Tungsten carbides with surface areas ranging from 4 to 39 m 2 g were prepared by the temperature-programmed carburization of tungsten oxide and nitride powders with pure CH 4 or a 48.9% CH 4 in H 2 mixture. Oxygen uptakes on the carbides were low most likely because of the presence of graphitic carbon at the surface. Nevertheless, the carbides were active and selective for the dehydrogenation of butane at temperatures between 623 and 723 K and atmospheric pressure with and without H 2 in the reactant feed. With H 2 in the feed, the higher surface area carbides (⩾ 36 m 2 g ) were as active as a Pt-Sn/γ-Al 2O 3 catalyst, but their selectivities were different. Without H 2 in the feed, the selectivities of the carbides were similar to those of the Pt-Sn/γ-Al 2O 3 catalyst, but their reaction rates were 1-3 orders of magnitude lower. The high surface area materials were also active for the hydrogenolysis of butane. Because the catalytic properties of the carbides varied with the average particle size, we concluded that butane dehydrogenation was structure-sensitive over these materials, and suspected that this behavior was due to variations in the surface stoichiometry as well as the particle faceting.