Ordered mesoporous carbide derived carbons for high pressure gas storage

Carbon

Volumn 48, Issue 6, 2010, Pages 1707-1717

  Kockrick, Emanuel ^a,b   Schrage, Christian ^a   Borchardt, Lars ^a   Klein, Nicole ^a   Rose, Marcus ^a   Senkovska, Irena ^a   Kaskel, Stefan ^a  

^a DRESDEN UNIVERSITY OF TECHNOLOGY   (Germany)

^b UNIVERSITÉ LYON 1   (France)

Author keywords

[No Author keywords available]

Indexed keywords

ADSORPTION KINETICS; ADSORPTION PROPERTIES; BIMODAL PORE SIZE DISTRIBUTION; CARBIDE DERIVED CARBON; ENERGY STORAGE SYSTEMS; GAS STORAGE; HIGH PRESSURE GAS; HIGH PRESSURE HYDROGEN; HIGH SPECIFIC SURFACE AREA; HYDROGEN TREATMENTS; MESOPOROUS; MESOSTRUCTURED; METHANE ADSORPTION; MOBILE APPLICATIONS; N-BUTANE; ORDERED MESOPOROUS; POROUS CARBONS; REFERENCE MATERIAL; SILICON CARBIDE CERAMIC; SMALL ANGLE X-RAY SCATTERING; STORAGE CAPACITY; SYNTHESIS CONDITIONS;

BUTANE; CHLORINATION; DESIGN; HIGH PRESSURE ENGINEERING; LIQUEFIED PETROLEUM GAS; MESOPOROUS MATERIALS; METHANE; PHYSISORPTION; PORE SIZE; SILICON CARBIDE; SYNTHESIS (CHEMICAL);

HYDROGEN STORAGE;

EID: 77249119660     PISSN: 00086223     EISSN: None     Source Type: Journal    
DOI: 10.1016/j.carbon.2010.01.004     Document Type: Article

References (57)

1. Davis M.E. Ordered porous materials for emerging applications. Nature 417 6891 (2002) 813-821
2. Arico A.S., Bruce P., Scrosati B., Tarascon J.M., and Van Schalkwijk W. Nanostructured materials for advanced energy conversion and storage devices. Nat Mater 4 5 (2005) 366-377
3. Schlapbach L., and Zuttel A. Hydrogen-storage materials for mobile applications. Nature 414 6861 (2001) 353-358
4. Eberle U., Felderhoff M., and Schueth F. Chemical and physical solutions for hydrogen storage. Angew Chem Int Ed 48 36 (2009) 6608-6630
5. Senkovska I., and Kaskel S. High pressure methane adsorption in the metal-organic frameworks. Micropor Mesopor Mater 112 (2008) 108-115
6. Cracknell R.F., Gordon P., and Gubbins K.E. Influence of pore geometry on the design of microporous materials for methane storage. J Phys Chem 97 2 (1993) 494-499
7. Alcaniz-Monge J., de la Casa-Lillo M.A., Cazorla-Amoros D., and Linares-Solano A. Methane storage in activated carbon fibres. Carbon 35 2 (1997) 291-297
8. Eddaoudi M., Kim J., Rosi N., Vodak D., Wachter J., O'Keeffe M., et al. Systematic design of pore size and functionality in isoreticular MOFs and their application in methane storage. Science 295 5554 (2002) 469-472
9. Zhang S.Y., Talu O., and Hayhurst D.T. High-pressure adsorption of methane in Nax, Mgx, Cax, Srx, and Bax. J Phys Chem 95 4 (1991) 1722-1726
10. Celzard A., and Fierro V. Preparing a suitable material designed for methane storage: a comprehensive report. Energy Fuel 19 2 (2005) 573-583
11. Feaver A., and Cao G.Z. Activated carbon cryogels for low pressure methane storage. Carbon 44 3 (2006) 590-593
12. Menon V.C., and Komarneni S. Porous adsorbents for vehicular natural gas storage: a review. J Porous Mater 5 1 (1998) 43-58
13. Kowalczyk P., Solarz L., Do D.D., Samborski A., and MacElroy J.M.D. Nanoscale tubular vessels for storage of methane at ambient temperatures. Langmuir 22 21 (2006) 9035-9040
14. Yang C.M., Noguchi H., Murata K., Yudasaka M., Hashimoto A., Iijima S., et al. Highly ultramicroporous single-walled carbon nanohorn assemblies. Adv Mater 17 7 (2005) 866-870
15. Noro S., Kitagawa S., Kondo M., and Seki K. A new, methane adsorbent, porous coordination polymer [{CuSiF6(4,4 '-bipyridine)(2)}(n)]. Angew Chem Int Ed 39 12 (2000) 2082-2084
16. Ma S.Q., Sun D.F., Simmons J.M., Collier C.D., Yuan D.Q., and Zhou H.C. Metal-organic framework from an anthracene derivative containing nanoscopic cages exhibiting high methane uptake. J Am Chem Soc 130 3 (2008) 1012-1016
17. Wang X.S., Ma S.Q., Rauch K., Simmons J.M., Yuan D.Q., Wang X.P., et al. Metal-organic frameworks based on double-bond-coupled di-isophthalate linkers with high hydrogen and methane uptakes. Chem Mater 20 9 (2008) 3145-3152
18. Seki K. Design of an adsorbent with an ideal pore structure for methane adsorption using metal complexes. Chem Commun 16 (2001) 1496-1497
19. Millward A.R., and Yaghi O.M. Metal-organic frameworks with exceptionally high capacity for storage of carbon dioxide at room temperature. J Am Chem Soc 127 51 (2005) 17998-17999
20. Mueller U., Schubert M., Teich F., Puetter H., Schierle-Arndt K., and Pastre J. Metal-organic frameworks - prospective industrial applications. J Mater Chem 16 7 (2006) 626-636
21. Panella B., Hirscher M., Putter H., and Muller U. Hydrogen adsorption in metal-organic frameworks: Cu-MOFs and Zn-MOFs compared. Adv Funct Mater 16 4 (2006) 520-524
22. Dash R., Chmiola J., Yushin G., Gogotsi Y., Laudisio G., Singer J., et al. Titanium carbide derived nanoporous carbon for energy-related applications. Carbon 44 12 (2006) 2489-2497
23. Yeon S.H., Osswald S., Gogotsi Y., Singer J.P., Simmons J.M., Fischer J.E., et al. Enhanced methane storage of chemically and physically activated carbide-derived carbon. J Power Sources 191 2 (2009) 560-567
24. Gogotsi Y., Nikitin A., Ye H.H., Zhou W., Fischer J.E., Bo Y., et al. Nanoporous carbide-derived carbon with tunable pore size. Nat Mater 2 9 (2003) 591-594
25. Gogotsi Y., Dash R.K., Yushin G., Yildirim T., Laudisio G., and Fischer J.E. Tailoring of nanoscale porosity in carbide-derived carbons for hydrogen storage. J Am Chem Soc 127 46 (2005) 16006-16007
26. Dash R.K., Yushin G., and Gogotsi Y. Synthesis, structure and porosity analysis of microporous mesoporous carbon derived from zirconium carbide. Micropor Mesopor Mater 86 1-3 (2005) 50-57
27. Chmiola J., Yushin G., Dash R., and Gogotsi Y. Effect of pore size and surface area of carbide derived carbons on specific capacitance. J Power Sources 158 1 (2006) 765-772
28. Rose M., Kockrick E., Senkovska I., and Kaskel S. High surface area carbide-derived carbon fibers produced by electrospinning of polycarbosilane precursors. Carbon 48 2 (2010) 403-407
29. Yushin G., Dash R., Jagiello J., Fischer J.E., and Gogotsi Y. Carbide-derived carbons: effect of pore size on hydrogen uptake and heat of adsorption. Adv Funct Mater 16 17 (2006) 2288-2293
30. Xia K.S., Gao Q.M., Wu C.D., Song S.Q., and Ruan M.L. Activation, characterization and hydrogen storage properties of the mesoporous carbon CMK-3. Carbon 45 10 (2007) 1989-1996
31. Chmiola J., Yushin G., Gogotsi Y., Portet C., Simon P., and Taberna P.L. Anomalous increase in carbon capacitance at pore sizes less than 1 nanometer. Science 313 5794 (2006) 1760-1763
32. Chmiola J., Largeot C., Taberna P.L., Simon P., and Gogotsi Y. Desolvation of ions in subnanometer pores and its effect on capacitance and double-layer theory. Angew Chem Int Ed 47 18 (2008) 3392-3395
33. Largeot C., Portet C., Chmiola J., Taberna P.L., Gogotsi Y., and Simon P. Relation between the ion size and pore size for an electric double-layer capacitor. J Am Chem Soc 130 9 (2008) 2730-2731
34. Simon P., and Gogotsi Y. Materials for electrochemical capacitors. Nat Mater 7 11 (2008) 845-854
35. Krawiec P., Kockrick E., Borchardt L., Geiger D., Corma A., and Kaskel S. Ordered mesoporous carbide derived carbons: novel materials for catalysis and adsorption. J Phys Chem C 113 18 (2009) 7755-7761
36. Lu A.H., and Schueth F. Nanocasting: a versatile strategy for creating nanostructured porous materials. Adv Mater 18 14 (2006) 1793-1805
37. Krawiec P., Geiger D., and Kaskel S. Ordered mesoporous silicon carbide (OM-SiC) via polymer precursor nanocasting. Chem Commun 23 (2006) 2469-2470
38. Shi Y.F., Meng Y., Chen D.H., Cheng S.J., Chen P., Yang T.F., et al. Highly ordered mesoporous silicon carbide ceramics with large surface areas and high stability. Adv Funct Mater 16 4 (2006) 561-567
39. Krawiec P., Schrage C., Kockrick E., and Kaskel S. Tubular and rodlike ordered mesoporous silicon (oxy)carbide ceramics and their structural transformations. Chem Mater 20 (2008) 5421-5433
40. Jun S., Joo S.H., Ryoo R., Kruk M., Jaroniec M., Liu Z., et al. Synthesis of new, nanoporous carbon with hexagonally ordered mesostructure. J Am Chem Soc 122 43 (2000) 10712-10713
41. Gibaud A., Xue J.S., and Dahn J.R. A small angle X-ray scattering study of carbons made from pyrolyzed sugar. Carbon 34 4 (1996) 499-503
42. Yeon S.H., Reddington P., Gogotsi Y., Fischer J.E., Vakifahmetoglu C., and Colombo P. Carbide-derived-carbons with hierarchical porosity from a preceramic polymer. Carbon 48 1 (2010) 201-210
43. 2/silicon oxycarbide catalysts. J Mater Chem 19 11 (2009) 1543-1553
44. Lindner P., and Zemb T. Neutron, X-ray and light scattering: introduction to an investigative tool for colloidal and polymeric systems. North-Holland Delta Series (1991) 200-205
45. Kalliat M., Kwak C.Y., and Schmidt P.W. New approaches in coal chemistry (1981), American Chemical Society, Washington, DC
46. Laudisio G., Dash R.K., Singer J.P., Yushin G., Gogotsi Y., and Fischer J.E. Carbide-derived carbons: a comparative study of porosity based on small-angle scattering and adsorption isotherms. Langmuir 22 21 (2006) 8945-8950
47. Kusgens P., Rose M., Senkovska I., Frode H., Henschel A., Siegle S., et al. Characterization of metal-organic frameworks by water adsorption. Micropor Mesopor Mater 120 3 (2009) 325-330
48. Muller E.A., and Gubbins K.E. Molecular simulation study of hydrophilic and hydrophobic behavior of activated carbon surfaces. Carbon 36 10 (1998) 1433-1438
49. Rose M., Bohlmann W., Sabo M., and Kaskel S. Element-organic frameworks with high permanent porosity. Chem Commun 21 (2008) 2462-2464
50. Fuertes A.B., Marban G., and Nevskaia D.M. Adsorption of volatile organic compounds by means of activated carbon fibre-based monoliths. Carbon 41 1 (2003) 87-96
51. Saha B.B., Chakraborty A., Koyama S., Yoon S.H., Mochida I., Kumja M., et al. Isotherms and thermodynamics for the adsorption of n-butane on pitch based activated carbon. Int J Heat Mass Trans 51 7-8 (2008) 1582-1589
52. Walton K.S., Cavalcante C.L., and Levan M.D. Adsorption equilibrium of alkanes on a high surface area activated carbon prepared from Brazilian coconut shells. Adsorption 11 2 (2005) 107-111
53. Klein N., Henschel A., and Kaskel S. N-Butane adsorption on Cu3(btc)2 and MIL-101. Micropor Mesopor Mater 129 1-2 (2010) 238-242
54. Tan Z.M., and Gubbins K.E. Adsorption in carbon micropores at supercritical temperatures. J Phys Chem 94 15 (1990) 6061-6069
55. Matranga K.R., Myers A.L., and Glandt E.D. Storage of natural-gas by adsorption on activated carbon. Chem Eng Sci 47 7 (1992) 1569-1579
56. Lozano-Castello D., Alcaniz-Monge J., de la Casa-Lillo M.A., Cazorla-Amoros D., and Linares-Solano A. Advances in the study of methane storage in porous carbonaceous materials. Fuel 81 14 (2002) 1777-1803
57. Klein N., Senkovska I., Gedrich K., Stoeck U., Henschel A., Mueller U., et al. A mesoporous metal-organic framework. Angew Chem Int Ed 48 52 (2009) 9954-9957