2009.09.170 (2009).
Duval, T. P., Waddington, J. M. & Branfireun, B. A. Towards calcareous wetland creation in flooded abandoned aggregate quarries: A 3-year field mesocosm study. Ecol. Eng. 36, 586–595. https://doi.org/10.1016/j.ecoleng.2009.12.006 (2010).
Nita, J. Quarries in landscape and geotourism. Geogr. Pol. 85, 5–12 (2012).
Doupé, R. G. & Lymbery, A. J. Environmental risks associated with beneficial end uses of mine lakes in southwestern Australia. Mine Water Environ. 24(3), 134–138 (2005).
Jawecki, B., Lorenc, M. W. & Tokarczyk-Dorociak, K. Quarries in landscape of Strzelin County—Native rock materials in local architecture. Z. Dt. Ges. Geowiss. (German J. Geosci.) 166(2), 205–225. https://doi.org/10.1127/1860-1804/2014/0011 (2015).
Kasztelewicz, Z. Rekultywacja Terenów Pogórniczych w Polskich Kopalniach Odkrywkowych; (Reclamation of Post-Mining Areas in Polish Open-Cast Mines). (Fund. Nauka i Tradycje Górn. AGH, 2010).
Popović, S. G., Vukanić, S., Komatina, D. F., Alihodzic-Jasarevic, E. & Vatin, N. Models of landscape shaping in exploited quarries of urban area. Proc. Eng. 117, 609–615. https://doi.org/10.1016/j.proeng.2015.08.221 (2015).
Soni, A. K., Mishra, B. & Singh, S. Pit lakes as an end use of mining: A review. J. Min. Environ. 5(2), 99–111 (2014).
Jawecki, B., Szewrański, S., Stodolak, R. & Wang, Z. The use of digital terrain models to estimate the pace of filling the pit of a Central European granite quarry with water. Water 11, 2298. https://doi.org/10.3390/w11112298 (2019).
Kumar, R. N., McCullough, C. D. & Lund, M. A. Water resources in Australian Mine Pit Lakes. Min. Technol. 118, 204–211. https://doi.org/10.1179/174328610X12682159815028 (2009).
McCullough, C. D. Approaches to remediation of acid mine drainage water in pit lakes. Int. J. Min. Reclam. Environ. 22(2), 105–119 (2008).
Vandenberg, J., McCullough, C. & Castendyk, D. Key issues in mine closure planning related to pit lakes. in Proceedings of the 10th International Conference on Acid Rain Drainage & IMWA Annual Conference. April 21–24, 2015 Santiago, Chile (2015).
Baczyńska, E., Lorenc, M. W. & Kaźmierczak, U. Research on the landscape attractiveness of the selected abandoned quarries. Int. J. Min. Reclam. Environ. 32(6), 401–419. https://doi.org/10.1080/17480930.2017.1386756 (2018).
Gandah, F. & Atiyat, D. Re-use of abandoned quarries; case study of eco-tourism and rangers academy—Ajloun—Jordan. J. Civ. Environ. Eng. 6, 238. https://doi.org/10.4172/2165-784X.1000238 (2016).
Hinwood, A. L., Heyworth, J., Tanner, H. & McCullough, C. Recreational use of acidic pit lakes—Human health considerations for post closure planning. J. Water Resour. Prot. 4, 1061–1070. https://doi.org/10.4236/jwarp.2012.412122 (2012).
Kaźmierczak, U. et al. Post-mining remnants and revitalization. Geoheritage 11, 2025. https://doi.org/10.1007/s12371-019-00408-8 (2019).
Kivinen, S. Sustainable post-mining land use: Are closed metal mines abandoned or re-used space?. Sustainability. 9, 1705. https://doi.org/10.3390/su9101705 (2017).
Tokarczyk-Dorociak, K., Lorenc, M. W., Jawecki, B. & Zych-Głuszyńska, K. Post-Industrial landscape transformation and its application for geotourism, education and recreation—An example of the Wide Mt. near Strzegom, Lower Silesia/Poland. Z. Dt. Ges. Geowiss. 166, 195–203 (2015).
Ceppi, A. et al. Real-time drought forecasting system for irrigation management. Hydrol. Earth Syst. Sci. 18, 3353–3366. https://doi.org/10.5194/hess-18-3353-2014 (2014).
Schultze, M., Pokrandt, K.-H. & Hille, W. Pit lakes of the Central German lignite mining district: Creation, morphometry and water quality aspects. Limnology (Limnol.-Ecol. Manag. Inland Waters) 40, 148–155. https://doi.org/10.1016/j.limno.2009.11.006 (2010).
Kumar, R. N., McCullough, C. D., Lund, M. A. & Larranaga, S. A. Assessment of factors limiting algal growth in acidic pit lakes—A case study from Western Australia, Australia. Environ. Sci. Pollut. Res. 23, 5915–5924. https://doi.org/10.1007/s11356-015-5829-0 (2016).
Singleton, V. L., Jacob, B., Feeney, M. T. & Little, J. C. Modeling a proposed quarry reservoir for raw water storage in Atlanta, Georgia. J. Environ. Eng. 139, 70–78. https://doi.org/10.1061/%28ASCE%29EE.1943-7870.0000582 (2013).
Szczepański, J. The significance of groundwater flow modeling study for simulation of opencast mine dewatering, flooding, and the environmental impact. Water 11, 848. https://doi.org/10.3390/w11040848 (2019).
Kleeberg, A. & Grüneberg, B. Phosphorus mobility in sediments of acid mining lakes, Lusatia, Germany. Ecol. Eng. 24, 89–100 (2005).
Clews, E. et al. A pilot macroinvertebrate index of the water quality of Singapore’s reservoirs. Ecol. Ind. 38, 90–103 (2014).
Hayley, K., Valenza, A., White, E., Hutchison, B. & Schumacher, J. Application of the iterative ensemble smoother method and cloud computing: A groundwater modeling case study. Water 11, 1649. https://doi.org/10.3390/w11081649 (2019).
Nixdorf, B., Lessmann, D. & Deneke, R. Mining lakes in a disturbed landscape: Application of the EC Water Framework Directive and future management strategies. Ecol. Eng. 24, 67–73 (2005).
Wachowiak, G. Bilans wodny zbiornika w zalewanym wyrobisku końcowym likwidowanej odkrywki „Lubstów” PAK Kopalnia Węgla Brunatnego Konin S.A. (Water balance of a reservoir in the flooded, abandoned, open pit “Lubstów” PAK Lignite Opencast Mine Konin S.A.). Górnictwo Odkrywkowe 56(6), 68–79 (2015).
Jawecki, B. & Pawłowska, K. Evaluation of the influence of the heavy metals content on the possibility to use the waters from selected Strzelin Quarry Lakes for agricultural irrigation. J. Ecol. Eng. 22(3), 1–10. https://doi.org/10.12911/22998993/132604 (2021).
Jawecki, B., Kowalczyk, T. & Feng, Y. The evaluation of the possibility to use water from quarry lakes for irrigation. J. Ecol. Eng. 20, 188–201. https://doi.org/10.12911/22998993/112490 (2019).
Jawecki, B. & Mirski, J. Wstępna ocena zawartości biogenów w wodach zalanych nieczynnych kamieniołomów położonych na terenach wiejskich (Preliminary evaluation of nutrients concentration in quarry lakes located on the rural areas). Inżyn. Ekol. 19, 1–13. https://doi.org/10.12912/23920629/94957 (2018).
Mollema, P., Antonellini, M., Hubeek, A. & Van Diepenbeek, P. M. J. A The effect of artificial recharge on hydrochemistry: A comparison of two fluvial gravel pit lakes with different post-excavation uses in the Netherlands. Water 8, 409. https://doi.org/10.3390/w8090409 (2016).
McCullough, C. D. & Lund, M. A. Opportunities for sustainable mining pit lakes in Australia. Mine Water Environ. 25, 220–226 (2006).
Ravazzani, G., Giudici, I., Schmidt, C. & Mancini, M. Evaluating the potential of Quarry Lakes for supplemental irrigation. J. Irrig. Drain Eng. 137(8), 564–571. https://doi.org/10.1061/(ASCE)IR.1943-4774.0000321 (2011).
Castendyk, D. N., Mauk, J. L. & Webster, J. G. A mineral quantification method for wall rocks at open-cast mines, and application to the Martha Au–Ag mine, Waihi, New Zealand. Appl. Geochem. 20, 135–156 (2005).
Song, J. & Choi, Y. Analysis of the potential for use of floating photovoltaic systems on mine pit lakes: Case study at the Ssangyong open-pit limestone mine in Korea. Energies 9, 102. https://doi.org/10.3390/en9020102 (2016).
Kasperek, R., Wiatkowski, M. & Rosik-Dulewska, C. Investigations of hydrological regime changes in an area adjacent to a mine of rock raw materials. Annu. Set Environ. Protect. (Rocznik Ochrona Środowiska). 17, 256–274 (2015).
Ministry of the Environment (Ministerstwo Środowiska). Strategiczny Plan Adaptacji dla Sektorów i Obszarów Wrażliwych na Zmiany Klimatu do Roku 2020, z Perspektywą do Roku 2030. Warszawa 2013. (Strategic Adaptation Plan for Sectors and Areas Sensitive to Climate Change Until 2020, with a Perspective Until 2030. Warsaw 2013. https://bip.mos.gov.pl/fileadmin/user_upload/bip/strategie_plany_programy/Strategiczny_plan_adaptacji_2020.pdf. Accessed 29 Dec 2019 (2013).
National Water Management Authority (Krajowy Zarząd Gospodarki Wodnej). Projekt Polityki Wodnej Państwa do Roku 2030 (Z Uwzględnieniem Etapu 2016) (Draft of the State Water Policy Until 2030 (Including the 2016 Stage). http://web.archive.org/web/20170224111551/http://kzgw.gov.pl/files/file/Programy/PPWP2030/PWP_28_09_2011Ms.doc. Accessed 29 Dec 2019 (2011).
Ordinance of the Minister of Infrastructure of July 15, 2021 on the adoption of the Drought Effects Counteracting Plan. (Rozporządzenie Ministra Infrastruktury z dnia 15 lipca 2021 r. w sprawie przyjęcia Planu przeciwdziałania skutkom suszy). Dz.U.2021.1615 (2021).
Regional Water Management Authority in Wrocław (Regionalny Zarząd Gospodarki Wodnej we Wrocławiu). Plan Przeciwdziałania Skutkom Suszy w Regionach Wodnych Środkowej Odry, Izery, Metuje, Łaby i Ostrożnicy (Upa), Orlicy i Morawy (Plan to Counteract the Effects of Drought in the Water Regions of the Middle Odra, Jizera, Metuje, Labe and Ostrożnica (Upa), Orlica and Morava), Warszawa 2017. https://wroclaw.rzgw.gov.pl/files_mce/SUSZA%202017/ppss_wroc_aw_31.08.2017.pdf Accessed 29 Dec 2019 (2017).
State Water Holding—Polish Waters (Państwowe Gospodarstwo Wodne Wody Polskie. Projekt Planu Przeciwdziałania Skutkom Suszy (Draft Plan to Counteract the Effects of Drought). Warszawa, 2019. http://stopsuszy.pl/projekt-planu-przeciwdzialania-skutkom-suszy/. Accessed 29 Dec 2019 (2019).
Bernaciak, A., Spychała, M., Korytowski, M. & Powolna, P. Mała retencja wodna w programach ochrony środowiska gmin nadwarciańskich. Inżyn. Ekol. (Ecol. Eng.). 44, 121–130. https://doi.org/10.12912/23920629/60036 (2015).
Gromiec, M. & Winnicki, T. Projekt polityki wodnej państwa a diagnoza stanu gospodarki wodnej (Draft of water policy of the state and diagnosis of a status of water economy). Annu. Set Environ. Protect. (Rocznik Ochrona Środowiska). 13, 283–302 (2011).
Kowalewski, Z. Actions for small water retention undertaken in Poland. J. Water Land Dev. 12, 155–167 (2008).
Linnerooth-Bayer, J., Dubel, A., Sendzimir, J. & Hochrainer-Stigler, S. Challenges for mainstreaming climate change into EU flood and drought policy: Water retention measures in the Warta River Basin, Poland. Region. Environ. Change 15(6), 1011–1023. https://doi.org/10.1007/s10113-014-0643-7 (2015).
Szczykowska, J. & Siemieniuk, A. The present condition of small water retention and the prospects of its development using the example of the Podlaskie Voivodeship. J. Ecol. Eng. 15(3), 90–96. https://doi.org/10.12911/22998993.1109130 (2014).
Szwed, M. The elements of water balance in the changing climate in Poland. Adv. Meteorol. https://doi.org/10.1155/2015/149674 (2015).
Drabiński, A., Radczuk, L., Nyc, K., Mokwa, M., Olearczyk, B., Markowska, J., Bac-Bronowicz, J., Chmielewska, I., Jawecki, B. & Gromada O. et al. Program Małej Retencji Wodnej w Województwie Dolnośląskim (Programme of Small-Scale Water Retention in the Lower Silesian Voivodeship). http://bip.umwd.dolnyslask.pl/dokument.php?iddok=32376&str=11. Accessed 13 Aug 2019 (2006).
Walczykiewicz, P. et al. Landscape monitoring of post-industrial areas using LiDAR and GIS technology. Geodesy Cartogr. 64(1), 125–137 (2015).
Xiang, J. et al. Quantitative analysis of anthropogenic morphologies based on multi-temporal high-resolution topography. Remote Sens. 11, 1493. https://doi.org/10.3390/rs11121493 (2019).
Labant, S., Staňková, S. & Weiss, R. Geodetic determining of stockpile volume of mineral excavated in open pit mine. GeoSci. Eng. 1(1), 30–40. https://doi.org/10.2478/gse-2014-0049 (2013).
Sayab, M., Aerden, D., Paananen, M. & Saarela, P. Virtual structural analysis of Jokisivu open pit using ‘structure-from-motion’ unmanned aerial vehicles (UAV) photogrammetry: Implications for structurally-controlled gold deposits in southwest Finland. Remote Sens. 10, 1296. https://doi.org/10.3390/rs10081296 (2018).
Esposito, G., Matano, F. & Sacchi, M. Detection and geometrical characterization of a buried landfill site by integrating land use historical analysis, digital photogrammetry and airborne lidar data. Geosciences. 8, 348. https://doi.org/10.3390/geosciences8090348 (2018).
Gong, C. et al. Analysis of the development of an erosion gully in an open-pit coal mine dump during a winter freeze-thaw cycle by using low-cost UAVs. Remote Sens. 11, 1356. https://doi.org/10.3390/rs11111356 (2019).
Tong, X. et al. Integration of UAV-based photogrammetry and terrestrial laser scanning for the three-dimensional mapping and monitoring of open-pit mine areas. Remote Sens. 7, 6635–6662. https://doi.org/10.3390/rs70606635 (2015).
Wajs, J. Research on surveying technology applied for DTM modelling and volume computation in open pit mines. Min. Sci. 22, 75–83 (2015).
Witt, E. C. Use of lidar point cloud data to support estimation of residual trace metals stored in mine chat piles in the Old Lead Belt of southeastern, Missouri. AIMS Environ. Sci. 3(3), 509–524. https://doi.org/10.3934/environsci.2016.3.509 (2016).
Xu, Z., Xu, E., Wu, L., Liu, S. & Mao, Y. Registration of terrestrial laser scanning surveys using terrain-invariant regions for measuring exploitative volumes over open-pit mines. Remote Sens. 11, 606. https://doi.org/10.3390/rs11060606 (2019).
Walczak, Z., Sojka, M., Wróżyński, R. & Laks, I. Estimation of polder retention capacity based on ASTER, SRTM and LIDAR DEMs: The case of Majdany Polder (West Poland). Water 8, 230. https://doi.org/10.3390/w8060230 (2016).
Kazak, J., Chruściński, J. & Szewrański, S. The development of a novel decision support system for the location of green infrastructure for stormwater management. Sustainability. 10(12), 4388. https://doi.org/10.3390/su10124388 (2018).
Szewrański, S. et al. Pluvial flood risk assessment tool (PFRA) for rainwater management and adaptation to climate change in newly urbanised areas. Water 10, 386. https://doi.org/10.3390/w10040386 (2018).
Szewrański, S. et al. A location intelligence system for the assessment of pluvial flooding risk and the identification of storm water pollutant sources from roads in suburbanised areas. Water 10, 746. https://doi.org/10.3390/w10060746 (2018).
Laks, I., Kałuża, T., Sojka, M., Walczak, Z. & Wróżyński, R. Problems with modelling water distribution in open channels with hydraulic engineering structures. Annu. Set Environ. Protect. (Rocznik Ochrona Środowiska) 15, 245–257 (2013).
Laks, I., Sojka, M., Walczak, Z. & Wróżyński, R. Possibilities of using low quality digital elevation models of floodplains in hydraulic numerical models. Water 9, 283. https://doi.org/10.3390/w9040283 (2017).
Szewrański, S., Kazak, J., Szkaradkiewicz, M. & Sasik, J. Flood risk factors in suburban area in the context of climate change adaptation policies—Case study of Wroclaw, Poland. J. Ecol. Eng. 16, 13–18. https://doi.org/10.12911/22998993/1854 (2015).
Kondracki, J. Geografia Regionalna Polski (PWN, 2002).
Lower Silesian Geoportal—Module of Environmental Maps (Geoportal Dolnego Śląska—Moduł Przyroda). (https://geoportal.dolnyslask.pl/imap/?gpmap=gp80#gpmap=gp80 . Accessed 29 Apr 2019 (2019).
Lower Silesian Geoportal—Module of Topographic Map and Orthophotomap (Geoportal Dolnego Śląska—Moduł Map Topograficznych i Ortofotomap). https://geoportal.dolnyslask.pl/imap/?gpmap=gp80#gpmap=gp3 . Accessed 29 Apr 2019 (2019).
National Water Management Authority (Krajowy Zarząd Gospodarki Wodnej). Mapa Podziału Hydrograficznego Polski (Map of the Hydrographic Division of Poland). http://geoportal.kzgw.gov.pl (archival version, accessed 10 Oct 2016, currently not available on-line) (2010).
State Water Holding—Polish Waters (Państwowe Gospodarstwo Wodne—Wody Polskie). Komputerowa Mapa Podziału Hydrograficznego Polski (The Watershed Computer Map of Poland) https://dane.gov.pl/dataset/869,komputerowa-mapa-podziau-hydrograficznego-polski. Accessed 30 Dec (2019).
Jawecki, B. Rola Kamieniołomów w Kształtowaniu Krajobrazu na Przykładzie Ziemi Strzelińskiej (The role of Quarries in Shaping Landscape Based on the Example of the Strzelin Region). Monography. (Eds. Uniwersytet Przyrodniczy we Wrocławiu, 2017).
Oberc-Dziedzic, T. Internal structure of the granite and tonalite intrusions in the Strzelin massif, Fore-Sudetic block, SW Poland, Granitoids in Poland. AM Monogr. No. 1, 217–229 (2007).
Oberc-Dziedzic, T., Kryza, R., Pin, C. & Madej, S. Sequential granite emplacement: A structural study of the late Variscan Strzelin intrusion, SW Poland. Int. J. Earth Sci. (Geol. Rundschau) 102, 1289–1304 (2013).
Oberc-Dziedzic, T., Kryza, R., Pin, C. & Madej, S. Variscan granitoid plutonism in the Strzelin Massif (SW Poland): Petrology and age of the composite Strzelin granite intrusion. Geol. Q. 57(2), 269–288 (2013).
Szkudlarek, E.Ł. Prognoza Oddziaływania na Środowisko dla Projektu Rozporządzenia w Sprawie Ustalenia Warunków Korzystania z Wód Regionu Wodnego Środkowej Odry (Environmental Impact Forecast for the Draft Ordinance on the Terms of Use of the Waters of the Middle Odra Water Region). http://trmew.pl/fileadmin/user_upload/current_version/trmew.pl/strona_glowna/aktualnosci/2013/04/Prognoza_WKW_Sr_Odry_4_09_2013.pdf. Accessed 31 Dec 2019 (2013).
Integrated Management Services Sp. z o.o. Geomatic Software Solutions Sp. z o.o. Opracowanie Warunków Korzystania z Wód Zlewni Bystrzycy—Synteza (Development of the Conditions of Using the Waters of the Bystrzyca Catchment—Synthesis). http://nfosigw.gov.pl/bazawiedzy/ekspertyzy-dof-przez-nfosigw/filtr,0,0,0,0,0,0,0,0,ASC,0,5,25.html Accessed 31 Dec 2019 (2014).
Polish Geological Institute NRI (Państwowy Instytut Geologiczny PIB) Wydzielenie Rejonów Wodno-Gospodarczych dla Potrzeb Zintegrowanego Zarządzania Zasobami Wód Podziemnych i Powierzchniowych Kraju Region Wodny Środkowej Odry (Determination of Water-Economic Regions for the Needs of Integrated Management of Groundwater and Surface Water Resources of the Country. Water Region of the Middle Odra). Obszar Działalności RZGW we Wrocławiu. Podział na Rejony Wodno-Gospodarcze. (2007) https://wroclaw.rzgw.gov.pl/files_mce/Region%20wodny/Planowanie/RDW/charakterystyka_rejon_w_wodnogospodarczych_rzgw_we_wroc_awiu.pdf. Accessed 29 Dec 2019 (2019).
Regional Water Management Authority in Wrocław (Regionalny Zarząd Gospodarki Wodnej we Wrocławiu). Opracowanie Charakterystyki Zlewni Bilansowej Rzeki Nysy Kłodzkiej (Development of the Characteristics of the Nysa Kłodzka River Balance Catchment). https://wroclaw.rzgw.gov.pl/files_mce/Planowanie%20w%20gospodarowaniu%20wodami/charakterystyka_nysa_klodzka.pdf Accessed 29 Dec 2019 (2015).
Przybyła, C., Sojka, M., Mrozik, K., Wróżyński, R. & Pyszny, K. Program Zwiększenia Retencyjności Ziemi Dzierżoniowskiej na Lata 2014–2020 (Program for Increasing Retention of the Dzierżoniów Land for 2014–2020). https://www.dzierzoniow.pl/sites/default/files/pliki/gospodarka/pzrzd_2014-2020_czesc_i_0.pdf ; https://www.dzierzoniow.pl/sites/default/files/pliki/gospodarka/pzrzd_2014-2020_czesc_ii_0.pdf. Accessed 30 Dec 2019 (2015).
Archive of Western Poland Maps (Archiwum Map Zachodniej Polski). http://mapy.amzp.pl/tk25.cgi?41,60,50,73. Accessed 29 Apr 2019 (2019).
Lower Silesian Geoportal—Module of Archival Maps (Geoportal Dolnego Śląska—Moduł Map Archiwalnych). https://geoportal.dolnyslask.pl/imap/?gpmap=gp62#gpmap=gp62 . Accessed 29 Apr 2019 (2019).
Dávid, L. Quarrying: An anthropogenic geomorphological approach. Acta Montan. Slovaca 13(1), 66–74 (2008).
Zajączkowski, M., Sikora, M., Kasztelewicz, Z. & Będkowski, T. Klasyfikacja systemów eksploatacji odkrywkowej z uwzględnieniem aktualnego stanu technologii górniczych (Surface mining system classification taking into account the current mining technological advance). Prz. Gór 10(70), 79–84 (2014).
Resolution of the Board of the Opolskie Voivodeship of December 4, 2007 No. 1222/2007 “Program for the Construction of Small Retention Reservoirs in the Opolskie Voivodeship” (2007).
Ordinance of the Minister of the Environment of 23 December 2002 (u1) on the criteria for determining waters sensitive to pollution with nitrogen compounds from agricultural sources. J. Laws 241, item 2093 (2002) (considered to be repealed, valid on the day of researching).
Ordinance of the Minister of the Environment of November 27, 2002 on the requirements to be met by surface waters used to supply people with drinking water. J. Laws 204, item 1728 (2002).
Ordinance of the Minister of the Environment of October 4 2002 (u2) on the requirements to be met by inland waters being the living environment of fish in natural conditions J. Laws 176, item 1455 (2002) (considered to be repealed, valid on the day of researching).
Kaniszewski S., Treder W. Jakość wody do nawadniania i fertygacji, metody uzdatniania (Water quality for irrigation and fertigation, treatment methods). in Ograniczenie Zanieczyszczenia Azotem Pochodzenia Rolniczego Metodą Poprawy Jakości Wód (Reducing Nitrogen Pollution from Agricultural Sources by Improving Water Quality). (ed.Walczak, J.) (Fundacja na rzecz Rozwoju Polskiego Rolnictwa, 2018).
PN-84/C-04635. Woda do Nawadniania Roślin na Użytkach Rolnych Oraz do Ich Opryskiwania Chemicznymi Środkami Ochrony Roślin (Water for Irrigation of Plants on Agricultural Land and for Spraying Them with Chemical Plant Protection Products).
Saha U., ButcherS., Porter W., Sonon L., Hawkins G., Lessl J. Irrigation water quality for agriculture. in UGA Extension Bulletin 1448. https://secure.caes.uga.edu/extension/publications/files/pdf/B%201448_1.PDF . Accessed 29 July 2019 (2015).
Regional Water Management Authority in Wrocław (Regionalny Zarząd Gospodarki Wodnej we Wrocławiu). Projekt Planu Przeciwdziałania Skutkom Suszy w Regionach Wodnych Środkowej Odry, Izery, Metuje, Łaby i Ostrożnicy (Upa), Orlicy i Morawy (Draft Plan to Counteract the Effects of Drought in the Water Regions of the Middle Odra, Jizera, Metuje, Labe and Ostrożnica (Upa), Orlica and Morava). Warszawa (2016).
