Dehydrogenation kinetics of Ti-doped NaAlH4-Influence of Ti precursors and preparation methods

International Journal of Hydrogen Energy

Volumn 33, Issue 2, 2008, Pages 718-721

  Onkawa, M ^a,b   Zhang, S ^a   Takeshita, H T ^b   Kuriyama, N ^a   Kiyobayashi, T ^a  

^a NATIONAL INSTITUTE OF ADVANCED INDUSTRIAL SCIENCE AND TECHNOLOGY AIST   (Japan)

^b KANSAI UNIVERSITY   (Japan)

Author keywords

Desorption kinetics; Hydrogen storage; Sodium aluminum hydride

Indexed keywords

DEHYDROGENATION; DOPING (ADDITIVES); HYDROGEN STORAGE; MELTING POINT; PARTICLE SIZE; TITANIUM;

DESORPTION KINETICS; PHASE DISTRIBUTION; SODIUM ALUMINUM HYDRIDE;

SODIUM COMPOUNDS;

EID: 38849176184     PISSN: 03603199     EISSN: None     Source Type: Journal    
DOI: 10.1016/j.ijhydene.2007.10.002     Document Type: Article

References (24)

1. Bogdanović B., and Schwickardi M. Ti-doped alkali metal aluminium hydrides as potential novel reversible hydrogen storage materials. J Alloys Compd 253-254 (1997) 1-9
2. Bogdanović B., Brand R.A., Marjanović A., Schwickardi M., and Tölle J. Metal-doped sodium aluminium hydrides as potential new hydrogen storage materials. J Alloys Compd 302 (2000) 36-58
3. 4 as a hydrogen-storage material-preparation by Ti-catalyzed hydrogenation of aluminum powder in conjunction with sodium hydride. Appl Phys A 72 (2001) 221-223
4. Jensen C.M., Zidan R., Mariels N., Hee A., and Hagen C. Advanced titanium doping of sodium aluminum hydride: segue to a practical hydrogen storage material?. Int J Hydrogen Energy 24 (1999) 461-465
5. Zidan R.A., Takara S., Hee A.G., and Jensen C.M. Hydrogen cycling behavior of zirconium and titanium-zirconium-doped sodium aluminum hydride. J Alloys Compd 285 (1999) 119-122
6. 4. J Alloys Compd 297 (2000) 270-281
7. 3 - in lithium aluminohydride. R Soc Chem Chem Commun (2000) 1665-1666
8. Jensen C.M., and Gross K.J. Development of catalytically enhanced sodium aluminium hydride as a hydrogen-storage material. Appl Phys A 72 (2001) 213-219
9. Sandrock G., Gross K., Thomas G., Jensen C.M., Meerker D., and Takara S. Engineering considerations in the use of catalyzed sodium alanates for hydrogen storage. J Alloys Compd 330-332 (2002) 696-701
10. Sandrock G., Gross K., and Thomas G. Effect of Ti-catalyst content on the reversible hydrogen storage properties of the sodium alanates. J Alloys Compd 339 (2002) 299-308
11. 4. J Alloys Compd 330-332 (2002) 702-707
12. Felderhoff M., Klementiev K., Grünert W., Spliethoff B., Tesche B., Bellosta von Colbe J.M., et al. Combined TEM-EDX and XAFS studies of Ti-doped sodium alanate. Phys Chem Chem Phys 6 (2004) 4369-4374
13. 4 containing Ti additives. J Alloys Compd 376 (2004) 215-221
14. 4. J Phys Chem B 109 (2005) 15780-15785
15. Balema V.P., and Balema L. Missing pieces of the puzzle or about some unresolved issues in solid state chemistry of alkali metal aluminohydrides. Phys Chem Chem Phys 7 (2005) 1310-1314
16. 6. J Phys Chem A 107 (2003) 7671-7674
17. 4 catalyzed in different decomposition states. J Appl Phys 95 (2004) 7748-7753
18. 4 doped with a Ti-based catalyst. J Alloys Compd 404-406 (2005) 339-342
19. Zhang S., Taniguchi A., Xu Q., Takeichi N., Takeshita H.T., Kuriyama N., et al. Understanding the effect of titanium species on the decomposition of alanates in homogeneous solution. J Alloys Compd 413 (2006) 218-221
20. Bogdanović B., Eberle U., Felderhoff M., and Schüth F. Complex aluminum hydrides. Scr Materialia 56 (2007) 813-816
21. Galway AK, Brown, ME. Thermal decomposition of ionic solids, studies in physical and theoretical chemistry, vol 86. Amsterdam: Elsevier; 1999. ISBN: 0-444-82437-5.
22. L'vov B.V. The physical approach to the interpretation of the kinetics and mechanisms of thermal decomposition of solids: the state of the art. Thermochim Acta 373 2 (2001) 97-124
23. Meisner G.P., Tibbetts G.G., Pinkerton F.E., Olk C.H., and Balogh M. Enhancing low pressure hydrogen storage in sodium alanates. J Alloys Compd 337 (2002) 254-263
24. Gross KJ, Luo W, Majzoub E, Roberts G, Spangler S, Dedrick D, et al. Hydride development for hydrogen storage. In: Hydrogen, fuel cells, and infrastructure technologies FY 2003 Progress Report, US DOE, 2003.