| 1 - 1 |
Solar chemistry: Part A
Reller A |
| 3 - 13 |
Solar thermochemical conversion of biomass
Lede J |
| 15 - 19 |
Oxidation rates of carbon black particles exposed to concentrated sunlight
Funken KH, Lupfert E, Hermes M, Bruhne K, Pohlmann B |
| 21 - 23 |
Gasification of waste tyre and plastic (PET) by solar thermochemical process for solar energy utilization
Matsunami J, Yoshida S, Yokota O, Nezuka M, Tsuji M, Tamaura Y |
| 25 - 31 |
Application of concentrated solar radiation to high temperature detoxification and recycling processes of hazardous wastes
Funken KH, Pohlmann B, Lupfert E, Dominik R |
| 33 - 41 |
A cone concentrator for high-temperature solar cavity-receivers
Hahm T, Schmidt-Traub H, Lessmann B |
| 43 - 53 |
Design aspects of solar thermochemical engineering - A case study: Two-step water-splitting cycle using the Fe3O4/FeO redox system
Steinfeld A, Sanders S, Palumbo R |
| 55 - 57 |
Solar hydrogen production by using ferrites
Tamaura Y, Ueda Y, Matsunami J, Hasegawa N, Nezuka M, Sano T, Tsuji M |
| 59 - 69 |
Direct solar thermal dissociation of zinc oxide: Condensation and crystallisation of zinc in the presence of oxygen
Weidenkaff A, Steinfeld A, Wokaun A, Auer PO, Eichler B, Reller A |
| 71 - 74 |
Immobilized photosensitizers for solar photochemical applications
Faust D, Funken KH, Horneck G, Milow B, Ortner J, Sattlegger M, Schafer M, Schmitz C |
| 75 - 80 |
The influence of applied bias potential on the photooxidation of methanol and salicylate on titanium dioxide films
Mandelbaum P, Bilmes SA, Regazzoni AE, Blesa MA |
