At `340 K` and `1` atm pressure, `N_(2)O_(4)` is `66%` into `NO_(2)`. What volume of `10 g N_(2)O_(4)` ocuupy under these conditions?

N_(2)O_(4) is 60% dissociated into NO_(2) at 340K and 1 atm pressure. Find the volume of 10 g N_(2)O_(4) occupy under these condition.

At 60^(@) and 1 atm, N_(2)O_(4) is 50% dissociated into NO_(2) then K_(p) is

At 77^(@)C and one atmospheric pressure , N_(2)O_(4) is 70% dissociated into NO_(2) What will be the volume occupied by the mixture under these conditions if we start with 10 g of N_(2)O_(4) ?

At 27^(@)C and 1 atm pressure , N_(2)O_(4) is 20% dissociation into NO_(2) . What is the density of equilibrium mixture of N_(2)O_(4) and NO_(2) at 27^(@)C and 1 atm ?

At 27^(@)C and 1 atm pressure , N_(2)O_(4) is 20% dissociation into NO_(@) .What is the density of equilibrium mixture of N_(2)O_(4) and NO_(2) at 27^(@)C and 1 atm?

Influence of pressure, temperature, concentration and addition of inert gas on a reversible chemical reaction in equilibrium can be explained by formulating the expression for equilibrium constant K_(c) or K_(p) for the equilibrium. On the other hand Le Chatelier principle can be theoretically used to explain the effect of P , T or concentration on the physical or chemical equilibrium both. N_(2)O_(4) is 66% dissociated into NO_(2) at 340K and 1 atmospheric pressure. The volume occupied by 10gN_(2)O_(4) under these conditions is:

Gaseous N_(2)O_(4) dissociates into gaseous NO_(2) according to the reaction : [N_(2)O_(4)(g)hArr2NO_(2)(g)] At 300 K and 1 atm pressure, the degree of dissociation of N_(2)O_(4) is 0.2. If one mole of N_(2)O_(4) gas is contained in a vessel, then the density of the equilibrium mixture is :

At 298 K , the equilibrium between N_(2)O_(4) and NO_(2) is represented as : N_(2)O_(4(g))hArr2NO_(2(g)) . If the total pressure of the equilibrium mixture is P and the degree of dissociation of N_(2)O_(4(g)) at 298 K is x , the partial pressure of NO_(2(g)) under these conditions is:

Gaseous N_(2)O decomposes at 298 K and forms N_(2)(g) and O_(2)(g) .The DeltaH for the reaction at 1 atm pressure and 298 K is -163.15 kJ . What is the value of DeltaU for the decomposition of 200 g of N_(2)O under the same conditions?

At 273K and 1 atm a L of N_(2)O_(4) decomposes to NO_(2) according to equation N_(2)O_(4)(g) hArr 2NO_(2)(g) . To what extent ha the decomposition proceeded when the original volume is 25% less than that of exisiting volume?