[1] MULDER, G. J. Le guide du brasseur ou l’art de faire la bière, traduit du hollandais et

annoté par DUBIEF L. F. Paris : s.n., 1836. 397 p.

[2] VERGNAUD, A. D. Nouveau manuel complet du brasseur ou l’art de faire toutes les

sortes de bières. Paris : Librairie Encyclopédique de RORET, 1838. 341 p.

[3] KROHNE S.A.S. (Les Ors). Les solutions KROHNE. Les ors : Krohne S.A.S., 2010. 6 p.

[4] ZINSALO J. M. Etude des chaudières à eau chaude et à vapeur d’eau: technologie,

combustibles et qualité d’eau d’alimentation, IUT-Lokossa : Rapport d’exposé, 2002. 73 p.

[5] SEYNHAEVE J.-M. Combustion and heat production equipment. s.n.

[6] R. J-M. La combustion. Support au département BTP de l’AFPA. 2006. 126 p.

[7] BURGHARDT M. D. & HARBACH J. A., Engineering thermodynamics. London : 4ème

Edition, Harper Collins College Publishers. 1993. 876 p. Douzième partie, Reactive Systems,

p 371-420.

[8] DEBUY V. et al. Ω22- Principes et techniques pour la détection des gaz – Formalisation

du savoir et des outils dans le domaine des risques majeurs (DRA-76). Paris : INERIS, 2009.

54 p. Rapport INERIS-DRA-08-86244-13727B.

[9] MITCHELL Andrew. A. Flue gas analysis. National Gaes Awards, 1965. 12 p.

[10] RIAD, Asmae. Optimisation énergétique des deux chaudières auxiliaires à la centrale

thermoélectrique de l’OCP. Mémoire Master Sciences et Techniques, Génie des Matériaux et

Procédés, Université Sidi Mohammed Ben Abdellah, 2012.

[11] American Bureau of Shipping (Ed), Heavy Fuel Oil, New York, 2001.

[12] GOUDEAU J.-C. Combustion de mélanges combustibles classiques/biomasse : étude

des modifications induites au niveau de la composition des fumées et des cendres. Poitiers :

RECORD, 2001. 64 p. Rapport 00-0219/1A.

[13] LE GLEAU F. Étude d'un dispositif de traitement de fumées issues de l’incinération de

déchets industriels spéciaux. Thèse Optique et Laser, Physicochimie, Atmosphère : Ecole des

mines de Douai et l’Univ. Lille 1, 2012. 267 p.

[14] Burkart Knospe & Lothar Wallese. Flue Gas Analysis in Industry, TESTO Inc. 2ème

édition

[15] Commission Européenne, Grandes installations de combustion, 584 p. Juillet 2006

[16] Nazmul Hassan S. M. Techno-Economic Study of CO2 Capture Process for Cement

Plants. Thèse Science Appliquée en Ingénierie Chimique : Univ. De Waterloo, 2005, 200 p.

[17] Cheng-Hsiu Yu, Chih-Hung Huang & Chung-Sung Tan, A Review of CO2 Capture by

Absorption and Adsorption. Aerosol and Air Quality Research [en ligne] 12: 745–769, 2012

[18] AMANN Jean-Marc, Etude de procédés de captage du CO2 dans les centrales

thermiques. Thèse Génie des procédés : Ecole des Mines de Paris, 2007, 189 p.

[19] DERGUAL Fatiha, Captage du CO2 par les amines demixantes. Thèse Chimie

Physique : Univ. Abou-Bekr Belkaid de Tlemcen, 2013, 162 p.

[20] Lars Erik Øi, Removal of CO2 from exhaust gas. Thèse Technologie : Collège

Universitaire de Telemark, 2010, 165 p.

[21] Howard Herzog, Jerry Meldon & Alan Hatton, Advanced Post-Combustion CO2

Capture. Clean Air Task Force, Avril 2009, 39 p.

[22] Anand B. Rao, Edward S. Rubin & Michael B. Berkenpas. An integrated modeling

framework for carbon management technologies. Univ. Pittsburgh, 2004, 184 p.

[23] Marek Ściążko. Modeling framework for carbon mitigation technologies. Disponible sur

http://www.cmu.edu/epp/iecm/documentation/tech_04.pdf

[24] Shrikar Chakravarti, Amitabh Gupta & Balazs Hunek. Advanced Technology for the

Capture of Carbon Dioxide from Flue Gases. First National Conference on Carbon

Sequestration, Washington, DC, 2001. 11 p.

[25] Anusha Kothandaraman. Carbon Dioxide Capture by Chemical Absorption: A Solvent

Comparison Study. Thèse Ingénierie Chimique : Institut de Technologie de Massachusetts,

2010. 263 p.

[26] Mohammad Rateb Musa ABU ZAHRA. Carbon Dioxide Capture from Flue Gas :

Development and Evaluation of Existing and Novel Process Concepts. Thèse Technologie :

Univ. Technologique de Delft, 2009. 142 p.

[27] Deborah Adams. Flue gas treatment for CO2 capture. IEA Clean Coal Centre, 2010. 61

p. ISBN 978-92-9029-489-4

[28] Hendy Thee et al. A. kinetic and process modeling study of CO2 capture with MEA-

promoted potassium carbonate solutions. Chemical Engineering Journal, 2012, n° 210, p.

271-279

[29] Anand B. Rao, Edward S. Rubin & Michael B. Berkenpas. A Multi-Pollutant

Framework for Evaluating CO2 Control Options for Fossil Fuel Power Plants. Univ.

Pittsburgh, 184 p.

[30] Caleb Stewart & Mir-Akbar Hessami. A study of methods of carbon dioxide capture

and sequestration––the sustainability of a photosynthetic bioreactor approach. Energy

Conversion and Management, 2005, n°46, p. 403-420

[31] Duncan Leeson et al. A Systematic Review of Current Technology and Cost for

Industrial Carbon Capture. Londres : Grantham Institute, Novembre 2004. Rapport GR7

[32] Edward S. Rubin & Anand B. Rao. A Technical, Economic and Environmental

Assessment of Amine-based CO2 Capture Technology for Power Plant Greenhouse Gas

Control. Environ. Sci. Technol. 2002, n°36, p.4467-4475.

[33] Fernando Camacho, Sebastian Sanchez & Rafael Pacheco. Absorption of Carbon

Dioxide at High Partial Pressures in 1-Amino-2-propanol Aqueous Solution. Considerations

of Thermal Effects. Ind. Eng. Chem. Res.1997, n°36, p.4358-4364

[34] Praveen. S. Nair & P.P. Selvi. Absorption of Carbon dioxide in Packed Column.

International Journal of Scientific and Research Publications, 2014, vol.4, n°4. ISSN 2250-

3153

[35] Sanjay Bishnoi & Gary T. Rochelle. Absorption of carbon dioxide into aqueous

piperazine: reaction kinetics, mass transfer and solubility. Chemical Engineering Science,

2000, n° 55, p.5531-5543

[36] Adewale Adeosun et al. Absorption of CO 2 by Amine Blends Solution: An

Experimental

Evaluation. International Journal Of Engineering And Science, 2013, vol.3, n°9, p.12-23

[37] A. Corti, L. Lombardi & G. Manfrida. Absorption of CO2 with amines in a

semiclosed GT cycle: Plant Performance and Operating Costs. Document en ligne sur le site

http://asmedl.org/, consulté le 03/06/2015 à 14h 35min.

[38] Kh. Mohamadbigy et al. Amine absorption column design using mass transfer rate

simulation. Petroleum & Coal, 2005, vol.2, n°47, p.36-46

[39] Renjie Shao & Aage Stangeland. Amines used in CO2 Capture : Health and

Environmental Impacts. Bellona Report, Septembre 2009. 49 p.

[40] Emilian Koller, Aide-Mémoire Génie Chimique. Paris : 3ème Edition. 2009, pp353-375.

[41] Dan G. Chapel et al. Recovery of CO2 from Flue Gases: Commercial Trends. Rapport

de la rencontre annuelle de la « Société Canadiennes des Ingénieurs Chimistes », Saskatoon,

Saskatchewan, Canada, du 4 au 6 Octobre 1999, 17 p.

[42] Anand B. Rao, Edward S. Rubin & Michael B. Berkenpas. An integrated modeling

framework for carbon management technologies, DOE, 2004

[43] MITSUBISHI HEAVY INDUSTRIES, LTD. An overview of re-use and application of

CO2 by Mitsubishi Heavy Industries. Mitsubishi LTD, Juillet 2010, 44 p.

[44] Eric P. Robertson. Analysis of CO2 Separation from Flue Gas, Pipeline Transportation,

and Sequestration in Coal, Septembre 2007, 40 p. INL/EXT-08-13816

[45] LEONARD Grégoire et al. Modélisation du captage post-combustion de CO2 avec

évaluation de la dégradation des solvants. Récents Progrès en Génie des Procédés, Ed. SFGP,

Paris, France, 2013, n°104. ISBN: 978-2-910239-78-7

[46] Lars Erik Øi. Aspen HYSYS Simulation of CO2 Removal by Amine Absorption from a

Gas Based Power Plant. 9 p. Conférence de SIMS2007, Gøteborg, 30-31 Octobre 2007

[47] Seok Kim, Hyung-Taek Kim. Aspen simulation of CO2 absorption system with various

amine solution. Prepr. Pap.-Am. Chem. Soc., Div. Fuel Chem. 2004, vol.1, n°49, p.251

[48] A. M. Wolsky, E. J. Daniels & B. J. Jody. CO2 Capture from the Flue Gas of

Conventional Fossil-Fuel-Fired Power Plants. Environnmental Progress, 1994, vol.13, n°3,

p.214-219

[49] ADEME. Projet C2A2 Captage de CO2 par Amines avancées. Angers, Juin 2014

[50] PRYEN Marie & LAKRARI Anas. Etude bibliographique sur la capture et le

transport du CO2 dans les centrales thermiques. Ecole des Mines de Douai, 2009, 40 p.

[51] ORGANISATION DES NATIONS UNIES POUR LE DEVELOPPEMENT

INDUSTRIEL (UNIDO, Vienne). Carbon Capture and Storage in Industrial Applications.

Rapport de synthèse technologique. Vienne, Novembre 2010, 83 p.

[52] Władysław Moniuk, Ryszard Pohorecki & Piotr Machniewski. Carbon dioxide

absorption into aqueous blends of N-methyldiethanolamine and 2-ethylaminoethanol.

Chemical and Process Engineering, 2012, vol.4, n°33, p.547-561. DOI: 10.2478/v10176-012-

0045-7

[53] DOE. Carbon Dioxide Capture from Existing Coal-Fired Power Plants. Washington :

DOE, Décembre 2006, 229 p. Rapport DOE/NETL-401/110907

[54] Ya Liang. Carbon dioxide capture from flue gas using regenerable sodium-based

sorbents. Thèse Ingénierie Chimique : Collège Universitaire d’Agriculture et de Mécanique

de Lousiana, 2003, 137 p.

[55] Sepideh Ziaii Fashami. CO2 removal with 7M monoethanolamine (MEA) – Aspen Plus

model for base case. Texas : DOE, Décembre 2006, 15 p. Rapport DE-FG02-06ER84625

[56] Guilbert Ebune. Carbon Dioxide Capture from Power Plant Flue Gas using

Regenerable Activated Carbon Powder Impregnated with Potassium Carbonate. Mémoire de

Master Etudes Environnementaux : Univ. De l’Etat de Youngstown, 2008, 49 p.

[57] M.R.M. Abu-Zahra, J.P.M. Niederer, P.H.M. Feron, G.F. Versteeg, CO2 capture

from power plants: Part II. A parametric study of the economical performance based on

mono-ethanolamine, International Journal of Greenhouse Gas Control. 1 (2007) 135-142.

[58] Mohammad R. M. Abu-Zahra et al. Carbon Dioxide Post-Combustion Capture:

Solvent Technologies Overview, Status and Future Directions, A.Méndez-Vilas, Ed. 2013,

p.923-934

[59] Hanna Kierzkowska-Pawlak (2010) Carbon Dioxide Removal from Flue Gases by

Absorption/Desorption in Aqueous Diethanolamine Solutions, Journal of the Air & Waste

Management Association, 60:8, 925-931, DOI:10.3155/1047-3289.60.8.925

[60] Supitcha Rinprasertmeechai. Carbon Dioxide Removal from Flue Gas Using Amine-

Based Hybrid Solvent Absorption. International Journal of Chemical and Biological

Engineering, 2012, n°6, p.296-300

[61] Ioana IONEL et al. Carbon dioxide separation from flue gas using amine-based system.

TERMOTEHNICA, 2008, vol.2, p.43-48

[62] Dariusz Asendrych, Paweł Niegodajew & Stanisław Drobniak. CFD modelling of

CO2 capture in a packed bed by chemical absorption. Chemical and Process Engineering,

2013, vol.2, n°34, p.269-282. DOI: 10.2478/cpe-2013-0022

[63] WOJCIECH M. BUDZIANOWSKI, CO2 reactive absorption from flue gases into

aqueous ammonia solutions: the NH3 slippage effect. Environment Protection Engineering,

2011, Vol.37, n°4, p.5-19

[64] Naghi Jadidi & Ehsan Rahmandoust. CO2 Capturing from Industrial Flue Gases.

American Journal of Oil and Chemical Technologies, 2015, Vol.3, n°2, p.34-40

[65] NICHOLAS P. DEVRIES, CO2 absorption into concentrated carbonate solutions with

promoters at elevated temperatures. Thèse Master of Science in Agricultural and Biological

Engineering : Univ. d’Illinois, 2014, 76 p.

[66] IEA Greenhouse Gas R&D Programme 2008. CO2 capture in the cement industry.

2008. Etude technique 2008/3, 221 p.

[67] Anne Tibbett, Stuart Day & Merched Azzi. CO2 Capture Mongstad – Project A

Establishing sampling and analytical procedures for potentially harmful components from

post-combustion amine based CO 2 capture In Task 4: Literature survey of analytical

procedures and recommendations. CSIRO, 2010

[68] P.H.M. Feron & C.A. Hendriks. CO2 Capture Process Principles and Costs. Oil & Gas

Science and Technology – Rev. IFP, Vol. 60 (2005), No. 3, p.452-459

[69] Colin F. Alie. CO2 Capture With MEA: Integrating the Absorption Process and Steam

Cycle of an Existing Coal-Fired Power Plant. Thèse Ingénierie Chimique : Univ. de

Waterloo, 2004, 178 p.

[70] IEA. CO2 emissions from fuel combustion, Edition 2010, 130 p.

[71] E. Gambarotta et al. CO2 Separation from Flue Gas: Evaluation of a Solid Sorbent

Based Process.

[72] IEA Greenhouse Gas R&D Programme 2007. CO2 capture ready plant. 2007. Etude

technique 2007/4, 127 p.

[73] Murlidhar Gupta, Irene Coyle & Kelly Thambimuthu. CO2 capture technologies and

opportunities for Canada. Strawman Document for CO2 capture and storage technology

Roadmap, Canada, 2003

[74] Carol Toro Molina. Comparaison du captage du CO2 en postcombustion par des

solutions d’ammoniaque et d’amines organiques : Evaluation en contacteurs direct et

indirect, par des approches cinétiques, thermodynamiques et par modélisation. Other. Ecole

Nationale Supérieure des Mines de Paris, 2013. French. <NNT : 2013ENMP0029>. <pastel-

00935386>

[75] Suvajit Naskar, Kuntal Jana & Sudipta De. Comparative performance study of CO2

capture with monoethyl and diethyl amines using Aspen Plus. International Journal of

Emerging Technology and Advanced Engineering, 2013, Vol.3, N°3, p.490 -497

[76] Aida Rafat Abou El-Ela. Corrosion behavior of carbon steel in absorption based CO2

capture plant. Thèse Ingénierie Environnementale : Univ. de Qatar, 2014, 175 p.

[77] Mathias Finkenrath. Cost and performance of carbon dioxide capture from power

generation. IEA, 2011, 51 p.

[78] Edward S. Rubin, Chao Chen, Anand B. Rao. Cost and performance of fossil fuel

power plants with CO2 capture and storage. Energy Policy, 2007, Vol.35, p.4444-4454

[79] Ove Braut Kallevik. Cost estimation of CO2 removal in HYSYS. Thèse : Collège

Universitaire de Telemark, 2010, 131 p.

[80] Robert M. Cowan et al. Current status of CO2 capture technology development and

application, 2011, 189 p. Rapport DE-FC26-05NT42592

[81] Brian R. Strazisar, Richard R. Anderson & Curt M. White. Degradation of

Monoethanolamine Used in Carbon Dioxide Capture from Flue Gas of a Coal-fire Electric

Power Generating Station. Pittsburgh, 8 p.

[82] Imperial College University of Sheffield. Demonstrating CO2 capture in the UK

cement, chemicals, iron and steel and oil refining sectors by 2025: A Techno-economic Study ,

Element Energy LTD, 2014, 412 p.

[83] Ulrich Liebenthal & Alfons Kather. Design and Off-Design Behaviour of a CO2

Compressor for a Post-Combustion CO2 Capture Process. 15 p. 5ème Conférence

Internationale on sur les Technologies de Charbon Propre, Saragoza, Espagne, 8 - 12 May

2011

[84] Anand B. Rao. A Details of A Technical, Economic and Environmental Assessment of

Amine-based CO2 Capture Technology for Power Plant Greenhouse Gas Control. 2002. 40 p.

Rapport DE-FC26-00NT40935.

[85] Espen S. Hamborg et al. Determination of dissociation constants of CO2 absorbents

between 293 K – 353 K using electromotive force measurements. Univ. de Twente, 6 p.

[86] Ross E. Dugas. Pilot Plant Study of Carbon Dioxide Capture by Aqueous

Monoethanolamine. Thèse : Univ. de Texas, 2006, 143 p. Rapport DE-FC26-02NT41440

[87] Jérémy David. Economic Evaluation of Leading Technology Options for Sequestration

of Carbon Dioxide. Diplôme d’Ingénieur, Ecole Nationale Supérieure d’Ingénieurs du Génie

Chimique : Institut de Technologie de Massachusetts, 2000, 84 p.

[88] Prachi Singh, W. P. M. Van Swaaij & D.W.F. (Wim) Brilman. Energy Efficient

Solvents for CO 2 Absorption from Flue Gas: Vapor Liquid Equilibrium and Pilot Plant

Study. Energy Procedia, n° 37, (2013), p.2021 – 2046

[89] Camel MAKHLOUFI. Etude expérimentale et modélisation d'un procédé de captage

du CO2 en postcombustion par l'ammoniaque à l'aide de contacteurs membranaires : du

matériau à l'évaluation de l'intensification de l'absorption. Thèse Génie des Procédés et des

Produits : Univ. de Lorraine, 2013, 276 p.

[90] Ehsan Rahmandoost, Behrooz Roozbehani & Mohammad Hosein Maddahi.

Experimental Studies of CO2 Capturing from the Flue Gases. Iranian Journal of Oil & Gas

Science and Technology, 2014, Vol.4, N°4, pp.01-15

[91] Erik Gjernes, Laila Iren Helgesen & Yolandi Maree. Health and environmental

impact of amine based postcombustion CO2 capture. Energy Procedia, 2013

[92] Maciej Radosz. Flue-Gas Carbon Capture on Carbonaceous Sorbents: Toward a Low-

Cost Multifunctional Carbon Filter for Green Energy Producers. American Chemical

Society, mis en ligne le 29/04/2008.

[93] OLIVIER LASSAGNE. Analyse techno-économique de l'implantation de la capture du

CO2 dans une aluminerie. Mémoire Maitrise ès Sciences en Génie Mécanique : Univ. de

Laval, 2013, 100 p.

[94] Jochen Oexmann, Christoph Hasenbein & Alfons Kather. Semi-empirical model for

the direct simulation of power plant with integrated post-combustion CO2 capture processes

by wet chemical absorption. Energy Procedia, 2011, Vol.4, pp.1276-1285

[95] Jörn Rolker, Matthias Seiler. Industrial Progress: New Energy-Efficient Absorbents

for the CO2 Separation from Natural Gas, Syngas and Flue Gas. Advances in Chemical

Engineering and Science, 2011, Vol.1, pp.280-288

[96] Kevin S. Fisher et al. Integrating MEA regeneration with CO2 compression and peaking

to reduce CO2 capture costs. DOE : 2005, 95 p. Rapport DE-FG02-04ER84111

[97] Mehdi Karimi, Magne Hillestad & Hallvard F. Svendsen. Investigation of

intercooling effect in CO2 capture energy consumption. Energy Procedia, 2011, Vol.4,

pp.1601-1607

[98] Hanna KIERZKOWSKA-PAWLAK & Andrzej CHACUK. Kinetics of carbon

dioxide absorption into aqueous MDEA solutions. Ecological chemistry and engineerings,

2010, Vol.17, No.4

[99] Ahmed Aboudheir et al. Kinetics of the reactive absorption of carbon dioxide in high

CO2-loaded, concentrated aqueous monoethanolamine solutions. Chemical Engineering

Science, 2003, No.58, pp.5195–5210

[100] Chakib Bouallou. Le captage du CO2 dans les centrales thermiques. Chimie şi

Inginerie Chimică, Biotehnologii, Industrie Alimentară, 2010, Vol.1, No.11, pp.183-212

[101] Yongping Yang & Rongrong Zhai. MEA-Based CO2 Capture Technology and Its

Application in Power Plants. North China Electric Power University China

[102] Udara S.P.R. Arachchige et al. Model Development for CO2 Capture in the Cement

Industry. International Journal of Modeling and Optimization, Vol. 3, No. 6, December 2013

[103] QIAN Zhi & GUO Kai. Modeling and Kinetic Study on Absorption of CO2 by Aqueous

Solutions of N-methyldiethanolamine in a Modified Wetted Wall Column. Chinese Journal of

Chemical Engineering, 2009, Vol.4, No.17, pp.571-579

[104] Peter Frailie & Gary T. Rochelle. Modeling Energy Performance of Aqueous

MDEA/PZ for CO2 Capture. The University of Texas at Austin Luminant Carbon

Management Program TCCS-6, Juin 2011

[105] Jean-Marc Amann et al. Modeling of the CO2 capture in post-combustion. Scientific

Study & Research, Vol. VIII (1), 2007, ISSN 1582-540X

[106] FOURATI Manel. Modélisation par une approche à deux fluides des écoulements gaz

liquide à contre-courant dans les colonnes à garnissages. Thèse Dynamique des fluides :

Univ. de Toulouse, 2012, 226 p.

[107] S. Nazir et al. Modelling for capture of carbon dioxide using aqueous ammonia from

flue gases of a brick kiln. International Journal of Chemical and Environmental Engineering,

2011, Vol.2, No.3, 8 p.

[108] HECTOR JAVIER CHAVARRO MONTENEGRO. Novel solvents for CO2 capture

flowsheet analysis, Univ. de Manchester, 2011

[109] L.M. Romeo, I. Bolea, Y. Lara, J.M. Escosa, Optimization of intercooling

compression In CO2 capture systems, Applied Thermal Engineering (2008), doi:

10.1016/j.applthermaleng.2008.08.010

[110] ADEME. Panorama des voies de valorisation du CO2, Juin 2010

[111] Leila Faramarzi. Post-Combustion Capture of CO2 from Fossil Fueled Power Plants.

Thèse PhD : Univ. Technique de Danemark, 2010, 106 p.

[112] Sóley Emilsdóttir & Stefanía Ósk Garðarsdóttir. Transient behaviour of post-

combustion CO2 capture with MEA, Univ. de Technologie de Chalmers, 2012

[113] Jochen Oexmann. Post-combustion CO2 capture : energetic evaluation of chemical

absorption processes in coal-fired steam power plants. Thèse: Univ. Technique de Hamburg‐Harburg, 2011, 206 p.

[114] Amrutha Raghu. Quantification of amine loss in the post combustion CO2 capture

process. Thèse Ingénierie des Systèmes Environnementaux : Univ. de Regina, 2012, 88 p.

[115] Jou F-Y, Mather A., Otto F., The solubility of CO2 in a 30 mass percent

monoethanolamine solution, The Canadian Journal of Chemical Engineering, vol. 73, pp.

140-147, Février 1995.

[116] Lee JI, Otto FD, Mathera A.E. Equilibrium Between Carbon Dioxide and Aqueous

Monoethanolamine Solutions. Journal of Applied Chemical Biotechnology 1976; 26: 541-

549.

[117] Freguia, S et Rochelle, G. T. (2003) Modeling of CO2 absorption/stripping with

monoethanolamine. AIChE Journal, 49(7):1676–1687.

[118] Chakma, A., et al. (1995). Comparison of chemical solvents for mitigating CO2

emissions from coal-fired power plants. Heat Recovery Systems and CHP, 15(2):231–

240.

[119] Barchas, R.; Davis, R. (1992). Energy Conversion Management 33 (5-8), 333-340.

[120] Wilson, M. A. et al. (1992). Recovery of CO2 from power plant flue gases using

amines. Energy Conversion and Management, 33(5–8):325–331.

[121] Veawab, A. (2002). Corrosion in CO2 capture unit for coal-fired power plant flue gas.

In J. Gale and Y. Kaya, editors, Greenhouse Gas Control Technologies: Proceedings of the

6th International Conference on Greenhouse Gas Control Technologies, volume 2, pages

1595–1598. Elsevier Science Ltd.

[122] Goff, G. S. et Rochelle, G. T., Oxidative degradation of aqueous monoethanolamine in

CO2 capture systems under absorber conditions. Volume 1, pages 115–119. Elsevier Science

Ltd., October 2002.

[123] Célestin AGUIDI, Economie et utilisation rationnelle de l’énergie à la Société

Béninoise de Brasseries (SOBEBRA): bilan énergétique de l’usine de Cotonou. Mémoire

Ingénieur de conception en Génie Energétique : Ecole Polytechnique d’Abomey-Calavi,

2012, 145p.

[124] Jennifer Wilcox, Carbon Capture. New York : Springer Science & Business Media, 27

Mars 2012, ISBN 978-1-4614-2214-3, 234p.