In the equation
`NO_(2)^(ө)+H_(2)OrarrNO_(3)^(ө)+2H^(o+)+ n e ^ (-)`
`n` stands for

For the reaction : 2 NH_(3)(g) rarr N_(2)(g) + 3 H_(2)(g)

The reaction H_(2)S+H_(2)O_(2)rarrS+2H_(2)O shows

Consider the reaction : 4NO_(2)(g) + O_(2)(g) rarr 2N_(2)O_(5)(g), Delta_(f)H = -111 kJ If N_(2)O_(5)(s) is fromed instead of N_(2)O_(5)(g) in the above reaction, the Delta_(f)H is value will be (given, Delta H of sublimation for N_(2)O_(5) is 54 kJ mol^(-1) ).

For the redox reaction x MnO_(4)^(-) + yH_(2)C_(2)O_(4) + zH^(+) to m Mn^(2+) +n CO_(2) + p H_(2)O The valeu of x, y, m and n are

In the ionic equation - BiO_(3)^(-) + 6H^(+) + Xe^(-) → Bi^(3+) + 3H_(2)O the values of x is

The following equilibrium are given : N_(2)+3H_(2)hArr 2NH_(3):K_(1) N_(2)+O_(2)hArr 2NO : K_(2) H_(2)+(1)/(2)O_(2)hArr H_(2)O : K_(3) The equilibrium constant of the reaction : 2NH_(3)+(5)/(2)O_(2)hArr 2NO+3H_(2)O in terms of K_(1), K_(2) and K_(3) is :

The enthalpy of the reaction : H_(2)O_(2)(l) rarr H_(2)O(l) + (1)/(2)O_(2)(g) is -98.3 KJ mol^(-1) and the enthalpy of formation of H_(2)O(l) is -285.6 kJ mol^(-1) . The enthalpy of formation of H_(2)O_(2)(l) is :

One mole of N_(2) and 3 moles of H_(2) are mixed in a litre flask. If 50% N_(2) is converted into ammonia by the reaction. N_(2)(g)+3H_(2)(g)hArr 2NH_(3)(g) then the total number of moles of gas at equilibrium is :