Changes on texture and crystalline phase of activated carbon-supported NI-Ca catalyst during dry methane reforming

Open Materials Science Journal

Volumn 4, Issue , 2010, Pages 125-132

  Matos, Juan ^a   Rosales, Maibelin ^a   González, Gema ^a   de Navarro, Caribay Urbina ^b  

^a INSTITUTO VENEZOLANO DE INVESTIGACIONES CIENTÍFICAS   (Venezuela)

^b UNIVERSIDAD CENTRAL DE VENEZUELA   (Venezuela)

Author keywords

Activation; Carbon deposits; Dry methane reforming; Ni based catalyst

Indexed keywords

ACTIVATED CARBON; CALCIUM; CARBON DIOXIDE; CATALYSTS; CHEMICAL ACTIVATION; CRYSTALLINE MATERIALS; DEPOSITS; METHANE; MICROPOROSITY; MULTIWALLED CARBON NANOTUBES (MWCN); NANOPARTICLES; NICKEL; REFORMING REACTIONS; X RAY PHOTOELECTRON SPECTROSCOPY; YARN;

ACTIVATED CARBON SUPPORTED; CARBON DEPOSITES; DRY-METHANE REFORMING; EXPERIMENTAL CONDITIONS; HOMOGENEOUS DISTRIBUTION; INTERLAYER SEPARATION; MICROPOROUS CARBON STRUCTURES; NI-BASED CATALYST;

CATALYST SUPPORTS;

EID: 79960066877     PISSN: None     EISSN: 1874088X     Source Type: Journal    
DOI: 10.2174/1874088X01004010125     Document Type: Article

References (28)

1. Tomishige K. Syngas production from methane reforming with CO2/H2O and O2 over NiO-MgO solid solution catalyst in fluidized bed reactors. Catal Today 2004; 89: 405-18.
2. Bradford MCJ, Vannice MA. CO2 reforming of CH4. Catal Rev Sci Engin 1999; 41: 1-42.
3. Bradford MCJ, Vannice MA. Catalytic reforming of methane with carbon dioxide over nickel catalysts. Catalyst characterization and activity. Appl Catal A Gen 1996; 142: 73-96.
4. Rostrup-Nielsen JR, Hansen JHB. CO2 reforming of methane over transition metals. J Catal 1993; 144: 38-49.
5. Slagterm A, Schuurman A, Leclercq C, et al. Specific features concerning the mechanism of methane reforming by carbon dioxide over Ni/La2O3 catalyst. J Catal 1997; 172: 118-26.
6. Frusteri F, Spadaro L, Arena F, et al. TEM evidence for factors affecting the genesis of carbon species on bare and K-promoted Ni/MgO catalysts during the dry reforming of methane. Carbon 2002; 40: 1063-70.
7. Bai Z, Chen H, Li B, et al. Methane decomposition over Ni loaded activated carbon for hydrogen production and the formation of filamentous carbon. Inter J Hydrogen Energy 2007 32 32-7
8. Matos J, Brito JL, Laine J. Activated carbon supported Ni-Mo: Effects of pretreatments and composition on catalyst reducibility and on ethylene conversion. Appl Catal A Gen 1997; 152:27-42
9. Matos J, Laine J Ethylene conversion on activated carbon supported NiMo catalysts: Effect of the support Appl Catal A Gen 2003; 241: 25-38.
10. Matos J, Díaz K, García V, et al. Methane transformation in presence of carbon dioxide on activated carbon supported nickel- calcium catalysts. Catal Lett 2006; 109: 163-9.
11. Díaz K, García V, Matos J. Activated carbon supported Ni-Ca: Influence of reaction parameters on activity and stability of catalyst on methane reformation. Fuel 2007; 86: 1337-44.
12. Li Y, Zhang B, Xie X, et al. Novel Ni catalysts for methane decomposition to hydrogen and carbon nanofibers. J Catal 2006; 238: 412-24.
13. Li Y, Chen J, Chang L, et al. The doping effect of copper on the catalytic growth of carbon fibers from methane over a Ni/Al2O3 catalyst prepared from Feitknecht compound precursor. J Catal 1998; 178: 76-83.
14. Harkins WD, Jura G. Surfaces of solids. XIII. A vapor adsorption method for the determination of the area of a solid without the assumption of a molecular area, and the areas occupied by Nitrogen and other molecules on the surface of a solid. J Am Chem Soc 1944; 66: 1366-73.
15. Labib ME, Williams R. The use of zeta-potential measurements in organic solvents to determine the donor-acceptor properties of solid surfaces. J Colloids Interface Sci 1984; 97: 356-66.
16. Kroll VCH, Delichure P, Mirodatos C. Methane reforming reaction with carbon dioxide over a Ni/SiO2 catalyst: The nature of the active phase. Kinet Catal 1996; 37: 698-705.
17. Resasco DE. Single Walled Carbon Nanotubes. Large-scale production and commercial applications. J Nanopart Res 2002; 4: 131-6.
18. Wigmans T. Industrial aspects of production and use of activated carbons. Carbon 1989; 27: 13-22.
19. Matos J, Labady M, Albornoz A, et al. Topological organization and textural changes of carbon macro-networks submitted to activation with N2 and CO2. J Mater Sci 2004; 39: 3705-16.
20. Song Q, Xiao R, Li Y, et al. Catalytic carbon dioxide reforming of methane to synthesis gas over activated carbon catalyst. Ind Eng Chem Res 2008; 47: 4349-57.
21. Ramirez S, Ferreira D, Gottberg V, et al. Adding a micropore framework to a parent activated carbon by carbon deposition from methane or ethylene. Carbon 2003; 41: 2653-5.
22. Albornoz A, Labady M, López M, et al. Evidence for the formation of slit mesopores in activated carbon. J Mater Sci Lett 2000; 18: 1999-2000.
23. Krasil'nikova OK, Voloshchuk AM, Evsyukhin AE, et al. Preparation of ultramicro-, micro-, and supermicroporous carbon adsorbents by template procedure. Colloid J 2006; 68: 182-8.
24. Méndez MOA, Lisbôa ACL, Coutinho AR, et al. Activated petroleum coke for natural gas storage. J Braz Chem Soc 2006; 17: 1144-50.
25. Imasaka K, Kanatake Y, Ohshiro Y, et al. Production of carbon nanoonions and nanotubes using an intermittent arc discharge in water. Thin Solid Films 2006; 506-7: 250-4.
26. Baker RTK, Barber MA, Harris PS, et al. Nucleation and growth of carbon deposits from the nickel catalyzed decomposition of acetylene. J Catal 1972; 26: 51-62.
27. Snoeck JW, Froment GF, Fowles M. Steam/CO2 reforming of methane. Carbon Filament formation by the Boudouard reaction and gasification by CO2, by H2, and by steam. Ind Eng Chem Res 2002; 41: 4252-65.
28. Gronchi P, Fumagalli D, Del Rosso R, et al. Carbon deposition in methane reforming with carbón dioxide. J Thermal Anal Calor 1996; 47: 227-34