Журналы →  Materialy Elektronnoi Tekhniki →  2010 →  №4 →  Назад

Nanomaterials and nanotechnology
Название Hydrogen sorption by carbon nanomaterials
Автор A. V. Timonina, D. N. Borisenko, V. V. Kveder, N. N. Kolesnikov, S. K. Brantov
Информация об авторе A. V. Timonina, D. N. Borisenko, V. V. Kveder, N. N. Kolesnikov, S. K. Brantov, ISSP Rus. Acad. Sci.
Реферат
The hydrogen sorption by carbon nanomaterials (CNM) like single-wall and multi-wall nanotubes, nanofibers and thermally split graphite has been investigated at 298 K and pressures of up to 10 MPa. The measurement errors were calculated for the method used. Analysis of the received data has been carried out from the viewpoint of physicochemical adsorption fundamentals.
Ключевые слова Hydrogen sorption, carbon nanotubes, carbon nanofibers.
Библиографический список

1. Hynek, S. Hydrogen storage by carbon sorption / S. Hynek, W. Fuller, J. Bentley // Int. J. Hydrogen Energy. — 1997. — V. 22, N 6. — P. 601—610.
2. Iijima, S. Helical microtubules of graphitic carbon / S. Iijima // Nature. — 1991. — V. 354, N 6348. — P. 56—58.
3. Dillon, A. C. Strage of hydrogen in singl—walled carbon nanotubes / A. C. Dillon, K. M. Jones, T. A. Bekkedahl, C. H. Kiang, D. S. Bethune, M. J. Heben // Lett. Nature. — 1997. — V. 386, N 6623. — P. 377—379.
4. Chambers, A. Hydrogen storage in graphite nanofibers / A. Chambers, C. Park, R. T. K. Baker, N. M. Rodriguez // J. Phys. Chem. B. — 1998. — V. 102. — P. 4253—4256.
5. Park, C. Further Studies of the interaction of hydrogen with graphite nanofibers / C. Park, P. E. Anderson, A. Chambers, C. D. Tan, R. Hidalgo, N. M. Rodriguez // J. Phys. Chem. B. — 1999. — V. 103. — P. 10572—10581.
6. Tibbets, G. G. Hydrogen storage capacity of carbon nanotubes, filaments, and vapor—grown fibers / G. G. Tibbets, G. P. Meisner, C. H. Olk // Carbon. — 2001. — V. 39. — P. 2291—2301.
7. Ahn, C. C. Hydrogen desorption and adsorption measurements on graphite nanofibers / C. C. Ahn, Y. Ye, B. V. Ratnakumar, C. Withman, R. C. Bowman, Jr. and B. Fultz // Appl. Phys. Lett. — 1998. — V. 73, N 23. — P. 3378—3380.
8. Chen, Y. Hydrogen storage in aligned carbon nanotubes / Y. Chen, D. T. Shaw, X. D. Bai, E. G. Wang, C. Lund, W. M. Lu, D. D. L. Chung // Appl. Phys. Lett. — 2001.  — V. 78, N 15. — P. 2128—2130.
9. Hou, P. —X. Hydrogen adsorption/desorption behavior of multi—walled carbon nanotubes with different diameters / P. —X. Hou, S. —T. Xu, Z. Ying, Q. —H. Yang, C. Liu, H.—M. Cheng. // Carbon. — 2003. — V. 41. — P. 2471—2476.

10. Li, X. Hydrogen uptake by graphitized multi—walled carbon nanotubes under moderate pressure and at room temperature / X. Li, H. Zhu, L. Ci, C. Xu, Z. Mao, B. Wei, J.Liang, D. Wu // Carbon. — 2001. — V. 39. — P. 2077—2088.
11. Zhu, H. Hydrogen adsorption in bundles of well—aligned carbon nanotubes at room temperature / H. Zhu, A. Cao, X. Li, C. Xu, Z. Mao, D. Ruan, J.Liang, D. Wu // Apll. Surf. Sci. — 2001. — V. 178. — P. 50—55.
12. Ci, L. Anneling amorphous carbon nanotubes for their application in hydrogen storage / L. Ci, H. Zhu, B. Wei, C. Xu, D. Wu // Appl. Surf. Sci. — 2003. — V. 205. — P. 39—43.
13. Liu, C. Dresselhaus. Hydrogen storage in single—walled carbon nanotubes at room temperature / C. Liu, Y. Y. Fan, M. Liu, H. T. Cong, H. M. Cheng, M. S. Dresselhaus // Science. — 1999. — V. 286. — P. 1127—1129.
14. Ye, Y. Hydrogen adsorption and cohesive of singl—walled carbon nanotubes / Y. Ye, C. C. Ahn, C. Witham, B. Fultz, J. Liu, A. G. Rinzler, D. Colbert, K. A. Smith, R. E. Smalley // Appl. Phys. Lett. — 1999. — V. 74, N 16. — P. 2307—2309.
15. Tarasov, B. P. Hydrogen sorption properties of arc generated single—wall carbon nanotubes / B. P. Tarasov, J. P. Maehlen, M. V. Lototsky, V. E. Muradyan, V. A. Yartys // J. Alloys Comp. — 2003. — V. 256—357. — P. 510—514.
16. Roth, S. Hydrogen storage in carbon nanotubes / S. Roth, X.—H. Chen, Y.—M. Choi, M. Haluska, M. Hulman, A. Quintel, V. Skakalova //Max— Planck—Institute fur Festkorperforchsung, Stuttgart—Grenoble. Report. 2000. — P. 67—79.
17. Hirscher, M. Are carbon nanostructures an efficient hydrogen storage medium? / M. Hirscher, M. Becher, M. Haluska, F. von Zeppelin, X. Chen, U. Dettlaff—Weglikowska, S. Roth // J. Alloys Comp. — 2003. — V. 356—357. — P. 433—437.
18. Chen, P. High H2 Uptake by Alkali—Doped Carbon Nanotubes Under Ambient Pressure and Moderate Temperatures / P. Chen, X. Wu, J. Lin, K. L. Tan. // Science. — 1999. — V. 285. — P. 91—93.
19. Hirscher, M. Hydrogen storage in sonicated carbon materials / M. Hirscher, M. Becher, M. Haluska, U. Dettlaff—Weglikowska, A. Quinte, G.S. Duesberg, Y.—M. Choi, P. Downes, M. Hulman, S. Roth, I. Stepanek, P. Bernier // Appl. Phys. A. — 2001. — V. 72. — P. 129—132.
20. Bashkin, I. O. Termostabil'nye soedineniya vodoroda na baze uglerodnykh nanotrubok i nanovolokon, poluchennye pod vysokim davleniem / I. O. Bashkin, V. E. Antonov, A. V. Bazhenov, I. K. Bdikin, D. N. Borisenko, E. P. Krinichnaya, A. P. Moravskiy, A. I. KHarkunov, YU. M. SHul'ga, YU. A. Osip'yan, E. G. Ponyatovskiy. // Pis'ma v ZHETF. — 2004. — T. 79, vyp. 5. — S. 280—285.
21. Rzepka, M. Physisorption of hydrogen on microporous carbon and carbon nanotubes / M. Rzepka, P. Lamp, M. A. de la Casa—Lillo // J. Phys. Chem. B. — 1998. — V. 102. — P. 10894—10898.
22. Wang, Q. Optimization of nanotube arrays for hydrogen adsorption / Q. Wang, J. K. Johnson // J. Phys. Chem. B. — 1999. — V. 103. — P. 4809—4813.
23. Williams, K. A. Monte Carlo simulations of H2 physisorption in finite—diameter carbon nanotube ropes / K. A. Williams, P. C. Eklund // Chem. Phys. Lett. — 2000. — V. 320. — P.352—358.
24. Wang, Q. Computer simulations of hydrogen adsorption on grafitic nanofibersb / Q. Wang, J. K. Johnson. // J. Phys. Chem. B. — 1999. — V. 103. — P. 277.
25. Ma, Y. Effective hydrogen storage in single—wall carbon nanotubes / Y. Ma, Y. Xia, M. Zhao, R. Wang, L. Mai // Phys. Rev. B. — 2001. — V. 63. — P.115422—6.
26. Tarasov, B. P. Vodorodsoderzhashchie uglerodnye nanostruktury: sintez i svoystva / B. P. Tarasov, N. F. Gol'dshleger, A. P. Moravskiy // Uspekhi khimii. — 2001. — T. 70, № 2. — S. 149—166.
27. Tarasov, B. P. Sorbtsiya vodoroda uglerodnymi nanostrukturami / B. P. Tarasov, N. F. Gol'dshleger // ZH. Al'ternativnaya energetika i ekologiya. — 2002. — № 3. — C. 20—38.
28. Borisenko, D. N. Growth of Carbon Nanotubes (CNTs) in Elektric—Arc Discharge in Argon / D. N. Borisenko, N. N. Kolesnikov, M. P. Kulakov, V. V. Kveder // International Journal of Nanoscience. — 2002. — V. 1, N 3—4. — P. 235—246.
29. Patent № 2220905 RF MPK 6 S 01 V 31/02. Ustroystvo dlya polucheniya uglerodnykh nanotrubok metodom dugovogo razryada // D. N. Borisenko, N. N. Kolesnikov, V. V. Kveder, M. P. Kulakov.
30. Andrews, R. Continuous production of aligned carbon nanotubes: a step closer to commercial realization/ R. Andrews, D. Jacques, A. M. Rao, F. Derbyshire, D. Qian, X. Fan, E. C. Dickey, J. Chen. // Chem. Phys. Lett. — 1999. — V. 303. — P. 467—474.
31. Verhallen, P. T. H. M. The diffusion coefficients of helium, hydrogen, oxygen and nitrogen in water determined from the permeability of a stagnant liquid Lauer in the Quasi—steady state / P. T. H. M. Verhallen, L. J. P. Oomen, A. J. J. M. v. d. Elsen, A. J. Kruger // Chemical Engineering Science. — 1984. — V. 39. — P. 1535—1541.
32. Atsumi, H. Hydrogen bulk retention in graphite and kinetics of diffusion / H. Atsumi // J. Nucl. Mater. — 2002. — V. 307—311. — P. 1466—1470.
33. Atsumi, H. Hydrogen absorption and transport in graphite materials / H. Atsumi, K. Tauchi // J. Alloys Comp. — 2003. V. 356—357. P. 705—709.
34. Ströbel, R. Hydrogen adsorption on carbon materials / R. Ströbel, L. Jörissen, T. Schliermann, V. Trapp, W. Schütz, K. Bohmhammel, G. Wolf, J. Garche. // J. Power Sources. — 1999. — V. 84. — P. 221—224.
35. Etkins, P. Fizicheskaya khimiya. / P. Etkins.— M. : Mir, 1980. — T. 2.
36. Drits, M. E. Svoystva elementov / M. E. Drits, P. B. Budberg, G. S. Burkhanov, A. M. Drits, V. M. Panovko. — M. : Metallurgiya, 1985.
37. Shiraishi, M. Gas—solid interactions in the hydrogen/single—walled carbon nanotube system / M. Shiraishi, T. Takenobu, M. Ata // Chem. Phys. Lett. — 2003. — V. 367. - P. 633—636.

Language of full-text русский
Полный текст статьи Получить
Назад