Direct CO2 capture from ambient air using K2CO3/Al2O3 composite sorbent

International Journal of Greenhouse Gas Control

Volumn 17, Issue , 2013, Pages 332-340

  Veselovskaya, Janna V ^a,b   Derevschikov, Vladimir S ^a,b   Kardash, Tatyana Yu ^a,b   Stonkus, Olga A ^a   Trubitsina, Tatiana A ^c   Okunev, Aleksey G ^a,b  

^a BORESKOV INSTITUTE OF CATALYSIS   (Russian Federation)

^b NOVOSIBIRSK STATE UNIVERSITY   (Russian Federation)

^c OOO Aeroservice   (Russian Federation)

Author keywords

Absorption; Alumina; Carbon dioxide; Composite material; Potassium carbonate

Indexed keywords

ABSORPTION; ABSORPTION SPECTROSCOPY; ALUMINA; ALUMINUM OXIDE; CARBON CAPTURE; COMPOSITE MATERIALS; DIFFERENTIAL SCANNING CALORIMETRY; GAS ADSORPTION; HIGH RESOLUTION TRANSMISSION ELECTRON MICROSCOPY; POTASH; SCANNING ELECTRON MICROSCOPY; TEMPERATURE; THERMOGRAVIMETRIC ANALYSIS;

ATOMIC ABSORPTION SPECTROSCOPY; COMPOSITE SORBENTS; CONTINUOUS-FLOW SYSTEM; DIRECT CARBONS; EFFECT OF TEMPERATURE; LOW-TEMPERATURE NITROGEN; REGENERATION TEMPERATURE; THERMAL REGENERATION;

CARBON DIOXIDE;

ABSORPTION; ADSORPTION; ALUMINUM OXIDE; AMBIENT AIR; CARBON DIOXIDE; CARBON SEQUESTRATION; CARBONATE; CHEMICAL COMPOSITION; COMPOSITE; DESORPTION; POTASSIUM; TEMPERATURE EFFECT;

EID: 84879475852     PISSN: 17505836     EISSN: None     Source Type: Journal    
DOI: 10.1016/j.ijggc.2013.05.006     Document Type: Article

References (59)

1. Baciocchi R., Storti G., Mazzotti M. Process design and energy requirements for the capture of carbon dioxide from air. Chemical Engineering and Processing 2006, 45:1047-1058.
2. 2 removal and fixation. Energy Conversion and Management 1995, 36:899-902.
3. 2-containing gas mixtures over amine-bearing pore-expanded MCM-41 silica: application for gas purification. Industrial and Engineering Chemistry Research 2009, 49:359-365.
4. 2 capture. Energy and Fuels 2011, 25:2416-2425.
5. 2 capture from simulated flue gas or ambient air. Industrial and Engineering Chemistry Research 2011, 50:14203-14210.
6. 2 from simulated flue gas and ambient air. Energy and Fuels 2011, 25:5528-5537.
7. 2 adsorption on SBA-15 grafted with γ-(aminopropyl)triethoxysilane. Energy and Fuels 2003, 17:468-473.
8. Cheary R.W., Coelho A.A., Cline J.P. Fundamental parameters line profile fitting in laboratory diffractometers. Journal of Research of the National Institute of Standards and Technology 2004, 109:1-25.
9. Choi S., Drese J.H., Jones C.W. Adsorbent materials for carbon dioxide capture from large anthropogenic point sources. ChemSusChem 2009, 2:796-854.
10. 2 capture from the ambient air. Environmental Science and Technology 2011, 45:2420-2427.
11. 2 capture from ambient air. ChemSusChem 2011, 4:628-635.
12. 2 adsorption from ultradilute gases. Journal of Physical Chemistry Letters 2012, 3:1136-1141.
13. D'Alessandro D.M., Smit B., Long J.R. Carbon dioxide capture: prospects for new materials. Angewandte Chemie International Edition 2010, 49:6058-6082.
14. Davis J., Rochelle G. Thermal degradation of monoethanolamine at stripper conditions. Energy Procedia 2009, 1:327-333.
15. 2O. Journal of Physical Chemistry C 2012, 116:14461-14470.
16. 2. Industrial and Engineering Chemistry Research 2005, 44:8007-8013.
17. 2 capture from air. Environmental Science and Technology 2011, 45:9101-9108.
18. Goeppert A., Czaun M., May R.B., Prakash G.K.S., Olah G.A., Narayanan S.R. Carbon dioxide capture from the air using a polyamine based regenerable solid adsorbent. Journal of the American Chemical Society 2011, 133:20164-20167.
19. 2 capture from the atmosphere. Energy Environmental Science 2012, 5:7833-7853.
20. 3-on-carbon. Industrial and Engineering Chemistry Research 1998, 37:185-191.
21. 2 adsorbents in the presence of oxygen-containing gases. Microporous and Mesoporous Materials 2011, 145:146-149.
22. Huang H.Y., Yang R.T., Chinn D., Munson C.L. Amine-grafted MCM-48 and silica xerogel as superior sorbents for acidic gas removal from natural gas. Industrial and Engineering Chemistry Research 2002, 42:2427-2433.
23. 2 capture from dilute gases as a component of modern global carbon management. Annual Review of Chemical and Biomolecular Engineering 2011, 2:31-52.
24. 2 capture from the air. Climatic Change 2006, 74:17-45.
25. 2 from air. Industrial and Engineering Chemistry Research 2012, 51:8631-8645.
26. 2 capture. Catalysis Surveys from Asia 2007, 11:171-185.
27. 2 absorption and regeneration of alkali metal-based solid sorbents. Catalysis Today 2006, 111:385-390.
28. 2 sorption and regeneration at temperatures below 200°C. Fuel 2011, 90:1465-1470.
29. Lidin R.A., Andreeva L.L., Molochko V.A. Constants of Inorganic Substances 1995, Begell House, New York.
30. 2 capture technologies. Energy Environmental Science 2010, 3:1645-1669.
31. 2 capture from atmospheric air - thermodynamic analysis. International Journal of Greenhouse Gas Control 2009, 3:376-384.
32. 2(dobpdc). Journal of the American Chemical Society 2012, 134:7056-7065.
33. 3 cycle using concentrated solar power - thermodynamic analysis. Energy 2006, 31:1715-1725.
34. 2 from air - thermodynamic and thermogravimetric analyses. Chemical Engineering Journal 2008, 140:62-70.
35. 3-in-porous matrix: influence of the matrix nature. Reaction Kinetics and Catalysis Letters 2000, 71:355-362.
36. Okunev, Sharonov A.G., Gubar V.E., Danilova A.V., Paukshtis I.G., Moroz E.A., Kriger E.M., Malakhov T.A., Aristov V.V., Yu I. Sorption of carbon dioxide by the composite sorbent of potassium carbonate in porous matrix. Russian Chemical Bulletin 2000, 82:363-369.
37. Okunev A.G., Sharonov V.E., Gubar A.V., Danilova I.G., Paukshtis E.A., Moroz E.M., Kriger T.A., Malakhov V.V., Aristov Y.I. Sorption of carbon dioxide by the composite sorbent "potassium carbonate in porous matrix". Russian Chemical Bulletin 2003, 52:359-363.
38. Pielke R.A. An idealized assessment of the economics of air capture of carbon dioxide in mitigation policy. Environment Science and Policy 2009, 12:216-225.
39. Polak, R.B., Steinberg, M., 2012. Carbon dioxide removal systems. US Patent 2012/0003722 A1.
40. Rostrup-Nielsen J.R., Pedersen K., Sehested J. High temperature methanation: sintering and structure sensitivity. Applied Catalysis A: General 2007, 330:134-138.
41. 2 with amine-functionalized silica. Industrial and Engineering Chemistry Research 2008, 47:9406-9412.
42. 2 from humid gases on potassium carbonate supported by porous matrix. Russian Journal of Applied Chemistry 2001, 74:409-413.
43. 3. Russian Chemical Bulletin 2001, 82:363-369.
44. 3". Reaction Kinetics and Catalysis Letters 2004, 82:363-370.
45. 2 with chemicals. A Technology Assessment for the APS Panel on Public Affairs 2011, (http://www.aps.org/policy/reports/assessments/index.cfm).
46. Stolaroff J.K., Keith D.W., Lowry G.V. Carbon dioxide capture from atmospheric air using sodium hydroxide spray. Environmental Science and Technology 2008, 42:2728-2735.
47. 2 capture facility. Energy and Fuels 2003, 17:1034-1039.
48. 2 capture from the atmosphere and simultaneous concentration using zeolites and amine-grafted SBA-15. Environmental Science and Technology 2011, 45:10257-10264.
49. 2 recovery from the atmosphere and water electrolysis: feasibility of a new process for hydrogen storage. International Journal of Hydrogen Energy 1995, 20:653-663.
50. 2 capture by solid adsorbents and their applications: current status and new trends. Energy Environmental Science 2011, 4:42-55.
51. 2 capture and utilization. ChemSusChem 2008, 1:893-899.
52. 2 capturer derived from as-synthesized MCM-41 modified with amine. Chemistry-A European Journal 2008, 14:3442-3451.
53. 2 capture from ambient air. Environmental Science and Technology 2007, 41:7558-7563.
54. 2 absorption using dry potassium-based sorbents with different supports. Energy and Fuels 2009, 23:4683-4687.
55. 2 capture. Energy and Fuels 2009, 23:1766-1769.
56. 2 capture in a fluidized-bed reactor. Energy and Fuels 2010, 24:1009-1012.
57. 3. Energy and Fuels 2012, 26:1401-1405.
58. 3. Energy and Fuels 2012, 26:1406-1411.
59. 3 in a bubbling fluidized-bed reactor. Energy and Fuels 2012, 26:3062-3068.