The following equilibria exist simultaneously in a vessel.
`2NO_2(g) iff N_2O_4 (g), K_(p_1) = 6.8 atm^(-1)`
`NO(g) + NO_2(g) iff N_2O_3 (g), K_(p_2) `
If initially only NO and `NO_2` are present in 1 : 2 mole ratio and total pressure at equilibrium is 5.05 atm and the partial pressure of `N_2O_4` is 1.7 atm, calculate the equilibrium partial pressure of NO and `K_(p_2)` .

When NO and NO_(2) are mixed, the following equilibria are readily obtained, 2NO_(2) hArr N_(2)O_(4), K_(p)=6.8 atm^(-1) NO+NO_(2) hArr N_(2)O_(3) In an experiment when NO and NO_(2) are mixed in the ratio of 1:2 , the final total pressure was 5.05 atm and the partial pressure of N_(2)O_(4) was 1.7 atm. Calculate a. the equilibrium partial pressure of NO . b. K_(p) for NO+NO_(2) hArr N_(2)O_(3) .

K_p for the reaction N_2O_4 (g) hArr 2NO_2(g) is 0.66 at 46^@C . Calculate the part per cent dissociation of N_2O_4 at 46^@C and a total pressure of 0.5 atm. Also calculate the partial pressure of N_2O_4 and NO_2 at equilibrium .

The total pressure of a gaseous mixture of 2.8 g N_(2) , 3.2 g O_(2) , and 0.5 g H_(2) is 4.5 atm . Calculate the partial pressure of each gas.

A(s) harr M(s) + 1/2O_2(g) K_p of the reaction is 4. Find the partial pressure of O_2 at equilibrium

For the reaction : 2NO(g) + Cl_(2) (g) hArr 2NOCl (g), NO and Cl_(2) are initially taken in mole ratio 2 : 1 . The total pressure at equilibrium is found to be 1 atm . If mole of NOCl are one fourth of that of Cl_(2) at equilibrium, K_(p) for the reaction is: