CO2 CAPTURE FROM ATMOSPHERIC AIR VIA SOLAR DRIVEN CARBONATION-CALCINATION CYCLES
暂无分享,去创建一个
[1] U. Schärer,et al. Fast back-reactions of shock-released CO 2 from carbonates: An experimental approach , 2001 .
[2] John R. Grace,et al. The effect of CaO sintering on cyclic CO2 capture in energy systems , 2007 .
[3] Vladimir M. Zamansky,et al. Second Generation Advanced Reburning for High Efficiency NOx Control , 1997 .
[4] T. Yagi,et al. Application of chemical absorption process to CO2 recovery from flue gas generated in power plants , 1992 .
[5] Kang Li,et al. Carbon dioxide stripping in ceramic hollow fibre membrane contactors , 2009 .
[6] K. Van Balen,et al. Carbonation reaction of lime, kinetics at ambient temperature , 2005 .
[7] Klaus S. Lackner,et al. A Guide to CO2 Sequestration , 2003, Science.
[8] G. Marbán,et al. SURFACE AREA AND PORE SIZE CHANGES DURING SINTERING OF CALCIUM OXIDE PARTICLES , 1991 .
[9] Deuk Ki Lee,et al. An apparent kinetic model for the carbonation of calcium oxide by carbon dioxide , 2004 .
[10] A. Steinfeld,et al. Kinetic analysis of the carbonation reactions for the capture of CO2 from air via the Ca(OH)2–CaCO3–CaO solar thermochemical cycle , 2007 .
[11] A. D. Benedetto,et al. Modelling attrition of limestone during calcination and sulfation in a fluidized bed reactor , 1998 .
[12] Aldo Steinfeld,et al. Solar combined thermochemical processes for CO2 mitigation in the iron, cement, and syngas industries , 1994 .
[13] Chong Kul Ryu,et al. CO2 absorption and regeneration of alkali metal-based solid sorbents , 2006 .
[14] D. P. Harrison,et al. HIGH TEMPERATURE CAPTURE OF CARBON DIOXIDE: CHARACTERISTICS OF THE REVERSIBLE REACTION BETWEEN CaO(s) and CO2(g) , 1995 .
[15] K. S. Knaebel,et al. Pressure swing adsorption , 1993 .
[16] L. Heller-Kallai,et al. Decarbonation and recarbonation of calcites heated m CO2 , 1991 .
[17] L. Fan,et al. Carbonation−Calcination Cycle Using High Reactivity Calcium Oxide for Carbon Dioxide Separation from Flue Gas , 2002 .
[18] E. J. Anthony,et al. Fluidized bed combustion systems integrating CO2 capture with CaO. , 2005, Environmental science & technology.
[19] Yunhan Xiao,et al. Steam catalysis in CaO carbonation under low steam partial pressure , 2008 .
[20] Hallvard F. Svendsen,et al. CO2 capture from coal-fired power plants based on sodium carbonate slurry; a systems feasibility and sensitivity study , 2009 .
[21] Robert S. Boynton. Chemistry and Technology of Lime and Limestone , 1966 .
[22] Yuri I. Aristov,et al. Sorption of CO2 from Humid Gases on Potassium Carbonate Supported by Porous Matrix , 2001 .
[23] V. Manović,et al. Sequential SO2/CO2 capture enhanced by steam reactivation of a CaO-based sorbent , 2008 .
[24] D. Geldart. Types of gas fluidization , 1973 .
[25] L. B. Rogers,et al. Differential thermal analysis of the decomposition of sodium bicarbonate and its simple double salts , 1966 .
[26] David W. Keith,et al. Climate Strategy with Co2 Capture from the Air , 2001 .
[27] Axel Meisen,et al. Research and development issues in CO2 capture , 1997 .
[28] Geert Versteeg,et al. CO2 absorption in carbonate/bicarbonate solutions: The Danckwerts-criterion revisited , 2005 .
[29] B. Zhong,et al. Measurement of equivalent diffusivity during the calcination of limestone , 2002 .
[30] Kevin L. McNesby,et al. Modeling of synergistic effects in flame inhibition by 2-H heptafluoropropane blended with sodium bicarbonate , 2003 .
[31] Y. Lwin,et al. Chemical Equilibrium by Gibbs Energy Minimization on Spreadsheets , 2000 .
[32] Renato Baciocchi,et al. Process design and energy requirements for the capture of carbon dioxide from air , 2006 .
[33] T. Shimizu,et al. A twin fluid-bed reactor for removal of CO2 from combustion processes , 1999 .
[34] S. Uchida,et al. Minimum fluidization velocity of binary mixture of particles with large size ratio , 1986 .
[35] S. Hirano,et al. Cyclic Fixed-Bed Operations over K2CO3-on-Carbon for the Recovery of Carbon Dioxide under Moist Conditions , 1995 .
[36] Jyh-Ping Lin,et al. Kinetics of the Reaction of Ca(OH)2 with CO2 at Low Temperature , 1999 .
[37] C. Kim,et al. The effect of surface carbonation on the hydration of CaO , 1990 .
[38] M. Avrami. Kinetics of Phase Change. II Transformation‐Time Relations for Random Distribution of Nuclei , 1940 .
[39] John F. Davidson,et al. The Effects of Repeated Cycles of Calcination and Carbonation on a Variety of Different Limestones, as Measured in a Hot Fluidized Bed of Sand , 2007 .
[40] O. Levenspiel,et al. Drag coefficient and terminal velocity of spherical and nonspherical particles , 1989 .
[41] J. C. Abanades. The maximum capture efficiency of CO2 using a carbonation/calcination cycle of CaO/CaCO3 , 2002 .
[42] Wen-ching Yang. Handbook of Fluidization and Fluid-Particle Systems , 2003 .
[43] J. C. Abanades,et al. Conversion Limits in the Reaction of CO2 with Lime , 2003 .
[44] A. Steinfeld,et al. Thermoneutral Coproduction of Calcium Oxide and Syngas by Combined Decomposition of Calcium Carbonate and Partial Oxidation/CO2-Reforming of Methane , 2003 .
[45] Juan Carlos Abanades,et al. Enhancement of CaO for CO2 capture in an FBC environment , 2003 .
[46] D. Beruto,et al. Liquid-like H2O adsorption layers to catalyze the Ca(OH)2/CO2 solid–gas reaction and to form a non-protective solid product layer at 20°C , 2000 .
[47] A. L. Ortíz,et al. Hydrogen from methane in a single-step process , 1999 .
[48] Y. Matsumoto,et al. Dissolution rate of spherical carbon dioxide bubbles in strong alkaline solutions , 2000 .
[49] Klaus S. Lackner,et al. Carbon dioxide extraction from air: Is it an option? , 1999 .
[50] A. Newkirk,et al. Drying and Decomposition of Sodium Carbonate , 1958 .
[51] John S. Dennis,et al. the effect of CO2 on the kinetics and extent of calcination of limestone and dolomite particles in fluidised beds , 1987 .
[52] Shin-Min Shih,et al. Intrinsic kinetics of the thermal decomposition of sodium bicarbonate , 1993 .
[53] John P. Longwell,et al. Product Layer Diffusion during the Reaction of Calcium Oxide with Carbon Dioxide , 1999 .
[54] M. Constantinescu,et al. Coupled CO2 recovery from the atmosphere and water electrolysis: Feasibility of a new process for hydrogen storage , 1995 .
[55] Xiaoxun Ma,et al. Effect of interparticle adhesion forces on elutriation of fine powders from a fluidized bed of a binary particle mixture , 1998 .
[56] Liang-Shih Fan,et al. Diffusion through CaSO4 formed during the reaction of CaO with SO2 and O2 , 1993 .
[57] David W. Pershing,et al. Mathematical model for the flash calcination of dispersed CaCO3 and Ca(OH)2 particles , 1989 .
[58] David Dollimore,et al. A method of assessing solid state reactivity illustrated by thermal decomposition experiments on sodium bicarbonate , 1995 .
[59] A. Tomita,et al. Calcium catalysed steam gasification of Yallourn brown coal , 1986 .
[60] B. R. Stanmore,et al. Review—calcination and carbonation of limestone during thermal cycling for CO2 sequestration , 2005 .
[61] N. Nakagawa,et al. Minimum Fluidization Velocity of Binary Particle Mixtures with Adhesive Fine Powder , 2002 .
[62] M. C. Kim,et al. Effect of Taylor vortices on calcium carbonate crystallization by gas–liquid reaction , 2003 .
[63] Andrei Chilov. Mass spectrometric study of volatile components in mould powders , 2005 .
[64] Aldo Steinfeld,et al. CO2 capture from atmospheric air via consecutive CaO-carbonation and CaCO3-calcination cycles in a fluidized-bed solar reactor , 2009 .
[65] Douglas P. Harrison,et al. Carbon Dioxide Capture Using Dry Sodium-Based Sorbents , 2004 .
[66] L. Fan,et al. Mechanism of CaO reaction with H2S: Diffusion through CaS product layer , 1999 .
[67] D. D. Perlmutter,et al. Effect of the product layer on the kinetics of the CO2‐lime reaction , 1983 .
[68] Sorption of carbon dioxide by the composite sorbent “potassium carbonate in porous matrix” , 2003 .
[69] Amit Chakma,et al. Separation of CO2 from gas mixtures with liquid membranes , 1992 .
[70] Hae-geon Lee,et al. Decomposition of Na2CO3 by interaction with SiO2 in mold flux of steel continuous casting , 2001 .
[71] G. G. Stokes. "J." , 1890, The New Yale Book of Quotations.
[72] P. V. Danckwerts,et al. Kinetics of CO2 absorption in alkaline solutions—I Transient absorption rates and catalysis by arsenite , 1962 .
[73] P. Fennell,et al. Regeneration of sintered limestone sorbents for the sequestration of CO2 from combustion and other systems , 2007 .
[74] W. Sharp,et al. The System CaO-CO2-H2O in the Two-Phase Region Calcite + Aqueous Solution , 1965, The Journal of Geology.
[75] Mónica Alonso,et al. Reactivity of highly cycled particles of CaO in a carbonation/calcination loop , 2008 .
[76] H. Herzog,et al. Assessing the Feasibility of Capturing CO 2 from the Air , 2003 .
[77] Marco Mazzotti,et al. CO2 capture from air and co-production of H2 via the Ca(OH)2–CaCO3 cycle using concentrated solar power–Thermodynamic analysis , 2006 .
[78] A. Chakma. Separation of CO2 and SO2 from flue gas streams by liquid membranes , 1995 .
[79] Anton Meier,et al. Economic evaluation of the industrial solar production of lime , 2005 .
[80] A. Steinfeld,et al. Feasibility of Na-based thermochemical cycles for the capture of CO2 from air—Thermodynamic and thermogravimetric analyses , 2008 .
[81] G. Cohn. Reactions in the solid state. , 1948, Chemical reviews.
[82] Soo Chool Lee,et al. CO2 Absorption and Regeneration using Na and K Based Sorbents , 2004 .
[83] Gerhart Eigenberger,et al. Detailed modeling of the chemisorption of CO2 into NaOH in a bubble column , 1996 .
[84] S. Hirano,et al. Efficient Recovery of Carbon Dioxide from Flue Gases of Coal-Fired Power Plants by Cyclic Fixed-Bed Operations over K2CO3-on-Carbon , 1998 .
[85] V. Weekman,et al. Chemical Reaction Engineering , 1974 .
[86] Plate efficiency with chemical reaction—absorption of Carbon dioxide in Monoethanolamine solutions , 1956 .
[87] Aldo Steinfeld,et al. A new high-flux solar furnace for high-temperature thermochemical research , 1999 .
[88] Aldo Steinfeld,et al. Solar hydrogen production by thermal decomposition of natural gas using a vortex-flow reactor , 2004 .
[89] M. A. Wilson,et al. Recovery of CO2 from power plant flue gases using amines , 1992 .
[90] Pradyot Patnaik,et al. Handbook of Inorganic Chemicals , 1997 .
[91] J. Ager,et al. Rate coefficient for the gas phase reaction of NaOH with CO2 , 1987 .
[92] Robert Palumbo,et al. Solar Thermochemical Process Technology , 2003 .
[93] Vasilije Manovic,et al. Steam reactivation of spent CaO-based sorbent for multiple CO2 capture cycles. , 2007, Environmental science & technology.
[94] Gary T. Rochelle,et al. Rate modeling of CO2 stripping from potassium carbonate promoted by piperazine , 2009 .
[95] Aldo Steinfeld,et al. Operational Performance of a 5 kW Solar Chemical Reactor for the Co-Production of Zinc and Syngas , 2002 .
[96] Frank Zeman,et al. Energy and material balance of CO2 capture from ambient air. , 2007, Environmental science & technology.
[97] P. Salatino,et al. Attrition of sorbents during fluidized bed calcination and sulphation , 2000 .
[98] J. Lieto,et al. Non-isothermal gas–liquid absorption with chemical reaction studies: Temperature measurements of a spherical laminar film surface and comparison with a model for the CO2/NaOH system , 2001 .
[99] Ryszard Pohorecki,et al. Kinetics of reaction between carbon dioxide and hydroxyl ions in aqueous electrolyte solutions , 1988 .
[100] Arthur M. Squires,et al. Cyclic Calcination and Recarbonation of Calcined Dolomite , 1977 .
[101] R. V. Kumar,et al. Use of NASICON/Na2CO3 system for measuring CO2 , 2000 .
[102] M. Prost,et al. Validation of the gas-lift capillary bubble column as a simulation device for a reactor by the study of CO2 absorption in Na2CO3/NaHCO3 solutions , 1994 .
[103] Syuan-Hong Lin,et al. Hydrogen production from coal by separating carbon dioxide during gasification , 2002 .