Diffuse soil CO2 flux to assess the reliability of CO2 storage in the Mazarrón–Gañuelas Tertiary Basin (Spain)

Rodrigo-Naharro, Julio; Nisi, Bárbara; Vaselli, Orlando; Lelli, Matteo; Saldana, R.; Clemente-Jul, Carmen; Villar, Luis

doi:10.1016/j.fuel.2013.06.009

Cited by 12 publications

(4 citation statements)

References 35 publications

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“…The SBHS value appears smaller than most CO 2 discharges of volcanic, geothermal, and hydrothermal sites. Nevertheless, the SBHS value is similar to some volcanic sites, such as La Fossa (Italy) [ Carapezza et al , ] and White Island (New Zealand) [ Wardell et al , ]; some geothermal sites, such as Dixie Valley (USA) [ Bergfeld et al , ] and Mazarrón‐Gañuelas Tertiary Basin (Spain) [ Rodrigo‐Naharro et al , ]; and some hydrothermal sites, such as Long Valley (USA) [ Bergfeld et al , ]. In general, the CO 2 discharge of the SBHS is compatible with the majority of mofette sites, such as Selvena (Italy) [ Rogie et al , ], Stavešinci (Slovenia) [ Vodnik et al , ], and Hartoušov (Czech Republic) [ Kämpf et al , ], but appears orders of magnitude higher than estimated values of fault‐related sites, such as Peloritani Monts (Italy) [ Giammanco et al , ], San Andreas and Calaveras faults (USA) [ Lewicki et al , ], and Kunlun fault (China) [ Richon et al , ].…”

Section: Discussionmentioning

confidence: 90%

“…More generally, studies that have dealt with the spatial distribution of CO 2 fluxes at the Earth's surface were carried out primarily near volcanoes [e.g., Baubron et al , ; Farrar et al , ; Giammanco et al , ; Chiodini et al , ; Hernández et al , ]. Recently, many studies have focused on various natural systems, e.g., volcanic [e.g., Chiodini et al , ; Toutain et al , ; Viveiros et al , ; Finizola et al , ; Granieri et al , ; Di Napoli et al , ; Federico et al , ; Mazot et al , , ; Carapezza et al , ; Inguaggiato et al , ; Hernández et al , , ; Rinaldi et al , ; Tassi et al , ], geothermal [e.g., D'Alessandro et al , ; Fridriksson et al , ; Werner and Cardellini , ; Annunziatellis et al , ; Rodrigo‐Naharro et al , ], and hydrothermal geosystems [e.g., Gerlach et al , ; Lewicki et al , , , ; Werner et al , ; Rissmann et al , ]. However, only a few studies were performed in low temperature (<50°C) CO 2 degassing areas [e.g., Mörner and Etiope , ], such as mofette sites [e.g., Italiano et al , ; Rogie et al , ; Vodnik et al , ; Chiodini et al , ; Kämpf et al , ; Bräuer et al , ], as well as in fault‐related areas [e.g., Etiope , ; Lewicki and Brantley , ; Lewicki et al , ; Ciotoli et al , ] and, more rarely, in the largest orogens [ Perrier et al , ; Richon et al , ].…”

Section: Introductionmentioning

confidence: 99%

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The Syabru‐Bensi hydrothermal system in central Nepal: 1. Characterization of carbon dioxide and radon fluxes

et al. 2014

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The Syabru-Bensi hydrothermal system (SBHS), located at the Main Central Thrust zone in central Nepal, is characterized by hot (30-62°C) water springs and cold (<35°C) carbon dioxide (CO 2 ) degassing areas. From 2007 to 2011, five gas zones (GZ1-GZ5) were studied, with more than 1600 CO 2 and 850 radon flux measurements, with complementary self-potential data, thermal infrared imaging, and effective radium concentration of soils. Measurement uncertainties were evaluated in the field. CO 2 and radon fluxes vary over 5 to 6 orders of magnitude, reaching exceptional maximum values of 236 ± 50 kg m À2 d À1 and 38.5 ± 8.0 Bq m À2 s À1 , with estimated integrated discharges over all gas zones of 5.9 ± 1.6 t d À1 and 140 ± 30 MBq d À1 , respectively. Soil-gas radon concentration is 40 × 10 3 Bq m À3 in GZ1-GZ2 and 70 × 10 3 Bq m À3 in GZ3-GZ4. Strong relationships between CO 2 and radon fluxes in all gas zones (correlation coefficient R = 0.86 ± 0.02) indicate related gas transport mechanisms and demonstrate that radon can be considered as a relevant proxy for CO 2 . CO 2 carbon isotopic ratios (δ 13 C from À1.7 ± 0.1 to À0.5 ± 0.1‰), with the absence of mantle signature (helium isotopic ratios R/R A < 0.05), suggest metamorphic decarbonation at depth. Thus, the SBHS emerges as a unique geosystem with significant deep origin CO 2 discharge located in a seismically active region, where we can test methodological issues and our understanding of transport properties and fluid circulations in the subsurface.

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Section: Discussionmentioning

confidence: 90%

Section: Introductionmentioning

confidence: 99%

The Syabru‐Bensi hydrothermal system in central Nepal: 1. Characterization of carbon dioxide and radon fluxes

et al. 2014

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“…First, the CO 2 is injected into the saline aquifers in a supercritical state under the condition of high temperature and enormous pressure (Zhou et al , 2019). As the supercritical CO 2 is signiﬁcantly less dense (200-700 kg/m 3 ) than the ambient brine (900-1200 kg/m 3 ) and oil (about 800 kg/m 3 ; Huppert and Neufeld, 2014; Abedini and Torabi, 2014), the injected supercritical CO 2 will keep rising and leaking (Rodrigo-Naharro et al , 2013) owing to the buoyance until stopped by a cap rock. As a result, the supercritical CO 2 will reside above brine water (Talebian et al , 2013).…”

Section: Introductionmentioning

confidence: 99%

The impact of heterogeneous anisotropy of porous media on density-driven convection

Cai

Tang

et al. 2019

HFF

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Purpose The aim of this study is to numerically simulate the density-driven convection in heterogeneous porous media associated with anisotropic permeability field, which is important to the safe and stable long term CO2 storage in laminar saline aquifers. Design/methodology/approach The study uses compact finite difference and the pseudospectral method to solve Darcy’s law. Findings The presence of heterogeneous anisotropy may result in non-monotonic trend of the breakthrough time and quantity of CO2 dissolved in the porous medium, which are important to the CO2 underground storage. Originality/value The manuscript numerically study the convective phenomena of mixture contained CO2 and brine. The phenomena are important to the process of CO2 enhanced oil recovery. Interesting qualitative patterns and quantitative trends are revealed in the manuscript.

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“…In the framework of a large project on Carbon Capture and Storage (CCS) technologies, the Gañuelas-Mazarrón Tertiary Basin (GMTB), SE Spain, was studied as an analogue of a natural CO 2 reservoir affected by leakages (Pérez del Villar et al, 2008;Nisi et al, 2010a,b;Rodrigo-Naharro et al, 2011, Rodrigo-Naharro et al, 2013aRodrigo-Naharro, 2014;Rodrigo-Naharro et al, 2017, 2018. CO 2 -rich saline groundwater from deep and thermal aquifers are currently upwelling through geothermal wells, precipitating travertines at the water discharge points.…”

Section: Introductionmentioning

confidence: 99%

Current travertines precipitation related to artificial CO2 leakages from a natural reservoir (Gañuelas-Mazarrón Tertiary Basin, SE Spain)

Rodrigo-Naharro

Herrero

Huertas

et al. 2019

Journal of Hydrology

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In the framework of a natural CO 2 reservoir with CO 2 leakages as an analogue of a failed CO 2 deep geological storage, the current precipitation of travertines and the associated upwelling of CO 2-rich saline groundwater were analysed. This natural analogue is located in the Gañuelas-Mazarrón Tertiary Basin (SE Spain). The study comprises of the chemistry of both groundwater and travertines, including stable isotopes, mineralogy and petrography of the travertines, all this performed after a review of the geology of the basin. In this sense, the basin gathers the main features of a safe natural CO 2 reservoir in a deep saline aquifer sealed by a thick marl formation. The aquifer was artificially perturbed by the drilling of wells, inducing the travertines precipitation at these water discharge points. Groundwater is saline, slightly acid, oversaturated in aragonite and calcite and with significant concentrations of heavy elements, some of them toxic. From an isotopic viewpoint, the relative constant δ 13 C-DIC values suggest that carbon is mainly inorganic in origin with minor organic and mantle contributions. Travertines are basically composed of aragonite or calcite, their precipitation being controlled by a sudden CO 2 degassing and minor biological activity. Their δ 13 C signatures indicate that carbon mainly has an inorganic origin, although some contribution of organic carbon must be considered as well. Furthermore, these carbonate deposits did not precipitate in isotopic equilibrium, as determined by δ 18 O values. Finally, it is suggested that the appearance of travertines along with their carbon isotopic signatures represent efficient tools for detecting CO 2 leakages from any CO 2 storage site.

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Diffuse soil CO2 flux to assess the reliability of CO2 storage in the Mazarrón–Gañuelas Tertiary Basin (Spain)

Cited by 12 publications

References 35 publications

The Syabru‐Bensi hydrothermal system in central Nepal: 1. Characterization of carbon dioxide and radon fluxes

The Syabru‐Bensi hydrothermal system in central Nepal: 1. Characterization of carbon dioxide and radon fluxes

The impact of heterogeneous anisotropy of porous media on density-driven convection

Current travertines precipitation related to artificial CO2 leakages from a natural reservoir (Gañuelas-Mazarrón Tertiary Basin, SE Spain)

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