{"id":194,"date":"2023-08-24T00:22:42","date_gmt":"2023-08-24T00:22:42","guid":{"rendered":"https:\/\/books.gw-project.org\/stable-isotope-hydrology\/?post_type=part&p=194"},"modified":"2024-01-11T20:22:51","modified_gmt":"2024-01-11T20:22:51","slug":"references","status":"publish","type":"part","link":"https:\/\/books.gw-project.org\/stable-isotope-hydrology\/part\/references\/","title":{"raw":"12 References","rendered":"12 References"},"content":{"raw":"
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Adar, E.M., A. Dody, M.A. Geyh, A. Yair, A. Yakirevich, and A.S. Issar, 1998, Distribution of stable isotopes in arid storms I. Relation between the distribution of isotopic composition in rainfall and in consequent runoff. Hydrogeology<\/span> Journal, <\/span>volume\u00a0<\/span>6, <\/span>16\u00a0pages<\/span>, <\/span>doi:10.1007\/s100400050133<\/span><\/a>.<\/p>\r\n

Al-Charideh, A. and B. Kattaa, 2016, Isotope hydrology of deep groundwater in Syria: renewable and non-renewable groundwater and paleoclimate impact. Hydrogeology<\/span> Journal, <\/span>volume\u00a0<\/span>24, <\/span>20\u00a0pages<\/span>, <\/span>doi:10.1007\/s10040<\/span>-<\/span>015<\/span>-<\/span>1324<\/span>-<\/span>4<\/span><\/a>.<\/p>\r\n

Al Faitouri, M. and W.E. Sanford, 2015, Stable and radio-isotope analysis to determine recharge timing and paleoclimate of sandstone aquifers in central and southeast Libya. Hydrogeology<\/span> Journal, <\/span>volume\u00a0<\/span>23, <\/span>11\u00a0pages<\/span>, <\/span>doi:10.1007\/s10040<\/span>-<\/span>015<\/span>-<\/span>1232<\/span>-<\/span>7<\/span><\/a>.<\/p>\r\n

Alison, G.B. and M.W. Hughes, 1983, The use of natural tracers as indicators of soil-water movement in a temperate semi-arid region. Journal of Hydrology, volume\u00a060, 17\u00a0pages, doi:10.1016\/0022<\/span>-<\/span>1694(83)90019<\/span>-<\/span>7<\/span><\/a>.<\/p>\r\n

Andrews, J.E., 2006, Palaeoclimatic records from stable isotopes in riverine tufas: Synthesis and reviews. Earth Science Reviews, volume\u00a075, 20\u00a0pages, doi:10.1016\/j.earscirev<\/span>.2005.08.002<\/span><\/a>.<\/p>\r\n

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Aragu\u00e1s-Aragu\u00e1s, L., K. Froehlich, and K. Rozanski, 2000, Deuterium and oxygen-18 isotope composition of precipitation and atmospheric moisture. Hydrological<\/span> Processes<\/span>, <\/span>volume\u00a0<\/span>14, <\/span>15\u00a0pages<\/span>, <\/span>doi:10.1002\/1099<\/span>-<\/span>1085(20000615)14:8<<\/span>1341::<\/span>AID<\/span>-<\/span>HYP983>3.0.CO;2<\/span>-<\/span>Z<\/span><\/a>.<\/p>\r\n

Baloyi, R.S. and R.E. Diamond, 2019, Variable water quality of domestic wells emphasizes the need for groundwater quality monitoring and protection: Stinkwater, Hammanskraal, Gauteng. Water SA, <\/span>volume\u00a0<\/span>45, <\/span>9\u00a0pages<\/span>, <\/span>doi:10.4314\/<\/span>wsa.v<\/span>45i2.08<\/span><\/a>.<\/p>\r\n

Beven, K.J., 2001, Rainfall-Runoff Modelling\u00a0-\u00a0The Primer. John Wiley and Sons, Ltd., New York, 488\u00a0pages.<\/p>\r\n

Biggs, T.W., C.T. Lai, P. Chandan, R.M. Lee, A. Messina, R.S. Lesher, and N. Khatoon, 2015, Evaporative fractions and elevation effects on stable isotopes of high elevation lakes and streams in arid western Himalaya. Journal of Hydrology, volume\u00a0522, 11\u00a0pages, doi:10.1016\/j.jhydrol<\/span>.2014.12.023<\/span><\/a>.<\/p>\r\n

Blarasin, M., A. Cabrera, I. Matiatos, V. Lutri, L. Maldonado, D. Giacobone, E. Matteoda, F.B. Quinodoz, J.G. Albo, C.E. Felizzia, and J. Felizzia, 2020, Application of isotope techniques to enhance the conceptual hydrogeological model and to assess groundwater sustainability in the Pampean Plain in Cordoba, Argentina. Isotopes in Environmental and Health Studies, volume\u00a056, 16\u00a0pages, doi:10.1080\/10256016.2020.1796658<\/span><\/a>.<\/p>\r\n

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Boschetti, T., J. Cifuentes, P. Iacumin, and E. Selmo, 2019, Local meteoric water line of northern Chile (18-30\u00b0S): An application of error-in-variables regression to the oxygen and hydrogen stable isotope ratio of precipitation. Water, <\/span>volume\u00a0<\/span>11, <\/span>issue\u00a04, <\/span>791<\/span>\u00a0pages<\/span>, <\/span>doi:10.3390\/w11040791<\/span><\/a>.<\/p>\r\n

Bosman, H.H., 1981, <\/span>Raingauges<\/span>: <\/span>Quality<\/span> pays. Water SA, <\/span>volume\u00a0<\/span>7, <\/span>2\u00a0pages<\/span>.<\/span><\/p>\r\n

Camacho Suarez, V.V., A.M. Saraiva Okello, J.W. Wenninger, and S. Uhlenbrook, 2015, Understanding runoff processes in a semi-arid environment through isotope and hydrochemical hydrograph separations. Hydrology and Earth System Sciences, volume\u00a019, 17\u00a0pages, doi:10.5194\/hess<\/span>-<\/span>19<\/span>-<\/span>4183<\/span>-<\/span>2015<\/span><\/a>.<\/p>\r\n

Canavan, R.R., B. Carrapa, M.T. Clementz, J. Quade, P.G. DeCelles, and L.M. Schoenbohm, 2014, Early Cenozoic uplift of the Puna Plateau, Central Andes, based on stable isotope paleoaltimetry of hydrated volcanic glass. Geology, volume\u00a042, 4\u00a0pages, doi:10.1130\/G35239.1<\/span><\/a>.<\/p>\r\n

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Clark, I., 2015, Groundwater Geochemistry and Isotopes, CRC Press, Boca Raton, 456\u00a0pages, doi:10.1201\/b18347<\/span><\/a>.<\/p>\r\n

Clark, I.D. and P. Fritz, 1997, Environmental Isotopes in Hydrogeology, CRC Press, Boca Raton, 342\u00a0pages, doi:10.1201\/9781482242911<\/span><\/a>.<\/p>\r\n

Cook, P., 2020, Introduction to isotopes and environmental tracers as indicators of groundwater flow. The Groundwater Project, Guelph, Ontario, Canada, 74\u00a0pages, https:\/\/gw<\/span>-<\/span>project.org\/books\/introduction<\/span>-<\/span>to<\/span>-<\/span>isotopes<\/span>-<\/span>and<\/span>-<\/span>environmental<\/span>-<\/span>tracers<\/span>-<\/span>as<\/span>-<\/span>indicators<\/span>-<\/span>of<\/span>-<\/span>groundwater<\/span>-<\/span>flow\/<\/span><\/a>.<\/p>\r\n

Cook, P.G. and A.P. O'Grady, 2006, Determining soil and groundwater use of vegetation from heat pulse, water potential and stable isotope data. Oecologia, volume\u00a0148, 11\u00a0pages, doi:10.1007\/s00442<\/span>-<\/span>005<\/span>-<\/span>0353<\/span>-<\/span>4<\/span><\/a>.<\/p>\r\n

Craig, H., 1961, Isotopic variations in meteoric waters. Science, <\/span>volume\u00a0<\/span>133, <\/span>2\u00a0pages<\/span>, <\/span>doi:10.1126\/science.133.3465.1702<\/span><\/a>.<\/span><\/p>\r\n

Craig, H. and L.I. Gordon, 1965, Deuterium and oxygen 18 variations in the ocean and the marine atmosphere, editor, Tongiorgi, E., Stable Isotopes in Oceanographic Studies and Palaeotemperatures. Proceedings of the Spoleto Conferences in Nuclear Geology, Pisa, 122\u00a0pages.<\/p>\r\n

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Das, P., A. Mukherjee, S.A. Hussain, M.S. Jamal, K. Das, A. Shaw, M.K. Layek, and P. Sengupta, 2020, Stable isotope dynamics of groundwater interactions with Ganges River. Hydrological<\/span> Processes<\/span> 2021, <\/span>volume\u00a0<\/span>35, <\/span>issue\u00a01, 15\u00a0pages<\/span>, <\/span>doi:10.1002\/hyp.14002<\/span><\/a>.<\/span><\/p>\r\n

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Dawson, T.E., S. Mambelli, A.H. Plamboeck, P.H. Templer, and K.P. Tu, 2002, Stable isotopes in plant ecology. Annual Review of Ecology and Systematics, volume\u00a033, 53\u00a0pages, doi:10.1146\/annurev.ecolsys<\/span>.33.020602.095451<\/span><\/a>.<\/p>\r\n

Diamond, R.E. and C. Harris, 1997, Oxygen and hydrogen isotope composition of Western Cape meteoric water. South African Journal of Science, volume\u00a093, 4\u00a0pages, https:\/\/hdl.handle.net\/10520\/AJA00382353_74<\/span><\/a>.<\/p>\r\n

Diamond, R.E. and C. Harris, 2000, Oxygen and hydrogen isotope geochemistry of thermal springs of the Western Cape, South Africa: recharge at high altitude?. Journal of African Earth Sciences, volume\u00a031, 15\u00a0pages, doi:10.1016\/S0899<\/span>-<\/span>5362(00)80002<\/span>-<\/span>0<\/span><\/a>.<\/p>\r\n

Diamond, R.E. and C. Harris, 2019, Annual shifts in O- and H-isotope composition as measures of recharge: the case of the Table Mountain Springs, Cape Town, South Africa. Hydrogeology<\/span> Journal, <\/span>volume\u00a0<\/span>27, <\/span>16\u00a0pages<\/span>, <\/span>doi:10.1007\/s10040<\/span>-<\/span>019<\/span>-<\/span>02045<\/span>-<\/span>5<\/span><\/a>.<\/span><\/p>\r\n

Diamond, R.E. and S. Jack, 2018, Evaporation and abstraction determined from stable isotopes during normal flow on the Gariep River, South Africa. Journal of Hydrology, volume\u00a0559, 16\u00a0pages, doi:10.1016\/j.jhydrol<\/span>.2018.02.059<\/span><\/a>.<\/p>\r\n

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Dogramaci, S., G. Firmani, P. Hedley, G. Skrzypek, and P.F. Grierson, 2015, Evaluating recharge to an ephemeral dryland stream using a hydraulic model and water, chloride and isotope mass balance. Journal of Hydrology, volume\u00a0521, 13\u00a0pages, doi:10.1016\/j.jhydrol<\/span>.2014.12.017<\/span><\/a>.<\/p>\r\n

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