Nanomaterials and processes for carbon capture and conversion into useful by-products for a sustainable energy future

Greenhouse Gases: Science and Technology

Volumn 2, Issue 6, 2012, Pages 419-444

  Ashley, Michael ^a   Magiera, Charles ^a   Ramidi, Punnamchandar ^b   Blackburn, Gary ^c,d   Scott, Timothy G ^a   Gupta, Rajeev ^e   Wilson, Kerry ^c   Ghosh, Anindya ^b   Biswas, Abhijit ^a  

^a University of Notre Dame   (United States)

^b University of Arkansas at Little Rock ^*  (United States)

^c UNIVERSITY OF NOTRE DAME   (United States)

^d TRINITY COLLEGE DUBLIN   (Ireland)

^e UNIVERSITY OF PETROLEUM AND ENERGY STUDIES   (India)

Author keywords

Carbon capture; Conversion and storage; Greenhouse gases; Nanomaterials; Sustainable energy

Indexed keywords

CARBON DIOXIDE; EMISSION CONTROL; ENERGY CONSERVATION; GREENHOUSE GASES; LIQUID METHANE; METHANOL FUELS; NANOSTRUCTURED MATERIALS;

CAPTURE AND STORAGE TECHNOLOGIES; CARBON CAPTURE PROCESS; LATEST DEVELOPMENT; SUSTAINABLE ENERGY; TWO SECTION;

CARBON CAPTURE;

EID: 84873637674     PISSN: None     EISSN: 21523878     Source Type: Journal    
DOI: 10.1002/ghg.1317     Document Type: Article

References (134)

1. Olah GA, Goeppert A and Surya Prakash GK, Chemical recycling of carbon dioxide to methanol and dimethyl ether: from greenhouse gas to renewable, environmentally carbon neutral fuels and synthetic hydrocarbons. J Org Chem 74 (2):487-498 (2009).
2. U.S. Energy Information Administration and DOE, International energy outlook (2010).
3. Benson S and Cook P, Special Report on Carbon Capture and Storage. Intergovernmental Panel on Climate Change, pp.259 (2005). United Nations.
4. Environmental Protection Agency. Global Emissions. [Online]. United States Government. Available at: http://epa. gov/climatechange/ghgemissions/ global.html, access date: June 10, 2012
5. 2 from fl ue gas: A review. Sep Sci Tech 40(1/3):321-348 (2011).
6. Bailey DW and Feron PHM, Post-combustion decarbonisa-tion processes. Oil Gas Sci Technol 60(3):461-474 (2005).
7. Hosseini SS, Li Y, Chung TS and Liu Y, Enhanced gas separation performance of nanocomposite membranes using MgO nanoparticles. J Mem Sci 302(1/2):207-217 (2007).
8. 2 capture from fl ue gas-aspects from materials and theoretical chemistry. Nanoscale 2(10):1819-1841 (2010).
9. 2 capture over amine-func-tionalized MCM-22, MCM-36, and ITQ-2. Fuel 97:435-442 (2012).
10. Srivastava P, Kumar A, Behera SK, Sharma YK and Singh N, Soil carbon sequestration: An innovative strategy for reducing atmospheric Carbon Dioxide concentration. Biodivers Conserv 21(5):1343-1358 (2012).
11. 2 activation: Towards a sustainable energy future. Vacuum Technol Coating 12(11):26-31 (2011).
12. 2 into specialty chemicals. Proceedings of the ASME 2011 5th International Conference on Energy Sustainability, ES2011-54048, August 7-10, 2011, Washington DC, USA, pp. 1-8 (2011).
13. Olah GA, Goeppert A and Surya Prakash GK, Beyond Oil and Gas: The Methanol Economy. Wiley Publishing (2006). Hoboken, New Jersey.
14. 2 capture and storage: from pore scale to regional scale. Energy Environ Sci 5(6):7328-7345 (2012).
15. 2 sequestration in deep, saline, dolomitic-limestone aquifers: Critical evaluation of thermo-dynamic sub-models. Chem Geo 306:29-39 (2012).
16. 2 geological sequestration. Int J Greenhouse Gas Cont 8:90-100 (2012).
17. Szulczewski ML, MacMinn CW, Herzog HJ and Juanes R, Lifetime of carbon capture and storage as a climate-change mitigation technology. P Nat Acad Sci USA 109(14):5185-5189 (2012).
18. 2 sequestration sites due to shale and tight gas production. Env Sci Tech 46(7):4223-4227 (2012).
19. 2 storage in saline formations. Int J Greenhouse Gas Cont 7:168-180 (2012).
20. Delgado MR and Arean CO, Carbon Monoxide, dinitrogen, and Carbon Dioxide adsorption on zeolite H-Beta: IR spectroscopic and thermodynamic studies. Energy 36(8):5286-5291 (2011).
21. 2 on nitrogen-enriched activated carbon and zeolite 13X. J Int Adsorption Soc 17(1):235-246 (2011).
22. Llano-Restrepo M, Accurate correlation, structural interpretation, and thermochemistry of equilibrium adsorption isotherms of Carbon Dioxide in zeolite NaX by means of the GSTA model. Fluid Phase Equilibr 293(2):225-236 (2010).
23. Liu Z, Grande CA, Li P, Yu J and Rodrigues AE, Adsorption and desorption of carbon dioxide and nitrogen on zeolite 5A. Sep Sci Technol 46(3):434-451 (2011).
24. Eddaoudi M, Kim J, Rosi N, Vodak D, Wachter J, O'Keeffe M and Yaghi OM, Systematic design of pore size and functionality in isoreticular MOFs and their application in methane storage. Science 295(5554):469-472 (2002).
25. Wang B, Cote AP, Furukawa H, O'Keeffe M and Yaghi OM, Colossal cages in zeolitic imidazolate frameworks as selective carbon dioxide reservoirs. Nature 453(7192):207-211 (2008).
26. Millward AR and Yaghi OM, Metal-organic frameworks with exceptionally high capacity for storage of Carbon Dioxide at room temperature. J Am Chem Soc 127(51):17988-17999 (2005).
27. Furukawa H, Ko N, Go YB, Aratani N, Choi SB, Choi E et al., Ultrahigh porosity in metal-organic frameworks. Science 329(5990):424-428 (2010).
28. 4/CO gas mixtures at high pressures. Microporous and Mesoporous Materials 156:217-223 (2012).
29. 2 capture capability and molecular-level segregation in a Li-modifi ed metal organic framework. J Phys Chem C 114 (39):16611-16617 (2010).
30. Yazaydin AO, Snurr RQ and Park TH, Screening of metal-organic frameworks for carbon dioxide capture from fl ue gas using a combined experimental and modeling approach. J Am Chem Soc 131(51):18198-18199 (2009).
31. 2 adsorption by a triazacyclononane-bridged microporous metal-organic framework. Chem Eur J 17(24):6689-6695 (2011).
32. 2 capture. J Mem Sci 403:169-178 (2012).
33. 2 separation. J Mem Sci 403:203-215 (2012).
34. Xiaoling R, Jizhong R and Hui L, Poly (amide-6-b-ethylene oxide) multilayer composite membrane for Carbon Dioxide separation. Int J Greenhouse Gas Cont 8:111-120 (2012).
35. 2. Polym Advan Technol 23(5):835-840 (2012).
36. 2-cap-ture applications. Nature Materials 10(5):372-375 (2011).
37. Brennecke JF and Maginn EJ, Ionic liquids: Innovative fl uids for chemical processing, AIChE J 47:2384-2389 (2001).
38. Rogers RD and Seddon K, Ionic Liquids-Solvents of the future? Science 302:792-793 (2003).
39. 2 solubility and selectivity in nitrile-func-tionalized room-temperature ionic liquids using a group contribution approach. Ind Eng Chem Res 47:7005-7012 (2008).
40. Noble RD and Gin DL, Perspective on ionic liquids and ionic liquid membranes. J Membrane Sci 369:1-4 (2011).
41. -anion supported ionic liquid membranes. J Membrane Sci 238:57-63 (2004).
42. Bara JE, Gabriel CJ, Carlisle TK, Camper DE, Finotello A, Gin DL and Noble RD, Gas separations in fl uoroalkylfunc-tionalized room-temperature ionic liquids using supported liquid membranes. Chem Eng J 147: 43-50 (2009).
43. Cserjesi P, Nemestothy N and Belafi-Bako K, Gas separation properties of supported liquid membranes prepared with unconventional ionic liquids. J Membrane Sci 349:6-11 (2010).
44. Neves LA, Crespo JG and Coelhoso IM, Gas permeation studies in supported ionic liquid membranes. J Membrea Sci 357:160-170 (2010).
45. 2 separation performance and selectivities for room temperature ionic liquid membranes. J Membrane Sci 327:41-48 (2009).
46. 2 separation facilitated by task-specifi c ionic liquids using a supported liquid membrane. J Membrane Sci 314:1-4 (2008).
47. Myers C, Pennline H, Luebke D, Ilconich J, Dixon JK, Maginn EJ and Brennecke JF, High temperature separation of carbon dioxide/hydrogen mixtures using facilitated supported ionic liquid membranes. J Membrane Sci 322:28-31 (2008).
48. 2 separation membranes using ionic liquids in a Nafi on matrix. J Membrane Sci 363:72-79 (2010).
49. 4 separation. Chem Eng J 166:401-406 (2011).
50. Cuffe L, MacElroy JMD, Tacke M, Kozachok M and Mooney DA, The development of nanoporous membranes for separation of carbon dioxide at high temperatures. J Membrane Sci 272(1/2):6-10 (2006).
51. 2 capture using MECC membranes. J Membrane Sci 401:323-332 (2012).
52. Buonomenna MG, Golemme G and Tone CM, Nanostruc-tured poly(styrene-b-butadiene-b-styrene) (SBS) membranes for the separation of nitrogen from natural gas. Adv Funct Mater 22(8):1759-1767 (2012).
53. 2 separations using nanoporous alumino-supported ionic liquid membranes: effect of the support on separation performance. J Membrane Sci 390:201-210 (2012).
54. Anderson C, Pas S, Arora G, Kentish SE, Hill AJ, Sandler SI and Stevens GW, Effect of pyrolysis temperature and operating temperature on the performance of nanoporous carbon membranes. J Membrane Sci 322(1):19-27 (2008).
55. Moon HR, Urban JJ and Milliron DJ, Size-controlled synthesis and optical properties of monodisperse colloidal magnesium oxide nanocrystals. Angew Chem Int Ed 48(34):6278-6281 (2009).
56. Bourlines BA, Herrera R, Chalkias N, Jiang DD, Zhang Q, Archer AL and Giannelis PE, Surface functionalized nanopar-ticles with liquid-like behavior. Adv Mater 17:234-237 (2005).
57. Kim BJ, Cho KS and Park SJ, Copper-oxide decorated porous carbons for Carbon Dioxide adsorption behaviors. J Colloid Interf Sci 342(2):575-578 (2010).
58. Stephan W, Noble RD and Koval CA, Design methodology for a membrane/distillation column hybrid process. J Membrane Sci 99(3):259-272 (1995).
59. 2 capture. Energy Environ Sci 4:1765-1771 (2011).
60. 2 capture using dynamically operated low-cost fi ber beds. Chem Eng Sci 71:97-103 (2012).
61. Pacheco DM, Johnson JR and Koros WJ, Aminosilane-func-tionalized cellulosic polymer for increased Carbon Dioxide sorption. Ind Eng Chem Res 51(1):503-514 (2012).
62. 2 capture from air. Environ Sci Technol 45(20):9101-9108 (2011).
63. Mishra AK and Ramaprabhu S, Palladium nanoparticles decorated graphite nanoplatelets for room temperature carbon dioxide adsorption. Chem Eng J 187:10-15 (2012).
64. 2 capture. J Mater Chem 22:3708-3712 (2012).
65. Mishra AK and Ramaprabhu S, Nano magnetite decorated multiwalled carbon nanotubes: A robust nanomaterial for enhanced Carbon Dioxide adsorption. Energy Environ Sci 4:889-895 (2011).
66. Biswas A, Tokoly T, Wang T, Ramidi P, Ghosh A,Dervishi E, et al., Design and synthesis of sprayable nanocomposite coatings for carbon capture and direct conversion into environmentally safe stable carbonates. Chem Phys Lett 508(4/6):276-280 (2011).
67. 2 capture based on amine-functionalized mesoporous capsules. Energy Environ Sci 4:444-452 (2011).
68. Mishra AK and Ramaprabhu S, Carbon dioxide adsorption in graphene sheets. AIP Advances 1:032152 (2011).
69. Chen YH, Reilly J and Paltsev S, The Prospects for coal-to-liquid conversion: A general equilibrium analysis. Energy Policy 39(9):4713-4725 (2011).
70. Brooks K, Hu J, Zhu H and Kee RJ, Methanation of carbon dioxide by hydrogen reduction using the sabatier process in microchannel reactors. Chem Eng Sci 62(4):1161-1170 (2007).
71. Meng DD, Hur J and Kim C, Membraneless micro fuel cell chip enabled by self-pumping of fuel-oxidant mixture. IEEE 23rd International Conference on Micro Electro Mechanical Systems. (2010). University of California, Los Angeles, CA, USA, 02/2010.
72. Hollinger AS, Maloney RJ, Jayashree RS, Natarajan D, Markoski LJ and Kenis PJA, Nanoporous separator and low fuel concentration to minimize crossover in direct methanol laminar fl ow fuel cells. J Power Sources 195(11):3523-3528 (2010).
73. Ashley M, Ramidi P, Bontrager T, Magiera C, Ghosh A, Biris AS et al., Engineered nanocomposites for capturing and converting carbon dioxide into useful chemicals. MRS Online Proc Lib 1441:5-22 (2012).
74. 2 for sustainable development involving energy, catalysis, adsorption and chemical processing. Catalysis Today 115 (1/4):2-32 (2006).
75. Kim IG, Jo B, Kang D, Kim CS, Choi YS and Cha HJ, Biomineralization-based conversion of carbon dioxide to calcium carbonate using recombinant carbonic anhydrase. Chemosphere 87(10):1091-1096 (2012).
76. 2 into cyclic carbonates in the presence of metal complexes as catalysts. J Chem Res 34(11):622-626 (2010).
77. 2 cycloaddition reactions. Green Chem 11 (4):455-458 (2009).
78. 2 fi xation. Polymer Chem 2(10):2306-2315 (2011).
79. Gao J, Song Q, He L, Liu C, Yang Z, Han X et al., Preparation of polystyrene-supported Lewis acidic Fe(III) ionic liquid and its application in catalytic conversion of Carbon Dioxide. Tetrahedron 68(20):3835-3842 (2012).
80. Darensbourg D, Chemistry of carbon dioxide relevant to its utilization: A personal perspective. Inorg Chem 49(23):10765-10780 (2010).
81. North M, Villuendas P and Young C, A gas-phase fl ow reactor for ethylene carbonate synthesis from waste Carbon Dioxide. Chem Eur J 15(43):11454-11457 (2009).
82. 2. Energ Fuel 26(4):2473-2482 (2012).
83. 2: Further insight into the mechanism over Rh/γ-Al2O3 catalyst. Appl Catalysis B Environ 113/114: 2-10 (2012).
84. 2 nanotube array photoelectrochemical cell. Nanoscale 4(7):2245-2250. (2012).
85. Centi G and Perathoner S, Opportunities and prospects in the chemical recycling of carbon dioxide to fuels. Catal Today 148 (3/4):191-205 (2009).
86. 2 particles. J Phys Chem 114 (51):22763-22772 (2010).
87. 2 nanoparticles. Energy Environ Sci 5(3):6066-6070 (2012).
88. Centi G, Perathoner S and Rak Z, Reduction of greenhouse gas emissions by catalytic processes. Appl Catal B Environ 41(1/2):143-155 (2003).
89. Roy S, Varghese O, Paulose M and Grimes C, Toward solar fuels: photocatalytic conversion of carbon dioxide to hydrocarbons. ACS Nano 4(3):1259-1278 (2010).
90. 2 affi nity for the photocatalytic conversion of carbon dioxide into methane. J Mater Chem 22(12):5304-5307 (2012).
91. 2 into methane under solar irradiation. Angew Chem Int Ed 51(16):3915-3918 (2012).
92. 2 capture and utilization. ChemSusChem 1(11):893-899 (2008).
93. Tanaka R, Yamashita M and Nozaki K, Catalytic hydrogenation of carbon dioxide using Ir(III)-Pincer complexes. J Am Chem Soc 131:14168-14169 (2009).
94. 2 to methanol. J Am Chem Soc 133:18122-18125 (2011).
95. Wesselbaum S, Stein TS, Klankermayer J and Leitner W, Hydrogenation of carbon dioxide to methanol by using a homogeneous ruthenium-phosphine catalyst. Angew Chem Int Ed 51:7499-7502 (2012).
96. Chakraborty S, Zhang J, Krause JA and Guan H, An effi cient nickel catalyst for the reduction of Carbon Dioxide with a borane. J Am Chem Soc 132:8872-8873 (2010).
97. 2 to Methanol derivatives. Polyhedron 32:30-34 (2012).
98. 2 to a methanol derivative? A computational mechanistic study. Inorg Chem 50:3816-3825 (2011).
99. 3OH. Angew Chem Int Ed 48:9839-9843 (2009).
100. 2 to Methanol by Al-based frustrated lewis pairs and Ammonia Borane. J Am Chem Soc 132:1796-1797 (2010).
101. Riduan SN, Zhang Y and Ying JY, Conversion of Carbon Dioxide into Methanol with silanes over N-heterocyclic carbene catalysts. Angew Chem Int Ed 48:3322-3325 (2009).
102. 3OH. Appl Catal A Gen 350(1):16-23 (2008).
103. 3OH. Angew Chem Int Ed 50(9):2162-2165 (2011).
104. 2 to methanol: Kinetic, mechanistic, and structural insights. J Am Chem Soc 132(33):11539-1155 (2010)
105. 2 reduction. Chem Sus Chem 4(2):191-196 (2011).
106. Chinchen GC, Denny PJ, Jennings JR, Spencer MS and Waugh KC, Synthesis of methanol: Part 1. Catalysts and kinetics. Appl Catal 36:1-65 (1988).
107. 2-rich feed and from a CO-rich feed. Appl Catal A 218(1/2):235-240 (2001).
108. Aguayo A, Ereña J, Mier D, Arandes J, Olazar M and Bilbao J, Kinetic modeling of dimethyl ether synthesis in a single step on a CuO-ZnO-Al2O3/γ-Al2O3 catalyst. Ind Eng Chem Res 46(17):5522-5530 (2007).
109. 2O/SiC nanocrystallite under visible light irradiation. J Nat Gas Chem 20(2):145-150 (2011).
110. Carne CL and Klabunde KJ, The catalytic methanol synthesis over nanoparticle metal oxide catalysts. J Mol Catal A-Chem 194:227-236 (2003).
111. 3OH. Angew Chem Int Ed 50:2162-2165 (2011).
112. 2 into Benzoic Acid, Formic Acid, and Methanol. Angew Chem Int Ed 51(12):2981-2984 (2012).
113. 2 and water vapor to hydrocarbon fuels. Nano Lett 9(2):731-737 (2009).
114. 2 with chlorophyll and dehydrogenase system. Catal Commun 7(3): 173-176 (2006).
115. Gabor L, Hydrogen storage and delivery: The Carbon Dioxide-Formic Acid couple. Chimia 65(9):663-666 (2011).
116. Munshi P, Main AD, Linehan J, Tai CC and Jessop PG, Hydrogenation of carbon dioxide catalyzed by ruthenium trimethylphosphine complexes: The accelerating effect of certain alcohols and Amines. J Am Chem Soc124:7963 (2002).
117. Tanaka R, Yamashita M, Nozaki K, Catalytic hydrogenation of Carbon Dioxide using Ir(III)-pincer complexes. J Am Chem Soc 131:14168-14169 (2009).
118. Gassner F and Leitner W, Hydrogenation of carbon dioxide to formic acid using water-soluble rhodium catalysts. J Chem Soc Chem Commun 19:1465-1466 (1993).
119. Tsai JC and Nicholas KM, Rhodium-catalyzed hydrogenation of carbon dioxide to formic acid. J Am Chem Soc 114: 5117-5124 (1992).
120. 2O. Org Lett 14: 2642-2645 (2012).
121. 2 to formic acid by formate dehydrogenase immobilized in a novel alginate-silica hybrid gel. Catal Today 115 (1/4):263-268 (2006).
122. Reda T, Plugge CM, Abram NJ and Hirst J, Reversible interconversion of carbon dioxide and formate by an electroactive enzyme. P Natl Acad Sci USA 105(31):10654-10658 (2008).
123. Ha S, Dunbar Z and Masel RI, Characterization of a high performing passive direct formic acid fuel cell. J Power Sources 158(1):129-136 (2006).
124. 2 into formic acid on the catalysis of Cu. AIP Conference Proc 1251(1):234-237 (2010).
125. Cheng M, Wu B, Jin F, Duan X and Wang Y, Methanol production by reduction of formic acid over Cu catalyst under hydrothermal conditions. AIP Conference Proc 1251(1):234-237 (2010).
126. 2 hydrogenation by Ru(II) and Ir(III) aqua complexes under acidic conditions: Two catalytic systems differing in the nature of the rate determining step. Dalton Transactions 21(39):4657-4663 (2006).
127. He C, Tian G, Liu Z and Feng S, A mild hydrothermal route to fi x Carbon Dioxide to simple Carboxylic Acids. Org Lett 12(4):649-651 (2010).
128. Miller JE, Initial case for splitting Carbon Dioxide to Carbon Monoxide and Oxygen. SANDIA Report SAND2007-8012. Sandia National Laboratories, Albuquerque, NM (USA), (2007).
129. Chein R, Chen Y, Chen J and Chung J, Design and test of a miniature hydrogen production reactor integrated with heat supply, fuel vaporization, methanol-steam reforming and carbon monoxide removal unit. Int J Hydrogen Energ 37(8):6562-6571 (2012).
130. Peters M, Köhler B, Kuckshinrichs W, Leitner W, Markewitz P and Müller TE, Chemical technologies for exploiting and recycling Carbon Dioxide into the value chain. Chem-SusChem 4(9):1216-1240 (2011).
131. Azad AM, McDaniel E and Al-batty S, A novel paradigm in Greenhouse Gas Mitigation. Environ Prog Sust Energ 30(4):733-742 (2011).
132. 2-x Nanopar-ticles at room temperature. J Phys Chem C 116 (14):7904-7912 (2012).
133. 2 to CO at low overpotentials. Science 334(6056):643-644 (2011).
134. 2 using reduced Rhenium Tricarbo-nyl Catalysts. J Am Chem Soc 134(11):5180-5186 (2012).