Studies on structural aspects of cellulose acetate

Improvement in the efficiency of CO 2 separation from flue gases is a high-priority research area to reduce the total energy cost of carbon capture and sequestration technologies in coal-fired power plants. Efficient CO 2 removal from flue gases by adsorption systems requires the design of novel sorbents capable of capturing, concentrating, and recovering CO 2 on a cost-effective basis. This paper describes the preparation of an aminosilane-functionalized cellulosic polymer sorbent with enhanced CO 2 sorption capacity and promising performance for use in postcombustion carbon capture via rapid temperature-swing adsorption systems. The introduction of aminosilane functionalities onto the backbone of cellulose acetate was achieved by the anhydrous grafting of N-(2aminoethyl)-3-aminoisobutyldimethylmethoxysilane. The dry sorption capacity of the modified cellulosic polymer reached 27 cc (STP) CO 2 /cc sorbent (1.01 mmol/g sorbent) at 1 atm and 39 cc (STP) CO 2 /cc sorbent (1.46 mmol/g sorbent) at 5 atm and 308 K. The amine loading achieved was 5.18 mmol amine(nitrogen)/g sorbent. Exposure to water vapor after the first dry sorption cycle increased the dry sorption capacity of the sorbent by 12% at 1 atm, suggesting its potential for rapid cyclic adsorption processes under humid feed conditions. The CO 2 sorbent was characterized in terms of chemical composition, density changes, molecular structure, thermal stability, and surface morphology.

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Aminosilane-Functionalized Cellulosic Polymer for Increased Carbon Dioxide Sorption

Pacheco

Johnson

Koros

2011

Ind. Eng. Chem. Res.

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Aminosilane-Functionalized Hollow Fiber Sorbents for Post-Combustion CO₂ Capture

Lively²,

Lee

et al. 2013

Ind. Eng. Chem. Res.

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Increasing carbon dioxide emissions are generally believed to contribute to global warming. Developing new materials for capturing CO 2 emitted from coal-fired plants can potentially mitigate the effect of these CO 2 emissions. In this study, we developed and optimized porous hollow fiber sorbents with both improved sorption capacities and rapid sorption kinetics by functionalizing aminosilane (N-(2-aminoethyl)-3-aminoisobutyldimethylmethoxysilane) to cellulose acetate hollow fibers as a "proof of concept". A lumen-side barrier layer was also developed in the aminosilane-functionalized cellulose acetate fiber sorbent to allow for facile heat exchange without significant mass transfer with the bore-side heat transfer fluid. The functionalized cellulose acetate fiber sorbents were characterized by pressure decay sorption measurements, multicomponent column chromatography, FT-IR, elemental analysis, and scanning electron microscopy. The carbon dioxide sorption capacity at 1 atm is 0.73 mmol/g by using the pressure decay apparatus. Multicomponent column chromatography measurements showed that aminosilane functionalized cellulose acetate fiber sorbent has a CO 2 sorption capacity of 0.23 mmol/g at CO 2 partial pressure 0.1 atm and 35 °C in simulated flue gas. While this capacity is low, our proof of concept positions the technology to move forward to higher capacity with work that is underway. The presence of silicon and nitrogen elements in the elemental analysis confirmed the success of grafting along with FT-IR spectra which showed the absorbance peak (∼810 cm −1 ) for Si−C stretching. A crosslinked Neoprene material was used to form the lumen-side barrier layer. Preliminary data showed the required reduction in gas permeance to eliminate mixing between shell side and bore side fluid flows. Specifically the permeance was reduced from 10 000 GPUs for the neat fibers to 6.6 ± 0.1 and 3.3 ± 0.3 GPUs for the coated fibers. The selected lumen layer formation materials demonstrated strong resistance to water and oxygen.

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Polymorphic Transformations of Cellulose Acetates Prepared by Solution Acetylation at an Elevated Temperature

Tang¹,

Hon²,

Zhu³

1996

Journal of Macromolecular Science, Part A

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Studies on structural aspects of cellulose acetate

Cited by 3 publications

References 20 publications

Aminosilane-Functionalized Cellulosic Polymer for Increased Carbon Dioxide Sorption

Aminosilane-Functionalized Cellulosic Polymer for Increased Carbon Dioxide Sorption

Aminosilane-Functionalized Hollow Fiber Sorbents for Post-Combustion CO₂ Capture

Polymorphic Transformations of Cellulose Acetates Prepared by Solution Acetylation at an Elevated Temperature

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Studies on structural aspects of cellulose acetate

Cited by 3 publications

References 20 publications

Aminosilane-Functionalized Cellulosic Polymer for Increased Carbon Dioxide Sorption

Aminosilane-Functionalized Cellulosic Polymer for Increased Carbon Dioxide Sorption

Aminosilane-Functionalized Hollow Fiber Sorbents for Post-Combustion CO2 Capture

Polymorphic Transformations of Cellulose Acetates Prepared by Solution Acetylation at an Elevated Temperature

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Product

Resources

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Aminosilane-Functionalized Hollow Fiber Sorbents for Post-Combustion CO₂ Capture