Carbon dioxide capture and storage by pH swing aqueous mineralisation using a mixture of ammonium salts and antigorite source

Fuel

Volumn 114, Issue , 2013, Pages 153-161

  Sanna, Aimaro ^a,b   Dri, Marco ^a,b   Maroto Valer, Mercedes ^a  

^a HERIOT WATT UNIVERSITY   (United Kingdom)

^b UNIVERSITY OF NOTTINGHAM   (United Kingdom)

Author keywords

Ammonium salts; CCS; Dissolution; Mineral carbonation; Serpentine

Indexed keywords

CALCIUM CARBONATE; CARBON DIOXIDE; CARBONATION; DISSOLUTION; GLOBAL WARMING; KAOLINITE; MAGNESIUM; MINERALOGY; MINERALS; MIXTURES; SALTS; SERPENTINE; SILICATE MINERALS;

AMMONIUM SALT; CAPTURE PROCESS; CARBON DIOXIDE CAPTURE AND STORAGE; CARBON DIOXIDE EMISSIONS; HYDROMAGNESITE; MINERAL CARBONATION; MINERALISATION; SOLID MINERALS;

CARBON CAPTURE;

EID: 84885183639     PISSN: 00162361     EISSN: None     Source Type: Journal    
DOI: 10.1016/j.fuel.2012.08.014     Document Type: Article

References (39)

1. IPCC, IPCC special report on carbon dioxide capture and storage. Prepared by working group III of the intergovernmental panel on climate change. In: Metz B, Davidson O, de Coninck HC, Loos M, Meyer LA, editors. Cambridge (United Kingdom)/New York (NY, USA): Cambridge University Press; 2005. p. 442.
2. ZEP, CO2 capture costs, report. European technology platform for zero emission fossil fuel power plants; 2011. .
3. IEA. Energy technology perspectives: BLUE map scenario OECD/IEA; 2011.
4. Sanna A, Hall MR, Maroto-Valer M. Post-processing pathways in carbon capture and storage by mineral carbonation (CCSM) towards the introduction of carbon neutral materials. Energy Environ Sci 2012;5:7781-96.
5. Sanna A et al. Waste materials for carbon capture and storage by mineralisation (CCSM) - a UK perspective. Appl Energy; 2012. http:// dx.doi.org/10.1016/j.apenergy.2012.06.049.
6. Krevor SCM, Lackner KS. Enhancing serpentine dissolution kinetics for mineral carbon dioxide sequestration. Int J Greenhouse Gas Control 2011. http:// dx.doi.org/10.1016/j.ijggc.2011.01.006.
7. Gerdemann SJ, O'Connor WK, Dahlin DC, Penner LR, Rush H. Ex situ aqueous mineral carbonation. Environ Sci Technol 2007;41:2587-93. (Pubitemid 46595232)
8. Kelemen PB, Matter J. In situ carbonation of peridotite for CO2 storage. Proc Natl Acad Sci USA 2008;105:17295-300.
9. Wang X, Maroto-Valer MM. Dissolution of serpentine using recyclable ammonium salts for CO2 mineral carbonation. Fuel 2011;90:1229-37.
10. Hunwick R. System apparatus and method for carbon dioxide sequestration. Patent WO2008/101293; 2008.
11. Wang X, Mercedes Maroto-Valer M. Integration of CO2 capture and mineral carbonation by using recyclable ammonium salts. Chem Sustain Chem 2011;4(9):1291-300.
12. Reddy KJ, John S, Weber H, Argyle MD, Bhattacharyya P, Taylor DT et al. Simultaneous capture and mineralization of anthropogenic carbon dioxide (CO2): pilot scale studies. GHGT-10, Amsterdam; 2010.
13. Zevenhoven R, Fagerlund J, Songok JK. CO2 mineral sequestration: developments toward large-scale application. Greenhouse Gas Sci Technol 2011;1:48-57.
14. Wang X, Maroto-Valer M. Integration of CO2 capture and storage based on pH- swing mineral carbonation using recyclable ammonium salts. Energy Procedia 2011;4:4930-6.
15. Darde V, Thomsen K, van Well WJM, Stenby EH. Aqueous ammonia process for CO2 capture. Earth Environ Sci 2009;6:172017.
16. Rochelle GT. Amine scrubbing for CO2 capture. Science 2009;325(5948): 1652-4.
17. Yeh JT, Resnik KP, Rygle K, Pennline HW. Semi-batch absorption and regeneration studies for CO2 capture by aqueous ammonia. Fuel Process Technol 2005;86:1533-46.
18. Zhuang Q, Pomalis R, Zheng L, Clements B. Ammonia-based carbon dioxide capture technology: issues and solutions. Energy Procedia 2011;4:1459-70.
19. Figueroa JD, Fout T, Plasynski S, McIlvried H, Srivastava RD. Advances in CO2 capture technology-the US Department of Energy's carbon sequestration programs. Int J Greenhouse Gas Control 2008;2:9-20.
20. Versteeg P, Rubin ES. Technical and economic assessment of ammonia-based post-combustion CO2 capture. Energy Procedia 2011;4:1957-64.
21. Mani F, Peruzzini M, Stoppioni P. CO2 absorption by aqueous NH3 solutions: speciation of ammonium carbamate, bicarbonate and carbonate by a 13C NMR study. Green Chem 2006;8:995-1000. (Pubitemid 44656880)
22. Darde V, Thomsen K, van Well W, Stenby E. Chilled ammonia process for CO2 capture. Preprint - ICPWS XV Berlin, September 8-11, 2008.;
23. (b) Darde Victor, van Well Willy JM, Stenby Erling H. Kaj Thomsen. Energy Procedia 2011;4:1443-50.
24. Hollingbery LA, Hull TR. The thermal decomposition of huntite and hydromagnesite - a review. Thermochim Acta 2010;509:1-11.
25. Teir S, Revitzer H, Eloneva S, Fogelholm K-J, Zevenhoven R. Dissolution of natural serpentinite in mineral and organic acids. Int J Miner Process 2007;83:36-46. (Pubitemid 46860380)
26. Bearat H, McKelvy MJ, Chizmeshya AVG, Gormley D, Nunez R, Carpenter RW, et al. Carbon sequestration via aqueous olivine mineral carbonation: role of passivating layer formation. Environ Sci Technol 2006;40(15):4802-8. (Pubitemid 44157221)
27. Bhargava H, Sudheesh VD, Jani S, Lakshmi N, Venugopalan K. Study of dependence of magnetic properties on seeding temperature in fine particles of Cu0.25Co0.25Zn0.5Fe2O4. Bull Mater Sci 2011;34(5):1095-101.
28. Vance DB. Iron, the environmental impact of a universal element. Natl Environ J 1994;4(3):24-5.
29. Schott J, Pokrovsky OS, Oelkers EH. The link between mineral dissolution/ precipitation kinetics and solution chemistry. Rev Mineral Geochem 2009;70:207-58.
30. Zhang J, Zhang R, Geerlings H, Bi J. Mg-silicate carbonation based on an HCland NH3-recyclable process: effect of carbonation temperature. Chem Eng Technol 2012;35(3):1-8.
31. King HE, Plümper O, Putnis A. Effect of secondary phase formation on the carbonation of olivine. Environ Sci Technol 2010;44:6503-9.
32. Zhao H, Dadap N, Park A-HA. Tailored synthesis of precipitated magnesium carbonates as carbon-neutral filler materials during carbon mineral sequestration. In: 2010 ECI conference on the 13th international conference on fluidization - new paradigm in fluidization engineering; 2011. p. 109. .
33. Zhang Z, Zheng Y, Ni Y, Liu Z, Chen J, Liang X. Temperature- and pH-dependent morphology and FT-IR analysis of magnesium carbonate hydrates. J Phys Chem B 2006;110:12969-73. (Pubitemid 44115630)
34. Collett G, Crammond NJ, Swamy RN, Sharp JH. The role of carbon dioxide in the formation of thaumasite. Cem Concr Res 2004;34:1599-612.
35. Capitani G, Mellini M. The modulated crystal structure of antigorite: the m = 17 polysome. Am Mineral 2004;89:147-58. (Pubitemid 38179075)
36. Jonckbloedt RCL. Olivine dissolution in sulphuric acid at elevated temperatures - implications for the olivine process, an alternative waste acid neutralizing process. J Geochem Explor 1998;62:337-46.
37. Levenspiel O. Chemical reaction engineering. 3rd ed. New York: John Wiley & Sons; 1999. p. 665.
38. Teir S, Elenova S, Fogelholm C, Zevenhoven R. Appl Energy 2009;86:214-8.
39. Kodama S, Nishimoto T, Yamamoto N, Yogo K, Yamada K. Development of a new pH-swing CO2 mineralization process with a recyclable reaction solution. Energy 2008;33:776-84.