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2014 | OriginalPaper | Buchkapitel

7. Carbon Capture and Storage: In the Quest for Clean Fossil Energy

verfasst von : Nazim Muradov

Erschienen in: Liberating Energy from Carbon: Introduction to Decarbonization

Verlag: Springer New York

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Abstract

The main objective of carbon capture and storage (CCS) is to prevent CO₂ from entering the atmosphere by capturing CO₂ from large industrial sources and securely storing it in various carbon sinks. CCS is considered a critical component of the portfolio of carbon mitigation solutions, because global economy heavily relies and will continue to rely on fossil fuels in the foreseeable future. Currently, there are close to 300 active and planned CCS-related projects around the world—an indication of a growing commitment to this technological option. However, despite significant progress in CCS technology, the pace of CCS commercial deployment is rather slow. The major challenges facing the large-scale CCS deployment worldwide relate to a very high financial barrier and limited economic stimuli or regulatory drivers to encourage investments in the technology. This chapter highlights scientific and engineering progress in all three major stages of the CCS chain, CO₂ capture, transport, and storage, and the current status of existing and planned commercial CCS projects. Technological, economic, environmental, and societal aspects of the large-scale CCS deployment and its prospects as a major carbon abatement policy are analyzed in this chapter.

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Vorheriges Kapitel Carbon-Neutral Energy Sources

Nächstes Kapitel Transition to Low- and Zero-Carbon Energy and Fuels

New Entrants Reserve (NER300) is one of the world’s largest funding programs for innovative low-carbon energy demonstration projects as part of the EU Emission Trading System.

Global CCS Institute (2009) Strategic analysis of the global status of carbon capture and storage. Final report. http://www/globalccsinstitute.com/downloads/reports/2009/worley/foundation-report-1-rev0.pdf. Accessed 3 Aug 2010

Outcomes from UNFCCC conference in Doha (2013) Carbon Capture J 32

Global CCS Institute (2013) Status of carbon capture and storage update. Carbon Capture J 32

International Energy Agency (2012) Energy technology perspectives. Pathways to a clean energy system. IEA/OECD, Paris, France

Jacobson M (2009) Review of solutions to global warming, air pollution and energy security. Energy Environ Sci 2:148–173CrossRef

Quaile I, Gräßler B (2011) Deutsche Welle. http//www.dw-world.de/dw/article/0,15402725,00.html. Accessed 10 Dec 2011

Thompson J (2012) The dash for gas—no climate cure without CCS. Global CCS Institute. http://www.globalccsinstitute.com/insights/authors/jyhompson/2012/10/22/das-gas-%E2%80%93-no-climate-cure-without-ccs. Accessed 23 Oct 2012

International Energy Agency (2013) Tracking clean energy progress. IEA input to the Clean Energy Ministerial, IEA, Paris. www.iea.org/publications/TCEP_web.pdf. Accessed 10 Sep 2013

IEA calls for more funds to support carbon capture technology (2012) Bloomberg, June 11, 2012. http://www.eco-business.com/news/iea-calls-for-more-funds-to-support-carbon-capture-technology. Accessed 10 Jul 2012

10.

Mankins J (1995) Technology readiness levels, NASA Office of Space Access and Technology, Advanced Concepts Office. http://www.hq.nasa.gov/office/codeq/trl/trl.pdf. Accessed 20 Oct 2012

11.

WorleyParsons, Schlumberger, Baker & McKenzie and EPRI (2009) Strategic analysis of the global status of carbon capture and storage. http://cdn.globalccsinstitute.com/sites/default/files/publications/5751/report-5-synthesis-report.pdf. Accessed 10 Jul 2012

12.

Global CCS Institute (2011) The global status of CCS: 2011 update. Canberra, Australia, ISBN 978-0-9871863-0-0

13.

He H, Li W, Zhong M et al (2013) Reversible CO₂ capture with porous polymers using the humidity swing. Energy Environ Sci 6:488–493

14.

US Department of Energy (2007) Carbon sequestration technology. Roadmap, Washington, DC

15.

Rochelle G (2009) Amine scrubbing for CO₂ capture. Science 325:1652–1654CrossRef

16.

Ciferno J, Fout T, Jones A et al. (2009) Capturing carbon from existing coal-fired power plants. Chem Eng Progress:33–47

17.

US Department of Energy (2003) Carbon sequestration. Technology roadmap and program plan. US DOE Office of Fossil Energy, National Energy Technology Laboratory, Morgantown, West Virginia

18.

Millward A, Yaghi O (2005) Metal-organic frameworks with exceptionally high capacity for storage of carbon dioxide at room temperature. J Am Chem Soc 127:17998–17999CrossRef

19.

Carbon sponge could soak up coal emissions (2013) Carbon Capture J 32:21

20.

CO₂ capture in vehicles and home heating systems (2012) Carbon Capture J. http://www.carboncapturejournal.com/displaynews.php?NewsID=1043&PHPSESSID=18dkjsha7qaa6s815mlrslvtq4. Accessed 30 Nov 2012

21.

Lin H, Merkel T, Baker R (2007) The membrane solution to global warming. 6th annual conference on carbon capture and sequestration, Pittsburgh, PA

22.

Du N, Park H, Robertson G et al (2011) Polymer nanosieve membranes for CO₂-capture applications. Nat Mater 10:372–375CrossRef

23.

US Department of Energy (2006) Carbon Sequestration Technology Roadmap. Office of Fossil Energy, NETL, Morgantown, West Virginia

24.

US Department of Energy (2005) Roadmap for the hydrogen economy. Workshop on manufacturing R&D for the hydrogen economy, Washington, DC

25.

Intergovernmental Panel on Climate Change (2005) 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 H et al (eds). Cambridge University Press, Cambridge

26.

International Energy Agency (1996) Decarbonization of fossil fuels, IEA Report PH2/2, March 1996, IEA Greenhouse Gas R&D Programme, Cheltenham

27.

Muradov N (2009) Production of hydrogen from hydrocarbons. In: Gupta R (ed) Hydrogen fuel. Production, transport and storage. CRC Press, Boca Raton

28.

Wilson E, Gerard D (2007) Carbon capture and sequestration. Integrating technology, monitoring and regulation. Blackwell Publishing, Ames, IA

29.

Ball M, Weindorf W, Bunger U (2009) Hydrogen production. In: Ball M, Wietschel M (eds) Hydrogen economy. Opportunities and challenges. Cambridge University Press, Cambridge, UKCrossRef

30.

Lin S (2009) Hydrogen production from coal. In: Gupta R (ed) Hydrogen fuel. Production, transport and storage. CRC Press, Boca Raton

31.

US Department of Energy (2010) Worldwide gasification database online, NETL. Pittsburgh, PA. www.netl.doe.gov/coalpower/gasification/models/dtbs.pdf. Accessed 12 Aug 2012

32.

US Department of Energy (2012) Turbine program. Enabling near-zero emission coal-based power generation, Office of fossil energy, NETL. http://www.netl.doe.gov/technologies/coalpower/turbines/refshelf/brochures/brochure%209-19-05.pdf. Accessed 20 Aug 2012

33.

Fukuizumi Y, Shiozaki S, Muyama A et al (2004) Large frame gas turbines. The leading technology of power generation industries, Mitsubishi Heavy Industries, Technical Review, vol.41, No. 5, 1–5 Oct 2004. http://www.mhi.co.jp/technology/review/pdf/e415/e415254.pdf. Accessed 20 Aug 2012

34.

Bancalari E, Chan P, Diakunchak I (2007) Advanced hydrogen turbine development, Siemens, DOE contract No. DE-FC26-05NT42644. http://www.energy.siemens.com/co/pool/hq/energy-topics/pdfs/en/igcc/6_advanced_hydrogen.pdf. Accessed 20 Aug 2012

35.

Mak S (2003). Where are construction materials headed. http://www.dbce.csiro.au/inno-web/0899/sustainable.htm. Accessed 20 Jan 2008

36.

Stern M, Simeon F, Herzog H et al (2013) Post-combustion carbon-dioxide capture using electrochemically mediated amine regeneration. Energy Environ Sci. doi:10.1039/c3ee41165f

37.

CO₂ Technology Centre Mongstad (2012) Technologies. http://www.tcmda.com/en/technology/. Accessed 15 Jul 2012

38.

Brennecke J, Gurkan B (2010) Ionic liquids for CO₂ capture and emission reduction. J Phys Chem Lett 2010:3459–3464CrossRef

39.

Ritter S (2010) Carbon dioxide’s unsettled future. Chem Eng News 88:36–37

40.

Trachtenberg M, Cowan R, Smith D et al (2008). Membrane-based enzyme-facilitated efficient CO₂ capture. Proceedings of the 9th international conference on Greenhouse Gas Control Technologies, Washington, DC, p 353–360

41.

Tuinier M, Hamers H, van Sing Annaland M (2011) Techno-economic evaluation of cryogenic CO₂ capture—a comparison with absorption and membrane technology. Int J Greenhouse Gas Control 5:1559–1565CrossRef

42.

US Department of Energy (2012) Cryogenic carbon capture. ARPA-E project DE-AR0000101. NETL. http://www.netl.doe.gov/publications/proceedings/12/co2capture/presentations/5-Posters/D%20Frankman-SES-Cryogenic%20Carbon%20Capture.pdf. Accessed 20 Jan 2013

43.

Harris S (2013) Material could enable cheaper method of carbon capture. The Engineer, June, 2013. http://www.theengineer.co.uk/sectors/energy-and-environment/news/material-could-enable-cheaper-method-of-carbon-capture/1012898.article. Accessed 14 Sep 2013

44.

Zafar Q, Mattisson T, Gevert B (2005) Integrated hydrogen and power production with CO₂ capture using chemical-looping reforming-redox reactivity of particles of CuO, Mn₂O₃, NiO and Fe₂O₃ using SiO₂ as a support. Ind Eng Chem Res 44:3485–3496CrossRef

45.

McGlashan N (2008) Chemical looping combustion—a thermodynamic study. J Mech Eng Sci 222:1005–1019CrossRef

46.

Brandvoll O, Bolland O (2004) Inherent CO₂ capture using chemical looping combustion in a natural gas fired power cycle. ASME J Eng Gas Turb Power 126:316–321. ASME Paper GT-2002–30129

47.

Naqvi R, Bolland O (2007) Multi-stage chemical looping combustion (CLC) for combined cycles with CO₂ capture. Int J Greenhouse Gas Control 1:19–30CrossRef

48.

Habib M, Badr H, Ahmed S et al (2011) A review of recent developments in carbon capture utilizing oxy-fuel combustion in conventional and ion transport membrane systems. Int J Energy Res 35:741–764CrossRef

49.

Mattisson T (2007) Chemical-looping combustion using gaseous and solid fuels. 2nd Workshop on international oxy-combustion research network, 25–26 Jan 2007, Windsor, CT

50.

Tan X, Wang Z, Lin H et al (2008) Enhancement of oxygen permeation through La_0.6Sr_0.4Co0.2Fe_0.8O_3-δ hollow fibre membranes by surface modifications. J Membr Sci 324:128–135CrossRef

51.

Park J, Do Par S (2007) Oxygen permeability and structural stability of La_0.6Sr_0.4Co_0.2Fe_0.8O_3-δ membrane. Korean J Chem Eng 24:897–905CrossRef

52.

Esquiro A, Brandon N, Kilner J et al (2004) Electrochemical characterization of La_0.6Sr_0.4Co0.2Fe_0.8O_3-δ cathodes for intermediate temperature SOFC. J Electrochem Soc 151:A1847–A1855CrossRef

53.

Wang H, Cong Y, Yang W (2002) Oxygen permeation study in a tubular Ba_0.5Sr_0.5Co_0.8Fe_0.2O_3-δ oxygen permeable membrane. J Membr Sci 210:259–271CrossRef

54.

Zhu X, Cong Y, Yang W (2006) Effects of synthesis methods on oxygen permeability of BaCe_0.15Fe_0.85O_3-δ ceramic membranes. J Membr Sci 283:158–163CrossRef

55.

Arnold M, Wang H, Feldhoff A (2007) Influence of CO₂ on the oxygen permeation performance and microstructure of perovskite type (Ba_0.5Sr_0.5) (Co0_.8Fe_0.2)O_3-δ membranes. J Membr Sci 293:44–52CrossRef

56.

Yan A, Liu B, Dong Y et al (2008) A temperature programmed desorption investigation on the interaction of Ba_0.5Sr_0.5Co_0.8Fe_0.2O_3-δ perovskite oxides with CO2 in the absence and presence of H₂O and O₂. Appl Catal B 80:24–31CrossRef

57.

Benson S, Waller D, Kilner J (1999) Degradation of La_0.6Sr_0.4Co_0.2Fe_0.8O_3-δ in carbon dioxide and water atmospheres. J Electrochem Soc 146:1305–1309CrossRef

58.

Efimov K, Arnold M, Martynczuk J et al (2009) Crystalline intermediate phases in the sol-gel-based synthesis of La₂NiO_4+δ. J Am Ceram Soc 92:876–880CrossRef

59.

Kvamsdal H, Jordal K, Bolland O (2007) A quantitative comparison of gas turbine cycles with CO₂ capture. Energy 32:10–24CrossRef

60.

Sandquist S, Julsrud S, Vigenand B et al (2007) Development and testing of AZEP reactor components. Int J Greenhouse Gas Control 2007:180–187

61.

Sundquist S, Griffin T, Thornhaug N (2011) AZEP-development of an integrated air separation membrane-gas turbine. 2nd Nordic minisymposium on carbon dioxide capture and storage. Alstom Power, Gothenburg, Sweden, October 2011

62.

US Department of Energy (2012) Praxair: IEP—oxy-combustion CO₂ emissions control, OTM-based oxycombustion for CO₂ recovery, Project No.: FC26-01NT41147 & FC26-07NT43088 http://www.netl.doe.gov/technologies/coalpower/ewr/co2/oxy-combustion/otm-based.html. Accessed 14 Jan 2013

63.

Global CCS Institute (2009) Strategic analysis of the global status of carbon capture and storage. Report 5: synthesis report. http://cdn.globalccsinstitute.com/sites/default/files/publications/5751/report-5-synthesis-report.pdf. Accessed 12 Feb 2012

64.

Seiersten M (2001) Material selection for separation, transportation and disposal of CO₂. Proceedings of the Corrosion National Association. Corrosion Engineers, paper 1042

65.

Guijt W (2004) Analyses of incident data show US, European pipelines becoming safer. Oil Gas J 102:68–73

66.

McKinsey and Co (2008) Carbon capture & storage: assessing the economics. McKinsey and Company. http://assets.wwf.ch/downloads/mckinsey2008.pdf. Accessed 12 Feb 2012

67.

International Energy Agency (2004) Ship transport of CO₂. IEA Greenhouse Gas R&D Programme, Report PH4/30, Cheltenham

68.

Marchetti C (1977) On geoenginering and the CO₂ problem. Clim Chang 1:59–68CrossRef

69.

Kaarstad O (1992) Emission-free fossil energy from Norway. Energy Convers Manag 33:781–786CrossRef

70.

Koide H, Tazaki Y, Noguchi Y et al (1992) Subterranean containment and long-term storage of carbon dioxide in unused aquifers and depleted natural gas reservoirs. Energy Convers Manag 33:619–626CrossRef

71.

Bachu S (2003) Screening and ranking of sedimentary basins for sequestration of CO₂ in geological media. Environ Geol 44:277–289CrossRef

72.

Pershad H (2012) CCS for gas—results of Element Energy study. Carbon Capture J 13–15

73.

Doyle A (2013) Norwegian sea can hold 100 years of Norway’s CO₂. Scientific American, 25 Jan 2013. http://www.scientificamercian.com/article.cfm?id=Norwegian-sea-can-hold100-years-of-Norways-CO₂ . Accessed 10 Jul 2013

74.

Johnson J (2009) Huge CO₂ storage potential in China. Chem Eng News 87:27CrossRef

75.

Bachu S, Gunter W, Perkins E (1994) Aquifer disposal of CO₂: hydrodynamic and mineral trapping. Energy Convers Manag 35:269–279CrossRef

76.

Perkins E, Czernichowski-Lauriol I, Azaroual M et al (2004) Long term predictions of CO₂ storage by mineral and solubility trapping in the Weybourn Midale Reservoir. Proceedings of the 7th international conference on Greenhouse Gas Control Technologies, vol II, Vancouver, Canada, p. 2093–2096

77.

Casey A (2008) Carbon cemetery. Canadian Geographic Magazine, January/February:61

78.

US Department of Energy (2012) NETL. Enhanced oil recovery information. www.netl.doe.gov/KMD/cds/disk44/F-General/EOR_Brochure.pdf. Accessed 20 Dec 2012

79.

Holt T, Jensen J, Lindeberg E (1995) Underground of storage of CO₂ in aquifers and oil reservoirs. Energy Convers Manag 36:535–538CrossRef

80.

Ferguson R, Nichols C, van Leeuwen T et al (2009) Storing CO₂ with enhanced oil recovery. Greenhouse Gas Technologies-9, Elsevier Science Direct, Energy Procedia 1: 1989–1996

81.

Baviere M (2007) Basic concepts in enhanced oil recovery processes. Elsevier Applied Science, London, ISBN 1-85166-617-6

82.

Stevens S, Kuuskraa J, Schraufnagel R (1996) Technology spurs growth of US coal bed methane. Oil Gas J 94:56–63

83.

Key R, Kozyr A, Sabine C et al (2004) A global ocean carbon climatology: results from GLODAP. Global Biochem Cy 18:GB4031

84.

Giles J (2002) Norway sinks ocean carbon study. Nature 419:6CrossRef

85.

Brewer P, Peltzer E, Walz P et al (2005) Deep ocean experiments with fossil fuel carbon dioxide: creation and sensing of a controlled plume at 4 km depth. J Mar Res 63:9–33CrossRef

86.

Intergovernmental Panel on Climate Change (2007) IPCC 4th assessment report, climate change 2007. The physical science basis. Cambridge University Press, Cambridge

87.

O’Connor W, Dahlin D, Rush G et al (2005) Aqueous mineral carbonation, Final Report, DOE/ARC-TR-04-002, 15 March 2005

88.

US Department of Energy (1999) Carbon sequestration. State of the Science. US DOE, Office of Science, Office of Fossil Fuels, Working paper on carbon sequestration science and technology. Washington, DC

89.

Andersen R (2005) Algal culturing techniques. Elsevier, Amsterdam, pp 189–203

90.

Nakamura T (2004) Recovery and sequestration of CO₂ from stationary combustion systems by photosynthesis of microalgae, Technical report to DOE, NETL, No. PSI-1356, December 2004

91.

National Laboratory Directors (1997) Technology opportunities to reduce US greenhouse gas emissions. Oak Ridge National Laboratory, Tennessee

92.

International Energy Agency (2004) Improvements in power generation with post- combustion capture of CO₂, IEA report PH4/33. IEA Greenhouse gas R&D Programme, Cheltenham, UK

93.

Davison J (2005) CO₂ capture and storage and the IEA Greenhouse Gas Programme. Workshop on CO₂ issues, Miffelfart, Denmark, May 2005, IEA Greenhouse Gas Programme, Cheltenham

94.

Power from gas + CCS at 54% efficiency? (2013) Carbon Capture J 14–15

95.

Tola V, Pettinau A (2014) Power generation plants with carbon capture and storage: a techno-economic comparison between coal combustion and gasification technologies. Appl Energy 113:1461–1474CrossRef

96.

Global CCS Institute (2011) Economic assessment of carbon capture and storage technologies. 2011 update. WorleyParsons, Schlumberger. Canberra, Australia. http://cdn.globalccsinstitute.com/sites/default/files/publications/12786/economic-assessment-carbon-capture-and-storage-technologies-2011-update.pdf. Accessed 12 May 2012

97.

Thayer A (2009) Chemicals to help coal come clean. Chem Eng News 87:18–20CrossRef

98.

McCoy S, Rubin E (2008) An engineering economic model of pipeline transport of CO2 with application to carbon capture and storage. Int J Greenhouse Gas Control 2:219–229CrossRef

99.

National Energy Technology Laboratory (2012) Carbon storage. Geologic storage focus. http://www.netl.doe.gov/technologies/carbon_seq/corerd/storage.html. Accessed 12 Oct 2012

100.

Bock B, Rhudy R, Herzog H et al. (2003) Economic evaluation of CO₂ storage and sink options. DOE research report, DE-FC26–00NT40937, Washington, DC

101.

Hendriks C, Graus W, van Bergen F (2002) Global carbon dioxide storage potential and costs. Report Ecofys & The Netherlands Institute of Applied Geoscience TNO, Ecofys Report EEP, p 63

102.

Roche P (2012) Widespread CCS unlikely unless CO₂ capture cost reduced, conference hears. Daily Oil Bull. http://airwaterland.ca/issues/printer.asp?article=dob%2F121017%2Fdob2012_oh0032.html. Accessed 23 Oct 2012

103.

Akai M, Nishio N, Iijima M et al. (2004) Performance and economic evaluation of CO2 capture and sequestration technologies. Proceedings of the 7th international conference on Greenhouse Gas Control Technologies, Elsevier, Oxford

104.

World Energy Investment Outlook (2003) OECD/IEA, 75775 Paris. ISBN: 92-64-01906-5

105.

Edmonds J, Feund P, Dooley J (2000) The role of carbon management technologies in addressing atmospheric stabilization of greenhouse gases. Proceedings of the 5th international conference on Greenhouse Gas Control Technologies. Sponsored by the IEA Greenhouse gas R&D Programme, Cairns

106.

Kithil P (2007) A policy option to provide sufficient funding for massive-scale sequestration of CO₂, the Smithsonian/NASA Astrophysics Data System. http://adsabs.harvard.edu/abs/2007AGUFM.U43C1410K. Accessed 14 Jan 2010

107.

International Energy Agency (2013) Technology roadmap. Carbon capture and storage, 2013 edn. http://www.iea.org/publications/freepublications/publication/TechnologyRoadmapCarbonCaptureandStorage.pdf. Accessed 5 Sep 2013

108.

Status of CCS project database (2012) Carbon Capture J:24–25

109.

China becoming a global leader in CCS projects (2013) Carbon Capture J. http://www.carboncapturejournal.com/displaynes.php?NewsID=1126&PHPSESSID=18dkjsha7qaa6s815mlrslvtq4. Accessed 15 Jun 2013

110.

Global CCS Institute (2011) The global status of CCS: 2010, Canberra, Australia, ISSN 1838-9481. http://www.globalccsinsitute.com/resources/publications/global-status-ccs-2010. Accessed 25 May 2011

111.

Global CCS Institute status of CCS update (2013) Carbon Capture J. http://www.carboncapturejournal.com/. Accessed 20 Jul 2013

112.

Michael K, Allison G, Golab A (2009) CO₂ storage in saline aquifers II- experience from existing storage operations. Proceedings of the greenhouse gas technologies-9 conference. Energy procedia, vol 1, p. 1973–1980

113.

Statoil (2009) Development solution. http://www.statoil.com/statoilcom/snohvit/svg02699.nsf?opendatabase&lang=en. Accessed 25 Sep 2009

114.

Petroleum Technology Research Center (2007) Weyburn-Midale CO₂ monitoring & storage project. Proceedings of the 6th annual conference on carbon capture & sequestration. Pittsburg, PA, 7 May 2007

115.

Wackowski R (2007) Rangely Weber Sand unit CO₂ flooding case study, a long history of CO₂ injection. Proceedings of the CO₂ capture and storage conference, The Canadian Institute, Calgary, AB, 7 Feb 2007

116.

Beckwith R (2011) Carbon capture and storage: a mixed review. JPT:42–45

117.

Reeves S, Davis D, Oudinot A (2004) A technical and economic sensitivity study of enhanced coalbed methane recovery and carbon sequestration in coal. DOE topical report, Washington, DC

118.

Flett M, Beacher G, Brantjes J et al (2008) Gordon Project: subsurface evaluation of carbon dioxide disposal under Barrow Island. Society of Petroleum Engineering, SPE 116372

119.

Johnson J (2012) Stumbling on the path to “clean coal”. Chem Eng News 90:37–39

120.

Reisch M (2011) Air products inks carbon-capture deals. Chem Eng News 89:24

121.

International Energy Agency (2012) Carbon capture and storage in industrial applications. doi:10.1787/9789264130661-en. http://www.oecd-ilibrary.org/energy/carbon-capture-and-storage-in-industrial-applications_9789264130661-en. Accessed 18 Dec 2012

122.

Worrell E, Price L, Martin N et al (2001) Carbon dioxide emissions from the global cement industry. Annu Rev Energy Environ 26:303–329CrossRef

123.

Van Puyvelde D (2013) An update on CO₂ capture from cement production. Global CCS Institute. http://www.globalccsinstitute.com/insights/authors/dennisvanpuyvelde/2013/02/20/update-co2-capture-cement-production. Accessed 20 Aug 2013

124.

European Cement Research Academy (2012) Carbon capture technology ECRA’s approach towards CCS. ECRA Commun Bull. http://www.ecra-online.org/fileadmin/redaktion/files/pdf/ECRA_CCS_Communication_Bulletin_29.08.12neu.pdf. Accessed 20 Feb 2013

125.

Skyonic (2013) Profitable, scalable, solid carbon capture. www.skyonic.com. Accessed 12 Mar 2013

126.

Velzy C, Grillo L (2007) Waste-to-energy combustion. In: Kreith F, Goswami Y (eds) Handbook of energy efficiency and renewable energy. CRC Press, Boca Raton, USA

127.

Johnson J (2011) EPA proposes easing CO₂ controls. Chem Eng News 89:25

128.

Johnson J (2009) Water and CO₂ shouldn’t mix. Chem Eng News 87:32

129.

Carapeza M, Badalamenti B, Cavarra L et al (2003) Gas hazard assessment in a densely inhabited area of Colli Albani Volcano. J Volcanol Geothermal Res 123:81–94CrossRef

130.

Zoback M, Gorelick S (2012) Earthquake triggering and large-scale geologic storage of carbon dioxide. Proc Natl Acad Sci U S A. http://www.pnas.org/cgi/doi/10.1073/pnas.1202473109. Accessed 10 Mar 2013

131.

CCS may have potential to induce seismic events (2012) Carbon Capture J. http://www.carboncapturejournal.com/displaynews.php?NewsID=959&PHPSESSID=9sd636g2pot2m8t5t1e8n2gsc3. Accessed 20 Mar 2012

132.

Stone E, Lowe J, Shine K (2009) The impact of carbon capture and storage on climate. Energy Environ Sci 2:81–91CrossRef

133.

Zhou W, Stenhouse M, Arthur R et al (2005) The IEA Weybourn CO₂ monitoring and storage project—modeling of long-term migration of CO₂ from Weybourn. Proceedings of the 7th international conference on Greenhouse Gas Control Technologies, vol 1, Vancouver, Canada, p 721–730, Elsevier, UK

134.

National Institute for Occupational Safety and Health (1997). Washington, DC

135.

Palmgren C, Granger Morgan M, Bruine de Bruin W et al (2004) Initial public perception of deep geological and oceanic disposal of CO₂. Environ Sci Technol 38:6441–6450CrossRef

136.

Itoaka K, Saito A, Akai M (2004) Public acceptance of CO₂ capture and storage technology: a survey of public opinion to explore influential factors. Proceedings of the 7th international conference on Greenhouse Gas Control Technologies, 2004, Vancouver, Canada

137.

Johnson J (2010) Gasification plant funds shifted by DOE. Chem Eng News 88:34

138.

Shell Barendrecht project cancelled (2010) Carbon Capture J. http://www.carboncapturejournal.com/displaynews.php?NewsID=676. Accessed 20 Jul 2012

139.

CCS awareness higher in Saskatchewan than Europe Projects (2011) Carbon Capture J. http://www.carboncapturejournal.com/displaynews.php?NewsID=873. Accessed 15 Jan 2012

140.

International Energy Agency (2011) World Energy Outlook. Are we entering a golden age of gas? IEA, Paris, France

141.

Global CCS Institute (2012) Global status of large scale integrated projects. 2012 update. http://cdn.globalccsinstitute.com/sites/default/files/publications/41146/globalstatusoflargescaleintegratedprojectsjune2012update.pdf. Accessed 20 Jan 2013

142.

Johnson J (2013) EPA tries capping power plant carbon. Chem Eng News 91:42–43

143.

Gurria A (2013) Carbon price vital to address climate change. Responding to climate change (RTCC), 9 Oct 2013. http://www.rtcc.org/2013/10/09/oecd-chief-carbon-price-vital-to-address-climate-change/. Accessed 14 Oct 2013

144.

Wilcox J (2012) Carbon capture. Springer, New York, p 321CrossRef

145.

Cook P (2012) Clean energy, climate and carbon. CSIRO Publishing, Collingwood, p 214

146.

Mills R (2011) Capturing carbon. The new weapon in the war against climate change. Columbia University Press, New York, p 465

147.

Jackson F (2009) Conquering carbon. Carbon emissions, carbon markets and the consumers. New Holland, London, UK, p 256

Titel: Carbon Capture and Storage: In the Quest for Clean Fossil Energy
verfasst von: Nazim Muradov
Verlag: Springer New York
Buch: Liberating Energy from Carbon: Introduction to Decarbonization
Print ISBN: 978-1-4939-0544-7

Electronic ISBN: 978-1-4939-0545-4

Copyright-Jahr: 2014
DOI: https://doi.org/10.1007/978-1-4939-0545-4_7

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