Title: Heterogeneous combustion: Recent developments and new opportunities for chemical engineers
Abstract: AIChE JournalVolume 51, Issue 11 p. 2876-2884 Perspective Heterogeneous combustion: Recent developments and new opportunities for chemical engineers Arvind Varma, Corresponding Author Arvind Varma [email protected] School of Chemical Engineering, Purdue University, West Lafayette, IN 47907School of Chemical Engineering, Purdue University, West Lafayette, IN 47907Search for more papers by this authorVictor Diakov, Victor Diakov School of Chemical Engineering, Purdue University, West Lafayette, IN 47907Search for more papers by this authorEvgeny Shafirovich, Evgeny Shafirovich School of Chemical Engineering, Purdue University, West Lafayette, IN 47907Search for more papers by this author Arvind Varma, Corresponding Author Arvind Varma [email protected] School of Chemical Engineering, Purdue University, West Lafayette, IN 47907School of Chemical Engineering, Purdue University, West Lafayette, IN 47907Search for more papers by this authorVictor Diakov, Victor Diakov School of Chemical Engineering, Purdue University, West Lafayette, IN 47907Search for more papers by this authorEvgeny Shafirovich, Evgeny Shafirovich School of Chemical Engineering, Purdue University, West Lafayette, IN 47907Search for more papers by this author First published: 27 September 2005 https://doi.org/10.1002/aic.10697Citations: 12Read the full textAboutPDF ToolsRequest permissionExport citationAdd to favoritesTrack citation ShareShare Give accessShare full text accessShare full-text accessPlease review our Terms and Conditions of Use and check box below to share full-text version of article.I have read and accept the Wiley Online Library Terms and Conditions of UseShareable LinkUse the link below to share a full-text version of this article with your friends and colleagues. Learn more.Copy URL Literature Cited 1 Mohanty KK. The near-term energy challenge. AIChE J. 2003; 49: 2454– 2460. 2 Varma A, Rogachev AS, Mukasyan AS, Hwang S. Combustion synthesis of advanced materials. Advances Chem Eng. 1998; 24: 79– 224. 3 Patil KC, Aruna ST, Mimani T. Combustion synthesis: an update. Curr Opin Solid State Mater Sci. 2002; 6: 507– 512. 4 Merzhanov AG, Borovinskaya IP. Self-propagating high-temperature synthesis of refractory inorganic compounds. Doklady Chemistry. 1972; 204: 429– 432. 5 Varma A, Li B, Mukasyan A. Novel synthesis of orthopaedic implant materials. Advanced Eng Mater. 2002; 4: 482– 486. 6 Castillo M, Ayers R A, Zhang X, Schowengerdt F, Moore JJ. Combustion synthesis of porous glasses and ceramics for bone repair. Biomed Sci Instrum. 2001; 37: 469– 474. 7 Mallard E, Le Chatelier A. Combustion des mélanges gazeux explosives. Annales de Mines. 1883; 4: 274– 381. 8 Varma A, Rogachev AS, Mukasyan AS, Hwang S. Mechanisms of combustion wave propagation in heterogeneous reaction systems. Combust Flame. 1998; 115: 354– 363. 9 Varma A, Rogachev AS, Mukasyan AS, Hwang S. Complex behavior of self-propagating reaction waves in heterogeneous media. Proc Nat Acad Sci USA. 1998; 95: 11053– 11058. 10 Mukasyan AS, Rogachev AS, Mercedes M, Varma A. Microstructural correlations between reaction medium and combustion wave propagation in heterogeneous systems. Chem Eng Sci. 2004; 59: 5099– 5105. 11 Aldushin AP, Khaikin BI. Combustion of mixtures forming condensed reaction products. Combust Explos Shock Waves. 1974; 10: 273– 283. 12 Mukasyan AS, Rogachev AS, Varma A. Mechanisms of reaction wave propagation during combustion synthesis of advanced materials. Chem Eng Sci. 1999; 54: 3357– 3367. 13 Hwang S, Mukasyan AS, Rogachev AS, Varma A. Combustion wave microstructure in gas-solid reaction systems: experiments and theory. Combust Sci Tech. 1997; 123: 165– 184. 14 Varma A, Mukasyan AS, Hwang S. Dynamics of self-propagating reactions in heterogeneous media: experiments and model. Chem Eng Sci. 2001; 56: 1459– 1466. 15 Bayliss A, Matkowsky BJ, Aldushin AP. Dynamics of hot-spots in solid fuel combustion. Physica D. 2002; 166: 104– 130. 16 Grinchuk PS, Rabinovich OS. Effect of random internal structure on combustion of binary powder mixtures. Phys Rev. 2005; E71:026116: 1– 7. 17 Beck JM, Volpert VA. Nonlinear dynamics in a simple model of solid flame microstructure. Physica D. 2003; 182: 86– 102. 18 Beck JM, Volpert VA. A simple model of two-dimensional solid flame microstructure. Combust Theory Modeling. 2003; 7: 795– 812. 19 Prakash AS, Khadar AMA, Patil KC, Hegde MS. Hexamethylenetetramine: a new fuel for solution combustion synthesis of complex metal oxides. J Mater Synthesis Processing. 2002; 10: 135– 141. 20 Aruna ST, Rajam KS. Mixture of fuels approach for the solution combustion synthesis of Al2O3-ZrO2 nanocomposite. Mater Res Bull. 2004; 39: 157– 167. 21 Jung C-H, Jalota S, Bhadiri SB. Quantitative effects of fuel on the synthesis of Ni/NiO particles using a microwave-induced solution combustion synthesis in air atmosphere. Mater Lett. 2005; 59: 2426– 2432. 22 Deshpande K, Mukasyan A, Varma A. Direct synthesis of iron oxide nanopowders by the combustion approach: reaction mechanism and properties. Chem Mater. 2004; 16: 4896– 4904. 23 Erri P, Pranda P, Varma A. Oxidizer-fuel interactions in aqueous combustion synthesis. 1. Iron(III) nitrate-model fuels. Ind Eng Chem Res. 2004; 43: 3092– 3096. 24 Mukasyan AS, Costello C, Sherlock KP, Lafarga D, Varma A. Perovskite membranes by aqueous combustion synthesis: synthesis and properties. Sep Purif Technol. 2001; 25: 117– 126. 25 Agrawal R, Offutt M, Ramage MP. Hydrogen economy - an opportunity for chemical engineers? AIChE J. 2005; 51: 1582– 1589. 26 Schlapbach L, Zuttel A. Hydrogen-storage materials for mobile applications. Nature. 2001; 414: 353– 358. 27 Schlesinger HI, Brown HC, Finholt AE, Gilbreath, JR, Hoekstra HR, Hyde EK. Sodium borohydride, its hydrolysis and its use as a reducing agent and in the generation of hydrogen. J Am Chem Soc. 1953; 75: 215– 219. 28 Amendola SC, Sharp-Goldman SL, Janjua MS, Spencer NC, Kelly MT, Petillo PJ, Binder M. A safe, portable, hydrogen gas generator using aqueous borohydride solution and Ru catalyst. Int J Hydrogen Energy. 2000; 25: 969– 975. 29 Kim J-H, Lee H, Han S-C, Kim, H-S, Song M-S, Lee J-Y. Production of hydrogen from sodium borohydride in alkaline solution: development of catalyst with high performance. Int J Hydrogen Energy. 2004; 29: 263– 267. 30 Larminie J, Dicks A. Fuel Cell Systems Explained. West Sussex: Chichester, UK: Wiley; 2003. 31 Desgardin N, Perut C, Renouard J, U.S. Patent Application 20040065395, European Patent 1405823; 2004. 32 Desgardin N, Perut C, Renouard J. U.S. Patent Application 20040065865, European Patent 1405824; 2004. 33 Delapierre G, Laurent J-Y, Priem T, Bloch D, Marsacq D, Perut C, Gauthier C. U.S. Patent Application 2004067396, European Patent 1344266; 2004. 34 Ivanov VG, Gavrilyuk OV, Glazkov OV, Safronov MN. Specific features of the reaction between ultrafine aluminum and water in a combustion regime. Combust Explos Shock Waves. 2000; 36: 213– 219. 35 Shafirovich E, Diakov V, Varma A. Combustion of novel chemical mixtures for hydrogen generation. Combust Flame, in press. 36 Shafirovich E, Mukasyan AS, Varma A, Kshirsagar G, Zhang Y, Cannon JC. Mechanism of combustion in low-exothermic mixtures of sodium chlorate and metal fuel. Combust Flame. 2002; 128: 133– 144. 37 Weinberg F. Optimizing heat recirculating combustion systems for thermoelectric converters. Combust Flame. 2004; 138: 401– 403. 38 Carbon Sequestration. Technology Roadmap and Program Plan 2005. US DOE, Office of Fossil Energy, National Energy Technology Laboratory. May 2005. Available at: http://www.fe.doe.gov/programs/sequestration/publications/programplans/2005/sequestration_roadmap_2005.pdf. Accessed August 12, 2005. 39 Richter HJ, Knoche K. Reversibility of combustion processes. In: Gaggioli RA, ed. Efficiency and Costing. Second Law Analysis of Processes. ACS Symposium Series 235. Washington DC: ACS, 1983: 71– 85. 40 Ishida M, Jin H. A new advanced power-generation system using chemical-looping combustion. Energy. 1994; 19: 415– 422. 41 Ishida M, Jin H. A novel chemical-looping combustor without NOx formation. Ind Eng Chem Res. 1996; 35: 2469– 2472. 42 Jin H, Ishida M. A new type of coal gas fueled chemical-looping combustion. Fuel. 2004; 83: 2411– 2417. 43 Lyngfelt A, Leckner B, Mattisson T. A fluidized-bed combustion process with inherent CO2 separation; application of chemical-looping combustion. Chem Eng Science. 2001; 56: 3101– 3113. 44 Mattisson T, Johansson M, Lyngfelt A. Multicycle reduction and oxidation of different types of iron oxide particles - Application for chemical-looping combustion. Energy Fuels. 2004; 18: 628– 637. 45 Wolf J, Anheden M, Yan J. Comparison of nickel- and iron-based oxygen carriers in chemical looping combustion for CO2 capture in power generation. Fuel. 2005; 84: 993– 1006. 46 García-Labiano F, de Diego LF, Adánez J, Abad A, Gayán P. Temperature variations in the oxygen carrier particles during their reduction and oxidation in a chemical-looping combustion system. Chem Eng Sci. 2005; 60: 851– 862. 47 Yu J, Corripio AB, Harrison DP, Copeland RJ. Analysis of the sorbent energy transfer system (SETS) for power generation and CO2 capture. Advances in Environ Res. 2003; 7: 335– 345. 48 Contractor RM. Dupont's CFB technology for maleic anhydride. Chem Eng Sci. 1999; 54: 5627– 5632. 49 Yetter RA, Dryer FL. Metal particle combustion and classification. In: Ross HD, ed. Microgravity Combustion : Fire in Free Fall. San Diego: Academic Press, 2001: 419– 478. 50 Williams A, Pourkashanian M, Jones JM, Skorupska N. Combustion and Gasification of Coal. New York: Taylor & Francis; 2000. 51 Frankie BM, Zubrin R. Chemical engineering in extraterrestrial environments. Chem Eng Progress. 1999; 2: 45– 54. 52 Vision for Space Exploration. NASA, 2004. Available at: http://exploration.nasa.gov/documents/documents.html#vision. Accessed August 12, 2005. 53 Miyamoto Y, Kaysser WA, Rabin BH, Kawasaki A, Ford RG. Functionally Graded Materials: Design, Processing and Applications. Boston: Kluwer Academic Pub; 1999. 54 Mukasyan A, Lau C, Varma A. Influence of gravity on combustion synthesis of advanced materials. AIAA J. 2005; 43: 225– 245. 55 Ash RL, Dowler WL, Varsi G. Feasibility of rocket propellant production on mars. Acta Astronautica. 1978; 5: 705– 724. 56 Zubrin RM, Baker D. Humans to Mars in 1999. Aerospace America. 1990; 28(8): 30– 32. 57 Ramohalli K, Lawton E, Ash R. Recent concepts in missions to Mars - extraterrestrial processing. J Propulsion Power. 1989; 5: 181– 187. 58 Sridhar KR. Mars sample return mission with in-situ resource utilization. J Propulsion Power. 1995; 11: 1356– 1362. 59 Yuasa S, Izoda H. Carbon dioxide breathing propulsion for a Mars airplane. AIAA 89-2863, 1989. 60 Shafirovich EYa, Shiryaev AA, Goldshleger UI. Magnesium and carbon dioxide: a rocket propellant for Mars missions. J Propulsion Power. 1993; 9: 197– 203. 61 Shafirovich EYa, Goldshleger UI. Comparison of potential fuels for Martian rockets using CO2. J Propulsion Power. 1997; 13: 395– 397. 62 Valov AE, Gusachenko EI, Shevtsov VI. The effect of CO2 pressure and concentration on the ignition of single Mg particles in CO2-Ar mixtures. Combust Explos Shock Waves. 1992; 28: 7– 10. 63 Legrand B, Shafirovich E, Marion M, Chauveau C, Gökalp I. Ignition and combustion of levitated magnesium particles in carbon dioxide. Proc Combustion Institute. 1998; 27: 2413– 2419. 64 Abbud-Madrid A, Modak A, Branch MC, Daily JW. Combustion of magnesium with carbon dioxide and carbon monoxide at low gravity. J Propulsion Power. 2001; 17: 852– 859 65 Shafirovich E, Salomon M, Gökalp I. Mars hopper versus Mars rover. Acta Astronautica, in press. 66 Mukasyan AS, Lau C, Varma A. Gasless combustion of aluminum particles clad by nickel. Combust Sci Technol. 2001; 170: 67– 85. 67 Shafirovich E, Mukasyan A, Thiers L, Varma A, Legrand B, Chauveau C, Gökalp I. Ignition and combustion of Al particles clad by Ni. Combust Sci Technol. 2002; 174(3): 125– 140. Citing Literature Volume51, Issue11November 2005Pages 2876-2884 ReferencesRelatedInformation
Publication Year: 2005
Publication Date: 2005-09-27
Language: en
Type: article
Indexed In: ['crossref']
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