Sarah Genovese scite author profile

A novel method for the postcombustion capture of CO 2 from coal-fired power plants has been described utilizing an aminosilicone absorbent. 1,3-Bis(3-aminopropyl)-1,1,3,3-tetramethyldsiloxane (GAP-0) rapidly transforms from a low viscosity liquid to a friable solid upon exposure to CO 2 in simulated flue gas. This material has excellent thermal stability, low vapor pressure, high CO 2 loading capability, and a large dynamic CO 2 capacity between rich and lean solvent loadings. Preliminary plant and process models assembled from experimental data show a decrease in parasitic energy loss from 30% to 18% when compared to the benchmark monoethanolamine (MEA) process and a concomitant lowering of the cost of electricity (COE) from 74% to 44% increase versus a plant without carbon capture.

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Aminosilicone Solvents for CO₂ Capture

Perry

Grocela‐Rocha

O’Brien

et al. 2010

ChemSusChem

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This work describes the first report of the use of an aminosilicone solvent mix for the capture of CO(2). To maintain a liquid state, a hydroxyether co-solvent was employed which allowed enhanced physisorption of CO(2) in the solvent mixture. Regeneration of the capture solvent system was demonstrated over 6 cycles and absorption isotherms indicate a 25-50 % increase in dynamic CO(2) capacity over 30 % MEA. In addition, proof of concept for continuous CO(2) absorption was verified. Additionally, modeling to predict heats of reaction of aminosilicone solvents with CO(2) was in good agreement with experimental results.

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A Computational Study of the Heats of Reaction of Substituted Monoethanolamine with CO₂

et al. 2010

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Various amines have been considered as materials for chemical capture of CO(2) through liquid-phase reactions to form either carbamate or carbamic acid products. One of the main challenges in these CO(2)-amine reactions lies in tuning the heat of reaction to achieve the correct balance between the extent of reaction and the energy cost for regeneration. In this work, we use a computational approach to study the effect of substitution on the heats of reaction of monoethanolamine (MEA). We use ab initio methods at the MP2/aug-cc-pVDZ level, coupled with geometries generated from B3LYP/6-311++G(d,p) density functional theory along with the conductor-like polarizable continuum model to compute the heats of reaction. We consider two possible reaction products: carbamate, having a 2:1 amine:CO(2) reaction stoichiometry, and carbamic acid, having a 1:1 stoichiometry. We have considered CH(3), NH(2), OH, OCH(3), and F substitution groups at both the α- and β-carbon positions of MEA. We have experimentally measured heats of reaction for MEA and both α- and β-CH(3)-substituted MEA to test the predictions of our model. We find quantitative agreement between the predictions and experiments. We have also computed the relative basicities of the substituted amines and found that the heats of reaction for both carbamate and carbamic acid products are linearly correlated with the computed relative basicities. Weaker basicities result in less exothermic heats of reaction. Heats of reaction for carbamates are much more sensitive to changes in basicity than those for carbamic acids. This leads to a crossover in the heat of reaction so that carbamic acid formation becomes thermodynamically favored over carbamate formation for the weakest basicities. This provides a method for tuning the reaction stoichiometry from 2:1 to 1:1.

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Selective Chemical Sensing Using Structurally Colored Core-Shell Colloidal Crystal Films

Potyrailo¹,

Ding²,

Butts³

et al. 2008

IEEE Sensors J.

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We demonstrate for the first time selective sensing of multiple vapors at low concentrations based on the structurally colored colloidal crystal film formed from composite core/shell nanospheres. Since color changes of sensing colloidal crystal films are negligible at relatively low vapor partial pressures ( 0 0 1), a straightforward detection of color changes cannot be applied. To overcome this limitation, we apply a differential spectroscopy measurement approach coupled with the multivariate analysis of differential reflectance spectra. The vapor-sensing selectivity is provided by the combination of the composite nature of the colloidal nanospheres in the film with the multivariate analysis of the spectral changes of the film reflectivity upon exposure to different vapors. The multianalyte sensing was demonstrated using a colloidal crystal film comprised of 326-nm diameter core polystyrene nanospheres coated with a 20-nm thick sol-gel shell. Discrimination of water, acetonitrile, toluene, and dichloromethane vapors using a single sensing colloidal crystal film was evaluated applying principal components analysis (PCA) of the reflectivity spectra. The polar and nonpolar vapors at different relative vapor partial pressures were well separated in PCA space. The best selectivity was obtained between toluene and dichloromethane vapors, while water and acetonitrile vapors were almost unresolved. Achieved detection limits were within the range of interest or better than those needed for determinations of these vapors for industrial applications.

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Angle-dependent XPS study of functional group orientation for aminosilicone polymers adsorbed onto cellulose surfaces

Burrell¹,

Butts²,

Derr³

et al. 2004

Applied Surface Science

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Sarah Genovese

CO₂ Capture Using Phase-Changing Sorbents

Aminosilicone Solvents for CO₂ Capture

A Computational Study of the Heats of Reaction of Substituted Monoethanolamine with CO₂

Selective Chemical Sensing Using Structurally Colored Core-Shell Colloidal Crystal Films

Angle-dependent XPS study of functional group orientation for aminosilicone polymers adsorbed onto cellulose surfaces

Contact Info

Product

Resources

About

Sarah Genovese

CO2 Capture Using Phase-Changing Sorbents

Aminosilicone Solvents for CO2 Capture

A Computational Study of the Heats of Reaction of Substituted Monoethanolamine with CO2

Selective Chemical Sensing Using Structurally Colored Core-Shell Colloidal Crystal Films

Angle-dependent XPS study of functional group orientation for aminosilicone polymers adsorbed onto cellulose surfaces

Contact Info

Product

Resources

About

CO₂ Capture Using Phase-Changing Sorbents

Aminosilicone Solvents for CO₂ Capture

A Computational Study of the Heats of Reaction of Substituted Monoethanolamine with CO₂