| 431 - 439 |
Future hydrogen markets for large-scale hydrogen production systems
Forsberg CW |
| 440 - 450 |
Progress in high-temperature electrolysis for hydrogen production using planar SOFC technology
Herring JS, O'Brien JE, Stoots CM, Hawkes GL, Hartvigsen JJ, Shahnam M |
| 451 - 456 |
Hydrogen production by water dissociation using mixed conducting dense ceramic membranes
Balachandran U, Lee TH, Dorris SE |
| 457 - 462 |
Membrane processes for the sulfur-iodine thermochemical cycle
Stewart FF, Orme CJ, Jones MG |
| 463 - 468 |
Electrochemical hydrogen production from thermochemical cycles using a proton exchange membrane electrolyzer
Sivasubramanian P, Ramasamy RP, Freire FJ, Holland CE, Weidner JW |
| 469 - 481 |
Hydrogen/methanol production by sulfur-iodine thermochemical cycle powered by combined solar/fossil energy
Giaconia A, Grena R, Lanchi M, Liberatore R, Tarquini P |
| 482 - 488 |
Stability of supported platinum sulfuric acid decomposition catalysts for use in thermochemical water splitting cycles
Ginosar DM, Petkovic LM, Glenn AW, Burch KC |
| 489 - 496 |
Flowsheet study of the thermochemical water-splitting iodine-sulfur process for effective hydrogen production
Kasahara S, Kubo S, Hino R, Onuki K, Nomura M, Nakao S |
| 497 - 504 |
Construction materials development in sulfur-iodine thermochemical water-splitting process for hydrogen production
Wong B, Buckingham RT, Brown LC, Russ BE, Besenbruch GE, Kaiparambil A, Santhanakrishnan R, Roy A |
| 505 - 509 |
A novel method for producing hydrogen based on the Ca-Br cycle
Simpson MF, Utgikar V, Sachdev P, McGrady C |
