![Kinetic analysis of the carbonation reactions for the capture of CO"2 from air via the Ca(OH)"2-CaCO"3-CaO solar thermochemical cycle [An article from: Chemical Engineering Journal]](https://www.ebooknetworking.net/books/B00/0PK/bigB000PKI3J0.jpg)
Kinetic analysis of the carbonation reactions for the capture of CO"2 from air via the Ca(OH)"2-CaCO"3-CaO solar thermochemical cycle [An article from: Chemical Engineering Journal]
Book Details
PublisherElsevier
ISBN / ASINB000PKI3J0
ISBN-13978B000PKI3J9
AvailabilityAvailable for download now
Sales Rank9,287,593
MarketplaceUnited States 🇺🇸
Description
This digital document is a journal article from Chemical Engineering Journal, published by Elsevier in 2007. The article is delivered in HTML format and is available in your Amazon.com Media Library immediately after purchase. You can view it with any web browser.
Description:
A thermogravimetric analysis of the carbonation of CaO and Ca(OH)"2 with 500ppm CO"2 in air at 200-450^oC is performed as part of a three-step thermochemical cycle to capture CO"2 from air using concentrating solar energy. The rate of CaO-carbonation is fitted to an unreacted core kinetic model that encompasses intrinsic chemical reaction followed by intra-particle diffusion. In contrast, the Ca(OH)"2-carbonation is less hindered by diffusion while catalyzed by water formation, and its rate is fitted to a chemically-controlled kinetic model at the solid interface not covered by CaCO"3. The rates of both carbonation reactions increase with temperature, peak at 400-450^oC, and decrease above 450^oC as a result of the thermodynamically favored reverse CaCO"3-decomposition. Avrami's empirical rate law is applied to describe the CO"2 uptake from the continuous air flow by CaO and Ca(OH)"2, with and without added water. The addition of water vapor significantly enhances the reaction kinetics to the extent that, in the first 20min, the reaction proceeds at a rate that is 22 and nine times faster than that observed for the dry carbonation of CaO and Ca(OH)"2, respectively.
Description:
A thermogravimetric analysis of the carbonation of CaO and Ca(OH)"2 with 500ppm CO"2 in air at 200-450^oC is performed as part of a three-step thermochemical cycle to capture CO"2 from air using concentrating solar energy. The rate of CaO-carbonation is fitted to an unreacted core kinetic model that encompasses intrinsic chemical reaction followed by intra-particle diffusion. In contrast, the Ca(OH)"2-carbonation is less hindered by diffusion while catalyzed by water formation, and its rate is fitted to a chemically-controlled kinetic model at the solid interface not covered by CaCO"3. The rates of both carbonation reactions increase with temperature, peak at 400-450^oC, and decrease above 450^oC as a result of the thermodynamically favored reverse CaCO"3-decomposition. Avrami's empirical rate law is applied to describe the CO"2 uptake from the continuous air flow by CaO and Ca(OH)"2, with and without added water. The addition of water vapor significantly enhances the reaction kinetics to the extent that, in the first 20min, the reaction proceeds at a rate that is 22 and nine times faster than that observed for the dry carbonation of CaO and Ca(OH)"2, respectively.
