| 525 - 529 |
Development of new proton exchange membrane electrolytes for water electrolysis at higher temperatures
Linkous CA, Anderson HR, Kopitzke RW, Nelson GL |
| 531 - 544 |
Economics of thermal dissociation of H2S to produce hydrogen
Cox BG, Clarke PF, Pruden BB |
| 545 - 550 |
Prolonged evolution of photohydrogen by intermittent supply of nitrogen using a combined system of Phormidium valderianum, Halobacterium halobium, and Escherichia coli
Bagai R, Madamwar D |
| 551 - 557 |
Catalytic gasification of biomass to produce hydrogen rich gas
Rapagna S, Jand N, Foscolo PU |
| 559 - 563 |
Effect of CO2 removal on hydrogen production by fermentation
Tanisho S, Kuromoto M, Kadokura N |
| 565 - 576 |
An economic analysis of three hydrogen liquefaction systems
Syed MT, Sherif SA, Veziroglu TN, Sheffield JW |
| 577 - 582 |
Fracture mechanical behaviour of the steel 15 MnNi 6 3 in argon and in high pressure hydrogen gas with admixtures of oxygen
Kussmaul K, Deimel P, Fischer H, Sattler E |
| 583 - 591 |
Insulated pressure vessels for hydrogen storage on vehicles
Aceves SM, Berry GD, Rambach GD |
| 593 - 598 |
An overview of industrial uses of hydrogen
Ramachandran R, Menon RK |
| 599 - 602 |
The relationship between equilibrium potential during discharge and hydrogen concentration in a metal hydride electrode
Feng F, Ping XY, Zhou ZQ, Geng MM, Han JW, Northwood DO |
| 603 - 609 |
A hydrogen fuelled internal combustion engine designed for single speed/power operation
Van Blarigan P, Keller JO |
| 611 - 615 |
Fuel cells for mobile applications, status, requirements and future application potential
Donitz W |
| 617 - 620 |
Hydrogen infrastructure for fuel cell transportation
Moore RB, Raman V |
