A new oxy-fuel H-2 generation process with CO2 avoidance is provided. The process utilizes mass recirculation of CO and H2O to the oxyforming reactor. A comparison between non-recirculating and mass-recirculating oxyforming reactor operation is given. Main benefits of mass recirculation are emphasized. The oxyforming reactor is integrated with the H-2 and CO2 separators, fuel cell and O-2 generator. In the process C/O is equal to 0.5 while C/H determines the temperature level in the reactor. The reaction system includes combustion, steam reforming and water gas shift reactions. The oxyforming process is found to be mass transport controlled with O-2 as the limiting reactant. It is emphasized that under MR conditions the decomposition of H-2/CO2 by water gas shift reaction is suppressed by means of CO/H2O-enrichment and hence MR conditions allow for higher temperatures beneficial to endothermic steam reforming reaction. Under MR conditions the thermodynamic equilibrium limits are overcome and all reactions are forced to proceed to the completion which enables 100% selectivities to H-2 and CO2. The effects of operation parameters such as temperature, flow rate, pressure and composition are examined. The derived S-terms enable for the concise interpretation of the effect of pressure on the concentration gradients transverse to the flow. The consistent control algorithm of the oxyforming reactor is provided. (C) 2010 Professor T. Nejat Veziroglu. Published by Elsevier Ltd. All rights reserved.