Determining noble gas partitioning within a CO2–H2O system at elevated temperatures and pressures

Warr, Oliver; Rochelle, Christopher A.; Masters, Andrew J.; Ballentine, C. J.

doi:10.1016/j.gca.2015.03.003

Cited by 27 publications

(35 citation statements)

References 64 publications

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“…Since the calculated values for molecular diffusion are small, mechanical dispersion must be the dominant factor in curve shape. This suggests that there is a higher degree of dispersion with an increase in atomic size, which is confirmed by the modelling results in this study and previous work (Warr et al, 2015). …”

Section: Analytically Derived Transport Modelsupporting

confidence: 92%

Experimental determination of noble gases and SF6, as tracers of CO2 flow through porous sandstone

et al. 2018

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A B S T R A C TIn order to label the CO 2 injected underground for geological storage and allow it to be differentiated from natural sources, a panoply of additive chemical tracers have been proposed. Yet, the transport of these tracers relative to CO 2 in pore space is currently poorly constrained. This leads to uncertainty as to whether tracers will act as an early warning of CO 2 arrival, or be preferentially retained in the pore space making them ineffective. Here, we present the factors affecting transport of noble gases and SF 6 relative to CO 2 in a porous rock. Using a porous sandstone core, each of the tracers were loaded into a sample loop and injected as discrete gas pulses into a CO 2 carrier stream at five different experiment pressures (10-50 kPag upstream to ambient pressure downstream). Tracer arrival profiles were measured using a quadrupole mass spectrometer. Significantly, our results show that peak arrival times of helium were slower than the other noble gases at each pressure gradient. The differences in peak arrival times between helium and other noble gases increased as the pressure gradient along the system decreased and the curve profiles for each noble gas differ significantly. The heavier noble gases (Kr and Xe) along with SF 6 show an earlier arrival time and a wider curve profile compared to He and Ne curves through the CO 2 carrier gas stream. This shows that Kr and Xe could be substituted for SF 6 , a potent greenhouse gas, in tracer applications. For comparison, CO 2 pulses were passed through a N 2 carrier gas resulting in significantly slower peak arrival times compared to those of noble gases and SF 6 . Hence, all investigated tracers when co-injected with CO 2 could potentially act as early warning tracers of CO 2 arrival, though we find that Kr, Xe and SF 6 will provide the most robust advance warning. Analysis of our experimental results shows that they cannot be explained by a simple one dimensional flow model through a porous medium. We outline a conceptual model that incorporates different preferential flow paths depending on flow velocities of individual gas streams. This model can explain the observed dataset and shows that the flow of noble gases and SF 6 tracers is influenced by pore-scale heterogeneity.

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Section: Analytically Derived Transport Modelsupporting

confidence: 92%

Experimental determination of noble gases and SF6, as tracers of CO2 flow through porous sandstone

et al. 2018

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“…It should also be noted that the quantitative estimates presented above are open to revision as they suffer from uncertainties associated with the fractionation and solubility factors which were experimentally determined for low pressure systems (Weiss, 1971(Weiss, , 1974Deines et al, 1974). Despite recent attempts to assess the solubility of He (and other noble gases) at high-pressure and high-temperature ranges (more relevant for carbon capture and storage, CCS, technologies) (Warr et al, 2015), the lack of information about the isotopic fractionation factors for highpressure systems restricts, at this stage, further constraints on this issue.…”

Section: Discussionmentioning

confidence: 99%

Turkish geothermal fields as natural analogues of CO 2 storage sites: Gas geochemistry and implications for CO 2 trapping mechanisms

Güleç

Hilton

2016

Geothermics

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“…When trace amounts of noble gases are present within a gas-water binary phase system, they exist as solute particles within both phases [1][2][3] . The exact ratio of noble gases in each phase, the partitioning, is dependent on environmental factors such as temperature and phase composition [2][3] .…”

Section: Introductionmentioning

confidence: 99%

Optimizing Noble Gas–Water Interactions via Monte Carlo Simulations

Warr

Ballentine

et al. 2015

J. Phys. Chem. B

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In this work we present optimized noble gas-water Lennard-Jones 6-12 pair potentials for each noble gas. Given the significantly different atomic nature of water and the noble gases, the standard Lorentz-Berthelot mixing rules produce inaccurate unlike molecular interactions between these two species. Consequently, we find simulated Henry's coefficients deviate significantly from their experimental counterparts for the investigated thermodynamic range (293-353 K at 1 and 10 atm), due to a poor unlike potential well term (εij). Where εij is too high or low, so too is the strength of the resultant noble gas-water interaction. This observed inadequacy in using the Lorentz-Berthelot mixing rules is countered in this work by scaling εij for helium, neon, argon, and krypton by factors of 0.91, 0.8, 1.1, and 1.05, respectively, to reach a much improved agreement with experimental Henry's coefficients. Due to the highly sensitive nature of the xenon εij term, coupled with the reasonable agreement of the initial values, no scaling factor is applied for this noble gas. These resulting optimized pair potentials also accurately predict partitioning within a CO2-H2O binary phase system as well as diffusion coefficients in ambient water. This further supports the quality of these interaction potentials. Consequently, they can now form a well-grounded basis for the future molecular modeling of multiphase geological systems.

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Determining noble gas partitioning within a CO2–H2O system at elevated temperatures and pressures

Cited by 27 publications

References 64 publications

Experimental determination of noble gases and SF6, as tracers of CO2 flow through porous sandstone

Experimental determination of noble gases and SF6, as tracers of CO2 flow through porous sandstone

Turkish geothermal fields as natural analogues of CO 2 storage sites: Gas geochemistry and implications for CO 2 trapping mechanisms

Optimizing Noble Gas–Water Interactions via Monte Carlo Simulations

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