For the following equilibrium Kp = 6.3xx...

For the following equilibrium `K_p = 6.3xx10^14` at 1000 K, `NO(g) + O_3(g) harr NO_2(g) + O_2(g)` Both the forward and reverse reactions in the equilibrium are elementary biomolecular reactions. What is `K_c`, reaction?

Similar Questions

Explore conceptually related problems

For the following equilibrium, K_c=6.3xx10^14 at 1000 K NO(g)+O_3(g)iffNO_2(g)+O_2(g) What is K_c for the reverse reactions?

N_2(g) + O_2(g) harr 2NO_(g) what is the effect of pressur on the above equilibrium?

Examine the chemical equilibrium. 4NH_(3(g)) + 5O_(2(g)) harr 4NO_(g) + 6H_2O_(g) Write the expression for equilibrium constatn (K_c) for the above equilibrium.

Pressure has no influence in the following equilibrium: N_2(g)+O_2(g)harr2NO_(g) . What is the reason for this?

For the reaction, 2NO_(g) + O_(2(g)) harr 2NO_(2(g)) . The equilibrium constant is K. Then predict the equilibrium constants for the following reactions. NO + 1/2O_2 harr NO_2

For the reaction, 2NO_(g) + O_(2(g)) harr 2NO_(2(g)) . The equilibrium constant is K. Then predict the equilibrium constants for the following reactions. 2NO_2 harr 2NO + O_2

For the reaction, 2NO_(g) + O_(2(g)) harr 2NO_(2(g)) . The equilibrium constant is K. Then predict the equilibrium constants for the following reactions. 4NO + 2O_2 harrr 4NO_2

For the following equilibrium `K_p = 6.3xx10^14` at 1000 K, `NO(g) + O_3(g) harr NO_2(g) + O_2(g)` Both the forward and reverse reactions in the equilibrium are elementary biomolecular reactions. What is `K_c`, reaction?

Similar Questions

Recommended Questions