Answer : equilibrium concentration of H2O = 3.16 M
Given
Volume of flask = 500 ml = 0.5 L
Initial concentration of species = moles of species / volume of flask
Initial concentration of CO = 0.5 moles / 0.5 L = 1 M
Initial concentration of H2O = 1.7 moles / 0.5 L = 3.4 M
Initial concentration of H2 = 1.1 moles / 0.5 L = 2.2 M
Suppose a 500 ml flask is filled with 0.50 mol of CO, 1.7 mol of H,0...
Suppose a 500. mL flask is filled with 0.50 mol of H, and 1.7 mol of 12. The following reaction becomes possible: H2(g) +12(g) = 2HI(g) The equilibrium constant K for this reaction is 3.30 at the temperature of the flask. Calculate the equilibrium molarity of HI. Round your answer to two decimal places. xs ?
Suppose a 500. mL flask is filled with 1.5 mol of CO, 1.8 mol of H,O and 0.60 mol of CO,. The following reaction becomes possible: CO(g) +H2O(g) + CO2(g)+H2(g) The equilibrium constant K for this reaction is 3.75 at the temperature of the flask. Calculate the equilibrium molarity of 1,0. Round your answer to two decimal places. IM | xs ?
Suppose a 500. mL flask is filled with 0.20 mol of NO2, 1.7 mol of NO and 0.80 mol of CO2. The following reaction becomes possible: NO2(g) +CO(g) = NO(g) + CO2(g) The equilibrium constant K for this reaction is 0.457 at the temperature of the flask. Calculate the equilibrium molarity of NO. Round your answer to two decimal places. MM x 6 ?
Suppose a 500 ml flask is filled with 1.7 mol of CO, 0.40 mol of H.O and 1.9 mol of CO,The following reaction becomes possible: CO(e)+H,0(B) - CO (8)+H.) The equilibrium constant K for this reaction is 0.305 at the temperature of the flask. Calculate the equilibrium molarity of CO. Round your answer to two decimal places
Suppose a 500. ml flask is filled with 0.90 mol of NO,, 0.10 mol of CO and 0.50 mol of NO. The following reaction becomes possible: NO2(g) +CO(g) = NO(g) + CO2(g) The equilibrium constant K for this reaction is 0.172 at the temperature of the flask. Calculate the equilibrium molarity of CO. Round your answer to two decimal places. IM xs ?
Suppose a 500. mL flask is filled with 1.7 mol of O_2 and 1.1 mol of NO. The following reaction becomes possible: N_2(g) + O_2(g) 2NO(g) The equilibrium constant K for this reaction is 3.80 at the temperature of the flask. Calculate the equilibrium molarity of NO.
Suppose a 500 ml flask is filled with 1.6 mol of H, and 1.7 mol of HCl. The following reaction becomes possible: H2(g) +C12(g) + 2HCI(g) The equilibrium constant K for this reaction is 8.78 at the temperature of the flask. Calculate the equilibrium molarity of Cl,. Round your answer to two decimal places. OM x 6 ?
Suppose a 250. ml flask is filled with 0.50 mol of CO, 0.60 mol of NO and 2.0 mol of CO2. The following reaction becomes possible: NO2(g) + CO(g) = NO(g) + CO2(g) The equilibrium constant K for this reaction is 3.29 at the temperature of the flask. Calculate the equilibrium molarity of CO. Round your answer to two decimal places. IM x 6 ?
Suppose a 500. mL flask is filled with 0.40 mol of CO, 0.60 mol of NO and 0.70 mol of CO2. The following reaction becomes possible: NO2(g) +CONO( CO2() The equilibrium constant K for this reaction is 9.06 at the temperature of the flask. Calculate the equilibrium molarity of CO. Round your answer to two decimal places. Џи
Suppose a 500. mL flask is filled with 1.5 mol of CO, 1.2 mol of NO and 1.0 mol of CO,. The following reaction becomes possible: NO2(g) +CO(g) = NO(g) + CO2(g) The equilibrium constant K for this reaction is 6.78 at the temperature of the flask. Calculate the equilibrium molarity of NO2. Round your answer to two decimal places. Пм x 6 ?