One "mole" of `N_(2)O_(4)(g)` at `300 K` is kept in a closed container under `1` atm. It is heated to `600 K`, when `20%` by mass of `N_(2)O_(4)(g)` decomposes to `NO_(2)(g)`. The resultant pressure is

One mole of N_(2)O_(4)(g) at 300 K is kept in a closed container under one atmosphere. It is heated to 600K when 20% by mass of N_(2)O_(4) (g) decomposes to NO_(2) (g). The resultant pressure is:

One mole of N_(2)O_(4)(g) at 300 K is kept in a closed container under one atmosphere. It is heated to 600K when 20% by mass of N_(2)O_(4) (g) decomposes to NO_(2) (g). The resultant pressure is:

One mole of N_(2)O_(4) (g) at 300 K is kept in a closed container under one atmosphere. It is heated to 600 K when 20% b mass of N_(2)O_(4) (g) decomposes to NO_(2) (g) the resultant pressure is

One mole of N_(2) O_(4(g)) at 300 K is kept in a closed container under latm. It is heated to 600K when 20% by mass of N_(2) O_(4(g)) decomposes to NO_(2(g)) . The resultant pressure is :

One mole of N_(2)O(g) at 300K is kept in a closed container under one atmosphere. It is heated to 600K when 20% by mass of N_(2)O_(4)(g) decomposes of NO_(2)(g) . The resultant pressure

One "mole" of N_(2)O_(4)(g) at 100 K is kept in a closed container at 1.0 atm pressure. It is heated to 400 K , where 30% by mass of N_(2)O_(4)(g) decomposes to NO_(2)(g) . The resultant pressure will be

One "mole" of N_(2)O_(4)(g) at 100 K is kept in a closed container at 1.0 atm pressure. It is heated to 400 K , where 30% by mass of N_(2)O_(4)(g) decomposes to NO_(2)(g) . The resultant pressure will be

ii. One mole of N_(2)O_(4)(g) at 100 K is kept in a closed container at 1.0 atm pressure. It is heated to 300 K , where 30% by mass of N_(2)O_(4)(g) decomposes to NO_(2)(g) . The resultant pressure will be

One mole of N_(2)O_(4)(g) at 100 K is kept in a closed container at 1.0 atm pressure. It is heated to 300 K , where 30% by mass of N_(2)O_(4)(g) decomposes to NO_(2)(g) . The resultant pressure will be