A mixture of 0.09286 mol of H20, 0.06878 mol of CHA, 0.02165 mol of CO, and 0.07288 mol of H, is placed in a 1.0-L steel pressure vessel at 951 K. The following equilibrium is established: 1 H,0(g) + 1 CH4(g)=1 CO(g) + 3 H2(9) At equilibrium 0.01205 mol of CO is found in the reaction mixture. (a) Calculate the equilibrium partial pressures of H20, CH4, CO, and H2. Peg(H20) = Peg(CH4) = Peg(CO) = Pea(H2) %3! (b) Calculate Kp for this reaction. Kp %3D

A mixture of 0.09286 mol of H20, 0.06878 mol of CHA, 0.02165 mol of CO, and 0.07288 mol of H, is placed in a 1.0-L steel pressure vessel at 951 K. The following equilibrium is established: 1 H,0(g) + 1 CH4(g)=1 CO(g) + 3 H2(9) At equilibrium 0.01205 mol of CO is found in the reaction mixture. (a) Calculate the equilibrium partial pressures of H20, CH4, CO, and H2. Peg(H20) = Peg(CH4) = Peg(CO) = Pea(H2) %3! (b) Calculate Kp for this reaction. Kp %3D

Chemistry: The Molecular Science

5th Edition

ISBN:9781285199047

Author:John W. Moore, Conrad L. Stanitski

Publisher:John W. Moore, Conrad L. Stanitski

Chapter20: Chemistry Of Selected Transition Elements And Coordination Compounds

Section20.2: Iron And Steel: Pyrometallurgy

Problem 20.3E

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