| 683 - 685 |
Novel hydrogen storage systems and materials
Hu YH |
| 686 - 697 |
Hydrogen storage properties of Ti1xScxMnCr Laves phase alloys
Li WH, Wu ED, Ma P, Sun K, Chen DF |
| 698 - 705 |
Effects of reactor design on TiFe-hydride's hydrogen storage
Halicioglu R, Selamet OF, Bayrak M |
| 706 - 712 |
Microstructures and electrochemical properties of Mg49Ti6Ni(45-x)Mx (M=Pd and Pt) alloy electrodes
Nikkuni FR, Santos SF, Ticianelli EA |
| 713 - 719 |
Effects of Different Ti-compounds on the Reversibility of NaAlH4
Rangsunvigit P, Suttisawat Y, Kitiyanan B, Kulprathipanja S |
| 720 - 725 |
Hydrogen storage properties of ball-milled graphite with 0.5wt% Fe
Zhang YH, Book D |
| 726 - 731 |
Hydrogen storage characterization of Mg17Ni1.5Ce0.5/5 wt.% Graphite synthesized by mechanical milling and subsequent microwave sintering
Jiang JJ, Leng HY, Meng J, Chou KC, Li Q |
| 732 - 740 |
Porous organic polymers containing carborane for hydrogen storage
Yuan SW, White D, Mason A, Liu DJ |
| 741 - 745 |
Electric charge and hydrogen storage
Hwang JY, Shi SZ, Sun X, Zhang Z, Wen CY |
| 746 - 753 |
Activated carbon @ MIL-101(Cr): a potential metal-organic framework composite material for hydrogen storage
Rallapalli PBS, Raj MC, Patil DV, Prasanth KP, Somani RS, Bajaj HC |
| 754 - 760 |
Hydrogen storage in hierarchical nanoporous siliconcarbon nanotube architectures
He Z, Wang SC, Wang XQ, Iqbal Z |
| 761 - 768 |
Optimal design of a composite laminate hydrogen storage vessel
Lin DTW, Hsieh JC, Chindakham N, Hai PD |
| 769 - 779 |
A new high-energy density hydrogen carriercarbohydratemight be better than methanol
Zhang YHP, Xu JH, Zhong JJ |
