Groundwater of the Crimean peninsula: a first systematic study using stable isotopes

References

• Dublyansky VN, Dublyanskaya GN. Karstovaya respublika (karst Kryma i ego problemy) [The karst republic (karst of Crimea and its issues)]. Simferopol; 1996. Russian.
   Google Scholar
• Gordievich VA, Kurishko VA, Lychagin GA. Gidrogeologiya Kryma i perspektivy ego neftegazonosnosti [Hydrogeology of Crimea and perspectives of its oil- and gas potential]. Kiev: AN USSR; 1963; Russian.
   Google Scholar
• Barabanov LN, Lychagin GA, Mesiats IA, et al., editors. Gidrogeologiya SSSR, tom VIII, Krym [Hydrogeology of USSR, vol. VIII, Crimea]. Moscow: Nedra; 1970. Russian.
   Google Scholar
• Kayukova EP, Yurovsky YG. Vodnije resursy Kryma [Water resources of Crimea]. Geoecol Eng Geol Hydrogeol Geocryol. 2016;1:25–32. Russian.
   Google Scholar
• Miran’kov DB. Problemi preodoleniya deficita vodnykh resursov v Respublike Krym: Adaptatsyia zarubezhnogo opyta [Problems of overcoming water resource deficit in the Republic of Crimea: Adaptation of foreign experience]. Scholarly Notes Crimean Federal University, Economics and Management. 2018;4(70):93–107. Russian.
   Google Scholar
• Aydarkozhina AS, Lavrushin VY. Usloviya formirovaniya giazevulkanicheskikh fluidov Krima, po dannim izmereniya δD, δ18O, δ13C, δ15N [Conditions of formation of mud volcano fluids from measurement of δD, δ18O, δ13C, δ15N]. In: Proceedings of the XXI Symposium on Isotope Geochemistry; 2016 Nov 15–17; Moscow. Moscow: Vernadsky Institute of Geochemistry, Russian Academy of Sciences, p. 135–138. Russian.
   Google Scholar
• Ershov VV, Levin BV. Novije dannije o veschestvennom sostave produktov dejatelnosti griazevikh vulkanov Kerchenskogo poluostrova [New data on material composition of the products of activity of mud volcanoes of the Kerch peninsula]. Dokl Akad Nauk. 2016;471(1):1–5. Russian.
   Google Scholar
• Seletsky YB, Pribluda VD, Poliakov VA, et al. Ispolzovanije kontsentratsij tiazhologo izotopa kisloroda pri izuchenii podzemnikh vod zakarstovannikh karbonatnikh massivov Gornogo Krima [Using concentrations of heavy isotope of oxygen in studies of ground waters in karstified carbonate massifs of the Crimean Mountains]. Water Res. 1982;4:83–90. Russian.
   Google Scholar
• Dublyansky YV, Klimchouk AB, Amelichev GN, et al. Izotopnyi sostav atmosfernikh osadkov i karstovikh istochnikov severo-zapadnogo sklona Krimskikh gor [Isotopic composition of atmospheric precipitation and karst springs of the northwest slope of the Crimean Mountains]. Speleol Karstol. 2012;9:14–21. Russian.
   Google Scholar
• Kayukova EP. Formirovanie izotopnogo sostava prirodnikh vod Gornogo Kryma pod vlijaniem estestvennikh processov [Formation of isotopic composition of natural waters of the Crimean Mountains under the influence of natural processes]. Vestn St Peterbg Univ. 2016;7(2):11–26. Russian.
   Google Scholar
• Amelichev GN, Tokarev IV, Tokarev SV, et al. Kompleksnaya otsenka vozrasta i ustanovleniye usloviy formirovaniya minerl’nikh vod ‘Bishuli’ (Ravninniy Krim) na osnove izotopno-geokhimicheskikh dannykh [Comprehensive assessment of age and determination of conditions of formation of mineral water ‘Bishuli’ (Crimean Plains) on the basis of isotope geochemistry data]. Scholarly Notes Crimean Federal University, Geography, Geology. 2017;3(69):130–150. Russian.
   Google Scholar
• Yudin VV. Geodinamika Kryma [Geodynamics of Crimea]. Simferopol: DIP; 2011; Russian.
   Google Scholar
• Shestopalov VM, Blinov PV, Lyutyi GG, et al. Suchasni princypy gidrogeologichnogo rainuvannya [Modern principles of hydrogeological regionalization]. Zbirnik naukovyh prac UkrDGRI. 2010;3–4:147–157. Ukrainian.
   Google Scholar
• Gor’kova LG, Lymar NB. Karta jestestvennoy zashchischennosti podzemnyh vod Ukrainskoy SSR, Masshtab 1: 200 000, Krymskaja oblast’, Objasnitelnaja zapiska [Map of natural protection of underground waters of the Ukrainian SSR, Scale 1: 200 000, Crimean region, Explanatory notes]. Kiev: Mingeo USSR; 1987; Russian.
   Google Scholar
• Lushchik AV, Morozov VI, Meleshin VP, et al. Podzemnyye vody karstovykh platformennyh oblastey yuga Ukrainy [Groundwaters of platform karst regions of the south of Ukraine]. Kiev: Naukova dumka; 1981; Russian.
   Google Scholar
• Lushchik AV, Morozov VI, Pavkin VP, et al. Osobennosti formirovaniya podzemnyh vod v zapadnoy chasti Ravninnogo Kryma (na promere buhty Ocheretay) [Particularities of the groundwater formation in the western part of the Crimean Plains (on an example of Ocheretay cave)]. Geol J. 1985;45(3):101–107. Russian.
   Google Scholar
• Gehre M, Geilmann H, Richter J, et al. Continuous flow 2H/1H and 18O/16O analysis of water samples with dual inlet precision. Rapid Commun Mass Spectrom. 2004;18:2650–2660. doi: 10.1002/rcm.1672
   PubMed Web of Science ®Google Scholar
• Spötl C, Fairchild IJ, Tooth AF. Speleothem deposition in a dynamically ventilated cave, Obir Caves (Austrian Alps). Evidence from modern cave air and drip water monitoring. Geochim Cosmochim Acta. 2005;69:2451–2468. doi: 10.1016/j.gca.2004.12.009
   Web of Science ®Google Scholar
• van Geldern R, Barth JAC. Optimization of instrument setup and post-run corrections for oxygen and hydrogen stable isotope measurements of water by isotope ratio infrared spectroscopy (IRIS). Limnol Oceanogr Meth. 2012;10:1024–1036. doi: 10.4319/lom.2012.10.1024
   Web of Science ®Google Scholar
• Dublyansky YV, Klimchouk AB, Tokarev SV, et al. Stable isotopic composition of atmospheric precipitation on the Crimean Peninsula and its controlling factors. J Hydrol. 2018;565:61–73.
   Google Scholar
• Dublyansky VN, Vakhrushev BA, Amelichev GN, et al. Krasnaya peschera: Rezul’tati kompleksnikh issledovanij [Krasnaya cave. Results of the comprehensive karstological studies]. Moscow: RUDN; 2002; Russian.
   Google Scholar
• Klimchouk AB. Epikarst: gidrogeologiya, morfogenez i evolutsiya [Epikarst: hydrogeology, morphogenesis and evolution]. Simferopol: Sonat; 2009; Russian.
   Google Scholar
• Schwartz K, Barth JAC, Postigo-Rebollo C, et al. Mixing and transport of water in a karst catchment: a case study from precipitation via seepage to the spring. Hydrol Earth Syst Sci. 2009;13:285–292. doi: 10.5194/hess-13-285-2009
   Web of Science ®Google Scholar
• Perrin J, Jeannin P, Zwahlen F. Epikarst storage in a karst aquifer: a conceptual model based on isotopic data, Milandre test site, Switzerland. J Hydrol. 2003;279:106–124. doi: 10.1016/S0022-1694(03)00171-9
   Web of Science ®Google Scholar
• Dublyansky VN. Karstovije pescheri i shakhti Gornogo Krima [Karst caves and shafts of the Crimean Mountains]. Leninhrad: Nauka; 1977; Russian.
   Google Scholar
• Vakhrushev BA, Vakhrushev IB. Rol’ karstovikh kondensatcionnikh vod v vodnom khoziaystve antichnikh i srednevekovikh poseleniy Kerchenskogo poluostrova [The role of karst condensation water in the water management of antique and medieval settlements of Kerch peninsula]. Culture of the Nations in the Black Sea Region. 1999;10:7–10. Russian.
   Google Scholar
• Clark ID, Fritz P. Environmental isotopes in hydrogeology. Boca Raton (FL): CRC Press; 1977.
   Google Scholar
• Shniukov EF, Gnatenko GI, Nesterovsky VA, et al. Griazevoy vulkanizm Kerchensko-Tamanskogo regiona [Mud volcanism of the Kerch-Taman Region]. Kiev: Naukova dumka; 1992; Russian.
   Google Scholar
• Kurishko VA, Mesiats IA, Terdovidov AS. Gidrogeologija griazevogo vulkanizma Kercheskogo poluostrova [Hydrogeology of mud volcanism of the Kerch peninsula]. Geol J. 1968;28(1):49–59. Russian.
   Google Scholar
• Buyakaite MI, Lavrushin VY, Pokrovsky BG, et al. Izotopniye sistemi strontsiya i kisloroda v vodakh griazevikh vulkanov Tamanskogo poluostrova [Isotope systems of strontium and oxygen in waters of mud volcanoes of the Taman’ peninsula]. Lith Min Resour. 2014;1:52–59.
   Google Scholar