Results of geophysical monitoring over a “leaking” natural analogue site in Italy

Results of geophysical monitoring over a ȁc;leaking” natural analogue site in Italy

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作者：R.J. Arts ; L. Baradello ; J.F. Girard ; G. Kirby ; S. Lombardi ; P. Williamson ; A. Zaja
关键词：Underground CO₂ storage ; Monitoring ; Leakage ; Natural analogue ; Faults
刊名：Energy Procedia
出版年：2009
出版时间：February 2009
年：2009
卷：1
期：1
页码：2269-2276
全文大小：1352 K

文摘

CO₂ storage in the subsurface is becoming more and more attractive as a means to reduce CO₂ emissions to the atmosphere and hence minimize human-induced global warming. The ability to monitor and verify these CO₂ storage reservoirs is a key element for further implementation of other storage sites. Since the current sites fortunately do not appear to ȁc;leak” CO₂, it is difficult to test the most suitable monitoring techniques for their ability to detect CO₂ migration pathways. In this study different monitoring methods have been evaluated at a site in the Latera caldera (central Italy) where natural, thermo-metamorphically produced CO₂ finds its way to the surface. The aim of the study is to identify which monitoring methods can detect the migrating CO₂ and to gain understanding of the preferential migration pathways of the CO₂. Different geophysical monitoring techniques have been deployed at a small, 200×500 m study area located in the centre of the caldera: 2D reflection seismics (testing different sources), 2D refraction seismics, multi-channel analysis of surface wave (MASW), ground penetrating radar (GPR), micro-gravity, magnetometer, self-potential (SP), 2D and 3D geo-electrical measurements and electro-magnetic (EM31 and EM34) measurements. Furthermore CO₂ flux measurements were performed in a dense grid over the study area, and a limited number of soil gas samples collected along two profiles, to ȁc;ground-truth” the geophysical results. In general a good correlation has been observed between the different methods and the presence of CO₂. Geophysical responses, especially those of the reflection seismic and magnetometer data, change markedly from one side of the proposed main fault to the other, probably linked to a sharp geological boundary. The observed fractures on the seismic data seem to correspond with the preferred migration pathways of the CO₂. The GPR and resistivity measurements detect strong variations in conductivity induced by the presence of the CO₂ up to about 2 and 20 m depth, respectively, as supported by the soil gas and flux measurements.

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