ZrO2-supported tungsten oxides were used for cyclic production of syngas and hydrogen by methane reforming (reduction) and water splitting (re-oxidation). The reduction characteristics of WO3 to WO2 and WO2 to W were examined at various temperatures (1073-1273 K) and reaction times. Significant portions of the tungsten oxides were also reduced by the produced H-2 and CO. The extent of reduction by H-2 varied greatly depending on temperature and WO3 content and also on the reduction of either WO3 or WO2, while that by CO was consistently low. When the overall degree of reduction became sufficiently high, methane decomposition started to proceed rapidly, resulting in considerable carbon deposition and H-2 production. Consequently, the H-2/(CO + CO2) ratio varied from around 1 to higher than 2. During the repeated cyclic operations with a proper reduction time at a given temperature, the syngas and hydrogen yields decreased gradually while the H-2/(CO + CO2) ratio remained nearly constant and the carbon deposition was negligible. Copyright (C) 2013, Hydrogen Energy Publications, LLC. Published by Elsevier Ltd. All rights reserved.