A new methodology is proposed for the acceleration of CO 2 dissolution to lower the risk of CO 2 leakage for carbon capture and storage (CCS) technology. It is called ex situ dissolution because CO 2 is being dissolved at a surface before it is injected underground. This new approach reduces or eliminates possible leakage of CO 2 from underground formation. To achieve full underground dissolution of injected pure supercritical CO 2 or gaseous CO 2 may take thousands of years because of the absence of strong mixing (convective-diffusion dominated processes). Dissolving CO 2 in brine before injection significantly increases the security of geological sequestration. The mass transfer from CO 2 droplets into brine during cocurrent (CO 2 Àbrine) horizontal pipe flow is studied mathematically to investigate the effectiveness of the proposed method. The dissolution rate of the CO 2 droplets is correlated to the variation of mean droplet diameter versus time, because the mass transfer causes shrinkage of the droplets. Empirical correlations based on Sherwood numbers were employed in the example for calculation of mass-transfer coefficients for droplets of CO 2 in the fluid flowing through a pipe.
A series of ferrocenyl conjugates to fatty acids have been designed and synthesized to establish the key properties required for use in biomolecular binding studies. Amperometric detection of the ferrocene conjugates was sought in the region of 0.3 V (vs Ag/AgCl) for use in protein/blood solutions. Different linkers and solubilizing moieties were incorporated to produce a conjugate with optimal electrochemical properties. In electrochemical studies, the linker directly attached to the ferrocene was found to affect significantly the E(1/2) value and the stability of the ferrocenium cation. Ester-linked ferrocene conjugates had E(1/2) ranging from +400 to +410 mV, while amide-linked compounds ranged from +350 to +370 mV and the amines +260 to +270 mV. Folding of long-chain substituents around the ferrocene, also significantly affected by the choice of linker, was inferred as a secondary effect that increased E(1/2). The stability of the ferrocenium cation decreased systematically as E(1/2) increased. Disubstituted ferrocene ester and amide conjugates, with oxidation potentials of +640 and +570 mV, respectively, showed only a barely discernible reduction wave in cyclic voltammetry at 50 mV/s. Electrochemical measurements identified two lead compounds with the common structural characteristics of an amide and carbamate linker (compounds 17 and 21) with a C(11) fatty acid chain attached. It is envisaged that such molecules can be used to mimic and study the biomolecular binding interaction between fatty acids and molecules such as human serum albumin.
The development of electrochemical probes useful for investigating the occupancy by other molecules of sites on complex proteins such as human serum albumin (HSA) is described. Ferrocenyl-(oxoethylene)-fatty acid compounds of different fatty acid chain length probed different binding sites on HSA. The interaction could be changed from one primarily with a drug binding site, when the probe was ferrocene methanol, to one predominantly with medium-chain fatty acid binding sites, by adding an (oxoethylene)-fatty acid substituents. Finally, the interaction could be changed to one interacting primarily with high-affinity long-chain fatty acid binding sites, as the fatty acid chain length in ferrocene-(oxoethylene)-fatty acid molecules increased. These results strongly implied that the binding could be further tailored by relatively simple modifications to the probe, for example, by changing the balance of hydrophobicity and hydrophilicity. The possibility of a procedure using mass-produced electrochemical cells to determine the fractional occupancy of different sites on HSA is demonstrated.
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.