Effects of reaction conditions on the production of alcohols (AOHs) and alkanes (Alk) from CO and H2, which can be obtained from the gasification of biomass, using molybdenum (Mo) based catalysts such as molybdenum sulfide (MoS2), molybdenum carbides (β-Mo2C) and potassium and vanadium modified β-Mo2C of K-Mo2C, V-Mo2C and V-K-Mo2C were studied. A high-pressure fixed packed bed (HPFPB) was employed to carry out the reaction. The results indicate that the conversion of CO (XCO, in C%) and specific production rates of alcohol (SPRAOH) and alkane (SPRAlk) (g h-1 gcat-1) are highly dependent on temperature (T). In T = 423–573 K, maximum yield of alcohols (YAOH, in C%) of 5.0% and SPRAOH of 7.9 mg h-1 gcat-1 occur at T = 523 K over MoS2 catalyst. In the meantime, well performance gives the selectivity of ethanol (SEtOH) of 52.0 C%. For the studies on varying H2/CO mole ratio (MH/C) from 1 to 4 at 523 K, the appropriate MH/C to produce EtOH is 2, giving higher ratios of SPRAOH/SPRAlk of 2.08 and YAOH/YAlk of 2.50 than those with other MH/C. As for varying the total gas flow rates (QG) of 300, 450, 600 to 900 cm3 min−1 tested at T = 523 K and MH/C = 2, the lower QG provides longer reaction time (or gaseous retention time, tR) thus offering higher XCO, however lower productivity. For setting pressure (PST) = 225–540 psi, a supply of higher pressure is equivalent to providing a larger amount of reactants into the reaction system. This thus suggests that the use of higher PST whould give both higher XCO and productivity. Effects of modification of β-Mo2C catalyst using potassium (K) and vanadium (V) on AOHs and Alks from the hydrogenation of CO were studied. Both K and V promoters show the effectiveness on the XCO, SPRAOH, (g gcat-1 h-1), and SAOH (in C%). At the K/Mo weight ratio of 0.52, the contributions of XCO and YAOH are as high as 28.8% and 18.1%, respectively. At the V/Mo weight ratio of 0.049, the XCO and YAOH are 26.2 and 12.0%, respectively. The corresponding XCO and YAOH for the case using β-Mo2C are 21.5% and 6.6%, respectively. The comparison indicates that both K and V are promoters for enhancing the XCO and YAOH, with K exhibiting more vigorous effect. The V-K co-modified β-Mo2C catalyst with V/K/Mo = 0.1/1/2 gives XCO of 35.1% and YAOH of 25.4% with SEtOH as high as 39.9%. The results reveal the synergistic enhancement of K and V on the XCO and YAOH, especially on the SEtOH. The presence of water induces the water-gas shift reaction (WGS) of CO which further contributes the formation of reactive radicals, thus enhancing the yields of alcohols. The XCO and YAOH can reach as high as 35.7% and 26.8%. The SEtOH may be retained at satisfactory value of 35.79%. Some ethanols are converted to higher alcohols of propanol and butanol due to the presence of H2O which contains H and O. The deviation of methanol (MeOH) from the linear Anderson-Schulz-Flory (ASF) distribution for the cases using K-Mo2C, V-Mo2C and V-K-Mo2C catalysts indicates that the reaction mechanisms of the chain-propagation of alcohols are different from those using sole β-Mo2C. This may be due to the functions of V or/and K on the mechanisms, such as the insertion and re-adsorption. For the alkanes, the ASF distributions are linear for the un-modified and modified β-Mo2C catalysts, revealing that reaction mechanisms of alkanes are not altered by the K and V added on the catalysts.