Hostname: page-component-78c5997874-94fs2 Total loading time: 0 Render date: 2024-11-10T12:32:15.026Z Has data issue: false hasContentIssue false
  • English
  • Français

The Hydrogen Programs in China

Published online by Cambridge University Press:  26 February 2011

Qidong Wang ,
Changpin Chen Yongquan Lei ,
Lixing Chen  and
Xinghua Wang
Qidong Wang
Affiliation:
Department of Materials Science and Engineering, College of Materials Science and Chemical Engineering, Zhejiang University Jade Spring, Hangzhou, Zhejiang China 310027
Changpin Chen Yongquan Lei
Affiliation:
Department of Materials Science and Engineering, College of Materials Science and Chemical Engineering, Zhejiang University Jade Spring, Hangzhou, Zhejiang China 310027
Lixing Chen
Affiliation:
Department of Materials Science and Engineering, College of Materials Science and Chemical Engineering, Zhejiang University Jade Spring, Hangzhou, Zhejiang China 310027
Xinghua Wang
Affiliation:
Department of Materials Science and Engineering, College of Materials Science and Chemical Engineering, Zhejiang University Jade Spring, Hangzhou, Zhejiang China 310027
Get access

Abstract

According to the stages of development, the hydrogen program in China can be divided into four periods since 1978. The chief activities and accomplishments in each period on hydrogen production, hydrogen processing and use of hydrogen in the form of energy are introduced. The work of consciously transforming the present energy system based upon coal-firing power plants and petroleum powered internal combustion engine vehicles into a hydrogen economy system with primary energy mainly based on renewable energies and recycling of biomass and the use of both electricity and hydrogen as energy vectors is just on its start.

Type
Research Article
Information
MRS Online Proceedings Library (OPL) , Volume 801: Symposium BB – Materials and Technologies for a Hydrogen Economy , 2003 , BB1.3
Copyright
Copyright © Materials Research Society 2004

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

REFERENCES

1. Yuan, P. S, Zhou, L.Y., Chang, G‥, Li, D., Power for Factories, (2002,1) 25, 3339. (In Chinese)Google Scholar
2. Chen, C.P., Wu, J. and Wang, Q.D., Rare Earth, 2 (1984) 8–3 ( In Chinese)Google Scholar
3. Wang, Q.D., Wu, J., Chen, C.P., Au, M., and Fang, T.S., Hydrogen Energy Progress VI, Pergamon Press, NY (1986), 872880.Google Scholar
4. Wang, Q.D., Wu, J., Chen, C.P. and Ye, Z., J. Less Common Met. 131,(1987) 321328.Google Scholar
5. Au, M., Chen, C.P., Ye, Z., Fang, T., Wu, J. and Wang, Q.D., Int. J. Hydrogen Energy, 21 (1996) 3337Google Scholar
6. Gao, Y.Z., Chen, G‥, Power for Factories, 85, (1995.4) 4149. (In Chinese)Google Scholar
7. Dong, Z.F., Chang, G, Li, D., Power for Factories, 82, (2000) 2535 (In Chinese)Google Scholar
8. Lei, Y.Q., Li, Z.P., Chen, C.P., Wu, J. and Wang, Q.D., J. Less-Common Met. 172–174 (1991) 12651272 Google Scholar
9. Lei, Y.W., Jiang, J.J., Sun, D.L., Wu, J. and Wang, Q.D., J. Alloys Comp. (1995) 553557.Google Scholar
10. Jiang, L.J., Zhan, F., Bao, D.Y., Qing, G‥R., Li, Y.O. and Wei, X.Y., Energy Storage Materials and Nickel /Metal Hydride Batteries, published by the National High Technology New Energy Storage Materials Center of China, 1996, 6266 ( In Chinese).Google Scholar
11. Lei, Y.Q., Wu, Y.M, Yang, Q.M., Wu, J. and Wang, Q.D., Z. Phy. Chim. 163 (1994) 141147.Google Scholar
12. Zhang, W.K., Hao, J.G., Hao, Y., Duan, W.W. and Li, W.S., Energy Storage Materials and Nickel/Metal Hydride Batteries, 1996, 105.Google Scholar
13. Lei, Y. Q., Yang, X.G., Wu, J. and Wang, Q.D., J. Alloys Comp. 231 (1995) 573577.Google Scholar
14. Wang, Q.D., Wu, J. and Chen, C.P., Z. Phys. Chim. 164 (1989) 12931304.Google Scholar
15. Zhu, G. M., Lei, Y.Q, Wang, Q.D. and Yang, X G., J. Alloys Comp. 253–254 (1997) 590593.Google Scholar
16. Wan, G., Proceedings of Shanghai Fuel Cell Vehicle Forum (2002, Dec. 3–5), Shanghai, China, 3039.Google Scholar
17. Wang, Y., Wu, D., Int. J. of Hydrogen Energy 26 (2001) 795800.Google Scholar
18. Li, Y.X., Lu, G.X., Li, S.B. Applied Catalysis A., General 214 (2001) 179185.Google Scholar
19. Hao, X.H., Guo, L.J., Mao, X., Zhang, X.M., Chen, X.J., Hydrogen Production from Glucose Used as a Model Compound of Biomass Gasification in Supercritical Water, Int. J. Hydrogen Energy (accepted)Google Scholar
20. Ren, N.Q., Chen, S.L., Zhao, D., Control of Fermentation Types in Continuous-Flow Acidogenic Reactors by pH and Redox Potential, J. of Harbin Institute of Technology, 8(2) (2001) 116119.Google Scholar
21. Xie, Z.L., Yang, Z.Q. and Zhao, P. C., Hydrogen Supply in Defense Systems, 14th World Hydrogen Energy Conference, June 9–13 2002, Montreal, Canada.Google Scholar
22. Cheng, H.M., Yang, W.H., Liu, C., Hydrogen Storage in Carbon Nano-tubes, Carbon, 39 (2001) 1147 –1154.Google Scholar
23. Zhu, H. W., Xu, C. L., Mao, Z. Q., Wu, D. J., Pore Structure and Hydrogen Storage of Single–walled carbon Nanotubes, 14th World Hydrogen Energy Conference, June 9–13, Montreal, Canada.Google Scholar
24. Wang, J., Wu, F., Shan, Z. Q., Effect of Addition of Mn and Co on the Hydrogen Storage Characteristics of Microcrystalline Mg, J. Alloys Compds, (accepted)Google Scholar
25. Li, Q., Jian, L. J., Lin, , Zhou, G. Z., Zhan, F., Zhen, Q., Wei, X. Y., The Hydrogen Storage Properties of the Composite Material of Mg+ x wt% Mm(NiCoMnAl)5, Transactions of Nonferrous Metals Society of China (accepted)Google Scholar
26. Yang, H.B., Sun, H., Yang, E.D., Gao, F., Yuan, H.T., Ahou, Z.X. and Guo, S.H., J. of Electrochemical Society 149(5), (2002) A543–A545‥Google Scholar
27. Chen, C. P., Wang, W., O Xu, H. and Chen, Y., Trans. Non-ferrous Metals Soc. Of China, 12 (2002) 1.Google Scholar
28. Cai, G‥M., Chen, C.P., An, Y., Xu, G.H., Chen, L.X. and Wang, Q.D., Journal of Rare Earths 20 (2002) 28 Google Scholar
29. Bjoerklund, Anna, Melaina, A., Keeleian, G‥, Int. J. Hydrogen Energy, 26 (2001) 1209 – 1221Google Scholar
30. Wallman, P. H., Thersness, C. B., Winter, J. D., Energy, 23(4) (1998) 271278.Google Scholar
31. Ni, W.D., Li, Z., Ma, W., Poly-generation Energy System Based on Oxygen-blown Gasification, Proceedings of the International Conference on Power Engineering, Xian, China, Oct 8–12, 2001.Google Scholar
32. Abdul-Resul, M., Baghdadi, S.A., Int. J. Hydrogen Energy, 25 (2000) 1005 – 1009.Google Scholar
33. Petkev, T.I. and Barzev, K.N., Int. J. Hydrogen Energy, 12 (1987) 633–628.Google Scholar