Selective separation of CO2 is a field of intensive research due to emerging emissions from fire coaled and natural gas power plants. In the focus of development efforts is a design of regenerable CO2 capture material where adsorption technologies and advanced solid adsorbents are again in the centre of interest. Short screening of composite zeolite/activated carbon material in the terms of its selectivity for CO2 towards water is presented in this research. Adsorption rate of CO2 and H2O is determined and analysed at two different temperatures and equilibrium pressure of 3.5 kPa which corresponds to flue gases contents. The results imply the water should be removed from treated gas before CO2 separation and capture. Design of advanced materials can be facilitated by implementation of DFT calculations. A preview of DFT analysed materials with higher affinity for CO2 than for water adsorption is presented within this research. It underscores the possibility of defining future strategies... for the design of novel carbon dioxide capture materials more resistant to water compared to currently used zeolites.
TY - CONF
AU - Ječmenica Dučić, Marija
AU - Vasić Anićijević, Dragana D.
AU - Savić, Branislava
AU - Aćimović, Danka
AU - Simić, Marija
AU - Maksin, Danijela
AU - Brdarić, Tanja
PY - 2022
UR - https://vinar.vin.bg.ac.rs/handle/123456789/10712
AB - Selective separation of CO2 is a field of intensive research due to emerging emissions from fire coaled and natural gas power plants. In the focus of development efforts is a design of regenerable CO2 capture material where adsorption technologies and advanced solid adsorbents are again in the centre of interest. Short screening of composite zeolite/activated carbon material in the terms of its selectivity for CO2 towards water is presented in this research. Adsorption rate of CO2 and H2O is determined and analysed at two different temperatures and equilibrium pressure of 3.5 kPa which corresponds to flue gases contents. The results imply the water should be removed from treated gas before CO2 separation and capture. Design of advanced materials can be facilitated by implementation of DFT calculations. A preview of DFT analysed materials with higher affinity for CO2 than for water adsorption is presented within this research. It underscores the possibility of defining future strategies for the design of novel carbon dioxide capture materials more resistant to water compared to currently used zeolites.
PB - University of Belgrade, Technical Faculty in Bor
C3 - "EcoTER’22" : Proceedings
T1 - New Strategies For Development Of Highly Selective Materials For Carbon Dioxide Capturective materials for carbon dioxide capture
SP - 81
EP - 84
UR - https://hdl.handle.net/21.15107/rcub_vinar_10712
ER -
@conference{
author = "Ječmenica Dučić, Marija and Vasić Anićijević, Dragana D. and Savić, Branislava and Aćimović, Danka and Simić, Marija and Maksin, Danijela and Brdarić, Tanja",
year = "2022",
abstract = "Selective separation of CO2 is a field of intensive research due to emerging emissions from fire coaled and natural gas power plants. In the focus of development efforts is a design of regenerable CO2 capture material where adsorption technologies and advanced solid adsorbents are again in the centre of interest. Short screening of composite zeolite/activated carbon material in the terms of its selectivity for CO2 towards water is presented in this research. Adsorption rate of CO2 and H2O is determined and analysed at two different temperatures and equilibrium pressure of 3.5 kPa which corresponds to flue gases contents. The results imply the water should be removed from treated gas before CO2 separation and capture. Design of advanced materials can be facilitated by implementation of DFT calculations. A preview of DFT analysed materials with higher affinity for CO2 than for water adsorption is presented within this research. It underscores the possibility of defining future strategies for the design of novel carbon dioxide capture materials more resistant to water compared to currently used zeolites.",
publisher = "University of Belgrade, Technical Faculty in Bor",
journal = ""EcoTER’22" : Proceedings",
title = "New Strategies For Development Of Highly Selective Materials For Carbon Dioxide Capturective materials for carbon dioxide capture",
pages = "81-84",
url = "https://hdl.handle.net/21.15107/rcub_vinar_10712"
}
Ječmenica Dučić, M., Vasić Anićijević, D. D., Savić, B., Aćimović, D., Simić, M., Maksin, D.,& Brdarić, T.. (2022). New Strategies For Development Of Highly Selective Materials For Carbon Dioxide Capturective materials for carbon dioxide capture. in "EcoTER’22" : Proceedings
University of Belgrade, Technical Faculty in Bor., 81-84.
https://hdl.handle.net/21.15107/rcub_vinar_10712
Ječmenica Dučić M, Vasić Anićijević DD, Savić B, Aćimović D, Simić M, Maksin D, Brdarić T. New Strategies For Development Of Highly Selective Materials For Carbon Dioxide Capturective materials for carbon dioxide capture. in "EcoTER’22" : Proceedings. 2022;:81-84.
https://hdl.handle.net/21.15107/rcub_vinar_10712 .
Ječmenica Dučić, Marija, Vasić Anićijević, Dragana D., Savić, Branislava, Aćimović, Danka, Simić, Marija, Maksin, Danijela, Brdarić, Tanja, "New Strategies For Development Of Highly Selective Materials For Carbon Dioxide Capturective materials for carbon dioxide capture" in "EcoTER’22" : Proceedings (2022):81-84,
https://hdl.handle.net/21.15107/rcub_vinar_10712 .
