For the given series of reaction,
`4NH_(3)(g) + 5O_(2)(g) rarr 4NO(g) + 6H_(2)O(l)`
`2NO(g) + O_(2)(g) rarr 2NO(g) +O_(2)(g) rarr 2NO_(2)(g)` If 20 ml of `NH_(3)` is mixed with 100 ml of `O_(2)` .Volume contraction at the completion of above reaction is:

For the given series of reaction, 4NH_(3)(g) + 5O_(2)(g) rarr 4NO(g) + 6H_(2)O(l) 2NO(g) + O_(2)(g) rarr 2NO(g) +O_(2)(g) rarr 2NO_(2)(g) Total volume of O_(2) used if 20 ml NH_(3) is mixed with 100 ml O_(2) is :

Complete the reactions. PH_(3)(g) +O_(2)(g) rarr

For the given series of reaction, 4NH_(3)(g) + 5O_(2)(g) rarr 4NO(g) + 6H_(2)O(l) 2NO(g) + O_(2)(g) rarr 2NO(g) +O_(2)(g) rarr 2NO_(2)(g) To obtain maximum mass of NO_(2) from a given mass of a mixture of NH_(3) and O_(2) the ratio of mass of NH_(3) ot O_(2) should be:

The differential rate law for the reaction, 4NH_3(g)+5O_2(g)rarr4NO(g)+6H_2O(g)

The differential rate law for the reaction, 4NH_3(g)+5O_2(g)rarr4NO(g)+6H_2O(g)

Justify the following reactions are redox rections : 4NH_3(g) + 5O_2(g) rarr 4NO(g) + 6H_2O (g)

Justify the following reaction is redox reaction 4NH_3(g) + 5O_2 (g) to 4NO (g) + 6H_2O (g)

For the first order reaction 2N_(2)O_(5)(g) rarr 4NO_(2)(g) + O_(2)(g)

For the first order reaction 2N_(2)O_(5)(g) rarr 4NO_(2)(g) + O_(2)(g)