The evolution of the Cappadocia Geothermal Province, Anatolia (Turkey): geochemical and geochronological evidence (土耳其)卡帕多西亚地热区的演化:地球化学和地质年代学证据 Evolution de la province géothermale de Cappadoce, Anatolie (Turquie): Evidences géochimiques et géochronologiques Evolução da Província Geotérmica de Capadócia, Anatólia (Turquia): evidências geoquímicas e geocronológicas La evolución de la Cappadocia Geothermal Province, Anatolia (Turquía): pruebas geoquímicas y geocronológicas

Cappadocia Geothermal Province (CGP), central Turkey, consists of nine individual geothermal regions controlled by active regional fault systems. This paper examines the age dating of alteration minerals and the geochemistry (trace elements and isotopes) of the alteration minerals and geothermal waters, to assess the evolution of CGP in relation to regional tectonics. Ar–Ar age data of jarosite and alunite show that the host rocks were exposed to oxidizing conditions near the Earth’s surface at about 5.30 Ma. Based on the δO–δD relationhip, water samples had a high altitude meteoric origin. The δS values of jarosite and alunite indicate that water samples from the southern part of the study area reached the surface after circulation through volcanic rocks, while northern samples had traveled to the surface after interacting with evaporates at greater depths. REY (rare earth elements and yttrium) diagrams of alteration minerals (especially illite, jarosite and alunite) from rock samples, taken from the same locations as the water samples, display a similar REY pattern to water samples. This suggests that thermal fluids, which reached the surface along a fault zone and caused the mineral alteration in the past, had similar chemical composition to the current geothermal water. The geothermal conceptual model, which defines a volcanically heated reservoir and cap rocks, suggests there are no structural drawbacks to the use of the CGP geothermal system as a resource. However, fluid is insufficient to drive the geothermal system as a result of scanty supply of meteoric water due to evaporation significantly exceeding rainfall