Nicolas Tonnet scite author profile

Are rocks still water‐wet in the presence of dense CO₂ or H₂S?

Broseta¹,

Tonnet²,

Shah³

2012

View full text Add to dashboard Cite

The various modes of acid gas storage in aquifers, namely structural, residual, and local capillary trapping, are effective only if the rock remains water‐wet. This paper reports an evaluation, by means of the captive‐bubble method, of the water‐wet character in presence of dense acid gases (CO2, H2S) of typical rock‐forming minerals such as mica, quartz, calcite, and of a carbonate‐rich rock sampled from the caprock of a CO2 storage reservoir in the South‐West of France. The method, which is improved from that previously implemented with similar systems by Chiquet et al. (Geofluids 2007; 7: 112), allows the advancing and receding contact angles, as well as the adhesion behavior of the acid gas on the mineral substrate, to be evaluated over a large range of temperatures (up to 140°C), pressures (up to 150 bar), and brine salinities (up to NaCl saturation) representative of various geological storage conditions. The water‐receding (or gas‐advancing) angle that controls structural and local capillary trapping is observed to be not significantly altered in the presence of dense CO2 or H2S. In contrast, some alteration of the water‐advancing (or gas‐receding) angle involved in residual trapping is observed, along with acid gas adhesion, particularly on mica. A spectacular wettability reversal is even observed with mica and liquid H2S. These results complement other recent observations on similar systems and present analogies with the wetting behavior of crude oil/brine/mineral systems, which has been thoroughly studied over the past decades. An insight is given into the interfacial forces that govern wettability in acid gas‐bearing aquifers, and the consequences for acid gas geological storage are discussed along with open questions for future work.

show abstract

Methane hydrates bearing synthetic sediments—Experimental and numerical approaches of the dissociation

Tonnet

¹

,

Herri

²

2009

Chemical Engineering Science

View full text Add to dashboard Cite

HAL is a multidisciplinary open access archive for the deposit and dissemination of scientific research documents, whether they are published or not. The documents may come from teaching and research institutions in France or abroad, or from public or private research centers. L'archive ouverte pluridisciplinaire HAL, est destinée au dépôt et à la diffusion de documents scientifiques de niveau recherche, publiés ou non, émanant des établissements d'enseignement et de recherche français ou étrangers, des laboratoires publics ou privés.

show abstract

Evaluation of the Petrophysical Properties of a Carbonate-rich Caprock for CO2 Geological Storage Purposes

Tonnet

¹

,

Mouronval

²

2010

View full text Add to dashboard Cite

Prior to any CO 2 geological storage operation, the caprock's ability to prevent CO 2 leakage must be carefully assessed. This ability is primarily related to the caprock's pore structure and to the interfacial properties of the caprock and the fluids in place, namely the brine that imbibes the caprock and the CO 2 stored in the underlying reservoir. This paper reports an experimental effort to characterize some of these parameters, using as a working example the carbonate-rich caprock and reservoir conditions of the Rousse depleted gas field in the South-West of France, where an estimated 120000 tons of CO 2 will be injected during two years. The parameters examined are: (i) the caprock wetting behavior in the presence of CO 2 , (ii) the caprock intrinsic (single-phase) permeability, (iii) the CO 2 breakthrough (or displacement) overpressure, i.e., the minimum pressure difference between CO 2 and brine required for CO 2 to penetrate and flow through the brine-saturated caprock, and (iv) the caprock effective permeability to CO 2 after breakthrough. The latter two parameters are indicative of, respectively, the caprock's capillary sealing efficiency and CO 2 leakage rate once breakthrough has occurred.The main observations and results are as follows. (i) The water-wet character of the Rousse caprock in the presence of CO 2 in storage conditions is confirmed through a series of contact angle measurements on substrates. (ii) Single-phase (brine) permeability coefficients measured in steady-state conditions are extremely small and strongly sensitive to the effective stress, i.e., to the difference between the confining pressure and the pore fluid pressure. They do not exceed 20-25 nanodarcy (10 -21 m 2 ) for effective stresses below 4 MPa, and 1 nanodarcy for effective stresses in the range of 10 MPa and above. (iii) Gas breakthrough in two different brine-saturated caprock samples, using either CO 2 or N 2 as the displacing gas phase, occurs in one sample for a CO 2 overpressure in excess of 7.6 MPa, and in the other sample for a N 2 overpressure in the interval of 4.5-6 MPa. In the latter sample, the effective permeability to N 2 after breakthrough is extremely low, below 1 nanodarcy; some "aging" effects are observed upon subsequent resaturations with brine and CO 2 breakthrough experiments, with a CO 2 breakthrough overpressure lower than expected and an increasing effective permeability to gas, yet still lower than 2 nanodarcy after two consecutive brine resaturations and CO 2 breakthroughs.

show abstract

Petrophysical assessment of a carbonate-rich caprock for CO2 geological storage purposes

Tonnet¹,

Mouronval²,

Chiquet³

et al. 2011

View full text Add to dashboard Cite

Evaluation of the Petrophysical Properties of a Carbonate-rich Caprock for CO2 Geological Storage Purposes

Tonnet

¹

,

Mouronval

²

2010

5

1

0

View full text Add to dashboard Cite

Prior to any CO 2 geological storage operation, the caprock's ability to prevent CO 2 leakage must be carefully assessed. This ability is primarily related to the caprock's pore structure and to the interfacial properties of the caprock and the fluids in place, namely the brine that imbibes the caprock and the CO 2 stored in the underlying reservoir. This paper reports an experimental effort to characterize some of these parameters, using as a working example the carbonate-rich caprock and reservoir conditions of the Rousse depleted gas field in the South-West of France, where an estimated 120000 tons of CO 2 will be injected during two years. The parameters examined are: (i) the caprock wetting behavior in the presence of CO 2 , (ii) the caprock intrinsic (single-phase) permeability, (iii) the CO 2 breakthrough (or displacement) overpressure, i.e., the minimum pressure difference between CO 2 and brine required for CO 2 to penetrate and flow through the brine-saturated caprock, and (iv) the caprock effective permeability to CO 2 after breakthrough. The latter two parameters are indicative of, respectively, the caprock's capillary sealing efficiency and CO 2 leakage rate once breakthrough has occurred.The main observations and results are as follows. (i) The water-wet character of the Rousse caprock in the presence of CO 2 in storage conditions is confirmed through a series of contact angle measurements on substrates. (ii) Single-phase (brine) permeability coefficients measured in steady-state conditions are extremely small and strongly sensitive to the effective stress, i.e., to the difference between the confining pressure and the pore fluid pressure. They do not exceed 20-25 nanodarcy (10 -21 m 2 ) for effective stresses below 4 MPa, and 1 nanodarcy for effective stresses in the range of 10 MPa and above. (iii) Gas breakthrough in two different brine-saturated caprock samples, using either CO 2 or N 2 as the displacing gas phase, occurs in one sample for a CO 2 overpressure in excess of 7.6 MPa, and in the other sample for a N 2 overpressure in the interval of 4.5-6 MPa. In the latter sample, the effective permeability to N 2 after breakthrough is extremely low, below 1 nanodarcy; some "aging" effects are observed upon subsequent resaturations with brine and CO 2 breakthrough experiments, with a CO 2 breakthrough overpressure lower than expected and an increasing effective permeability to gas, yet still lower than 2 nanodarcy after two consecutive brine resaturations and CO 2 breakthroughs.

show abstract

Nicolas Tonnet

Are rocks still water‐wet in the presence of dense CO₂ or H₂S?

Methane hydrates bearing synthetic sediments—Experimental and numerical approaches of the dissociation

Evaluation of the Petrophysical Properties of a Carbonate-rich Caprock for CO2 Geological Storage Purposes

Petrophysical assessment of a carbonate-rich caprock for CO2 geological storage purposes

Evaluation of the Petrophysical Properties of a Carbonate-rich Caprock for CO2 Geological Storage Purposes

Contact Info

Product

Resources

About

Nicolas Tonnet

Are rocks still water‐wet in the presence of dense CO2 or H2S?

Methane hydrates bearing synthetic sediments—Experimental and numerical approaches of the dissociation

Evaluation of the Petrophysical Properties of a Carbonate-rich Caprock for CO2 Geological Storage Purposes

Petrophysical assessment of a carbonate-rich caprock for CO2 geological storage purposes

Evaluation of the Petrophysical Properties of a Carbonate-rich Caprock for CO2 Geological Storage Purposes

Contact Info

Product

Resources

About

Are rocks still water‐wet in the presence of dense CO₂ or H₂S?