Standard

K2CO3-Containing Composite Sorbents Based on Thermally Modified Alumina : Synthesis, Properties, and Potential Application in a Direct Air Capture/Methanation Process. / Veselovskaya, Janna V.; Lysikov, Anton I.; Netskina, Olga V. et al.

In: Industrial and Engineering Chemistry Research, Vol. 59, No. 15, 15.04.2020, p. 7130-7139.

Research output: Contribution to journalArticlepeer-review

Harvard

Veselovskaya, JV, Lysikov, AI, Netskina, OV, Kuleshov, DV & Okunev, AG 2020, 'K2CO3-Containing Composite Sorbents Based on Thermally Modified Alumina: Synthesis, Properties, and Potential Application in a Direct Air Capture/Methanation Process', Industrial and Engineering Chemistry Research, vol. 59, no. 15, pp. 7130-7139. https://doi.org/10.1021/acs.iecr.9b05457

APA

Veselovskaya, J. V., Lysikov, A. I., Netskina, O. V., Kuleshov, D. V., & Okunev, A. G. (2020). K2CO3-Containing Composite Sorbents Based on Thermally Modified Alumina: Synthesis, Properties, and Potential Application in a Direct Air Capture/Methanation Process. Industrial and Engineering Chemistry Research, 59(15), 7130-7139. https://doi.org/10.1021/acs.iecr.9b05457

Vancouver

Veselovskaya JV, Lysikov AI, Netskina OV, Kuleshov DV, Okunev AG. K2CO3-Containing Composite Sorbents Based on Thermally Modified Alumina: Synthesis, Properties, and Potential Application in a Direct Air Capture/Methanation Process. Industrial and Engineering Chemistry Research. 2020 Apr 15;59(15):7130-7139. doi: 10.1021/acs.iecr.9b05457

Author

Veselovskaya, Janna V. ; Lysikov, Anton I. ; Netskina, Olga V. et al. / K2CO3-Containing Composite Sorbents Based on Thermally Modified Alumina : Synthesis, Properties, and Potential Application in a Direct Air Capture/Methanation Process. In: Industrial and Engineering Chemistry Research. 2020 ; Vol. 59, No. 15. pp. 7130-7139.

BibTeX

@article{4feeafbe65224a8688903b36f96060c6,
title = "K2CO3-Containing Composite Sorbents Based on Thermally Modified Alumina: Synthesis, Properties, and Potential Application in a Direct Air Capture/Methanation Process",
abstract = "In this work, a series of K2CO3-containing composite materials based on alumina supports with different porous structure were synthesized and studied in a direct air capture process. Alumina supports with the modified porous structure were obtained as a result of the thermal treatment of porous γ-Al2O3 at elevated temperatures. Composite materials were synthesized by impregnating the porous support (unmodified or modified alumina) with an aqueous solution of potassium carbonate. All the K2CO3/Al2O3 sorbents were tested in the process of CO2 absorption from the air with a relative humidity of 25% followed by thermal desorption as a result of heating the material to 200 °C. The composite materials were characterized by X-ray diffraction and temperature-programmed desorption methods. Among the materials studied, the composite sorbent based on the porous alumina thermally modified at T = 750 °C demonstrated the highest dynamic CO2 absorption capacity. This composite material was later tested in a direct air capture/methanation process combining CO2 capture from ambient air and methanation via the catalytic Sabatier reaction. The process was implicated using an adsorber and a catalytic reactor connected in series. To regenerate the composite sorbent after the step of CO2 absorption from ambient air, the adsorber was heated to 200 °C in an H2 flow. The desorbed CO2 was converted into methane in the preheated catalytic reactor containing the Ru/Al2O3 methanation catalyst. The optimization of the operating conditions (namely, the catalytic reactor temperature and the inlet H2 flow rate) allowed for obtaining CH4 from carbon dioxide with a yield of 98%. The thermal energy required for heating the new CO2 sorbent from 25 to 200 °C at the desorption/methanation step of the direct air capture/methanation process was estimated to be 9 MJ per 1 m3 (STP) of produced CH4.",
keywords = "DIRECT CO2 CAPTURE, POWER-TO-GAS, RENEWABLE ENERGY, METHANATION, HYDROGENATION, KINETICS, FUTURE",
author = "Veselovskaya, {Janna V.} and Lysikov, {Anton I.} and Netskina, {Olga V.} and Kuleshov, {Dmitry V.} and Okunev, {Aleksey G.}",
year = "2020",
month = apr,
day = "15",
doi = "10.1021/acs.iecr.9b05457",
language = "English",
volume = "59",
pages = "7130--7139",
journal = "Industrial & Engineering Chemistry Research",
issn = "0888-5885",
publisher = "American Chemical Society",
number = "15",

}

RIS

TY - JOUR

T1 - K2CO3-Containing Composite Sorbents Based on Thermally Modified Alumina

T2 - Synthesis, Properties, and Potential Application in a Direct Air Capture/Methanation Process

AU - Veselovskaya, Janna V.

AU - Lysikov, Anton I.

AU - Netskina, Olga V.

AU - Kuleshov, Dmitry V.

AU - Okunev, Aleksey G.

PY - 2020/4/15

Y1 - 2020/4/15

N2 - In this work, a series of K2CO3-containing composite materials based on alumina supports with different porous structure were synthesized and studied in a direct air capture process. Alumina supports with the modified porous structure were obtained as a result of the thermal treatment of porous γ-Al2O3 at elevated temperatures. Composite materials were synthesized by impregnating the porous support (unmodified or modified alumina) with an aqueous solution of potassium carbonate. All the K2CO3/Al2O3 sorbents were tested in the process of CO2 absorption from the air with a relative humidity of 25% followed by thermal desorption as a result of heating the material to 200 °C. The composite materials were characterized by X-ray diffraction and temperature-programmed desorption methods. Among the materials studied, the composite sorbent based on the porous alumina thermally modified at T = 750 °C demonstrated the highest dynamic CO2 absorption capacity. This composite material was later tested in a direct air capture/methanation process combining CO2 capture from ambient air and methanation via the catalytic Sabatier reaction. The process was implicated using an adsorber and a catalytic reactor connected in series. To regenerate the composite sorbent after the step of CO2 absorption from ambient air, the adsorber was heated to 200 °C in an H2 flow. The desorbed CO2 was converted into methane in the preheated catalytic reactor containing the Ru/Al2O3 methanation catalyst. The optimization of the operating conditions (namely, the catalytic reactor temperature and the inlet H2 flow rate) allowed for obtaining CH4 from carbon dioxide with a yield of 98%. The thermal energy required for heating the new CO2 sorbent from 25 to 200 °C at the desorption/methanation step of the direct air capture/methanation process was estimated to be 9 MJ per 1 m3 (STP) of produced CH4.

AB - In this work, a series of K2CO3-containing composite materials based on alumina supports with different porous structure were synthesized and studied in a direct air capture process. Alumina supports with the modified porous structure were obtained as a result of the thermal treatment of porous γ-Al2O3 at elevated temperatures. Composite materials were synthesized by impregnating the porous support (unmodified or modified alumina) with an aqueous solution of potassium carbonate. All the K2CO3/Al2O3 sorbents were tested in the process of CO2 absorption from the air with a relative humidity of 25% followed by thermal desorption as a result of heating the material to 200 °C. The composite materials were characterized by X-ray diffraction and temperature-programmed desorption methods. Among the materials studied, the composite sorbent based on the porous alumina thermally modified at T = 750 °C demonstrated the highest dynamic CO2 absorption capacity. This composite material was later tested in a direct air capture/methanation process combining CO2 capture from ambient air and methanation via the catalytic Sabatier reaction. The process was implicated using an adsorber and a catalytic reactor connected in series. To regenerate the composite sorbent after the step of CO2 absorption from ambient air, the adsorber was heated to 200 °C in an H2 flow. The desorbed CO2 was converted into methane in the preheated catalytic reactor containing the Ru/Al2O3 methanation catalyst. The optimization of the operating conditions (namely, the catalytic reactor temperature and the inlet H2 flow rate) allowed for obtaining CH4 from carbon dioxide with a yield of 98%. The thermal energy required for heating the new CO2 sorbent from 25 to 200 °C at the desorption/methanation step of the direct air capture/methanation process was estimated to be 9 MJ per 1 m3 (STP) of produced CH4.

KW - DIRECT CO2 CAPTURE

KW - POWER-TO-GAS

KW - RENEWABLE ENERGY

KW - METHANATION

KW - HYDROGENATION

KW - KINETICS

KW - FUTURE

UR - http://www.scopus.com/inward/record.url?scp=85084641561&partnerID=8YFLogxK

U2 - 10.1021/acs.iecr.9b05457

DO - 10.1021/acs.iecr.9b05457

M3 - Article

AN - SCOPUS:85084641561

VL - 59

SP - 7130

EP - 7139

JO - Industrial & Engineering Chemistry Research

JF - Industrial & Engineering Chemistry Research

SN - 0888-5885

IS - 15

ER -

ID: 24313008