If `N_(2) + 3 H_(2) hArr 2NH_(3) ... (1) & N_(2) + 3H_(2) overset(Fe)(hArr) 2NH_(3).... ` (II) are in equilibrium at same temperature. Then

Consider the following reaction equilibrium N_(2)(g)+ 3H_(2)(g) hArr 2NH_(3) Initially, 1 mole of N_(2) and 3 moles of H_(2) are taken in a 2 2L flask. At equilibrium state, if the number of moles of N_(2) is 0.6, what is the total number of moles of all gases present in the flask?

For the reaction, N_(2) + 3H_(2) hArr 2NH_(3) in a vessel, equal moles of N_(2) and H_(2) are mixed to attain equilibrium.

{:(List - I , List - II),((A) N_(2) + O_(2) hArr 2NO,(p) (atm)^(-2)),((B) 2SO_(2)(g) + O_(2) hArr 2SO_(3)(g),(Q) "NO unit"),((C) H_(2) + I_(2) hArr 2HI,(R)"No cffect of pressure"),((D) N_(2)(g) + 3H_(2) (g) hArr 2NH_(3)(g), (S) "High pressure favours forward reaction"):}

A reaction N_(2)+ 3H_(2) hArr 2NH_(3) + 92 k.j is at equilibrium. If the concentration of N_(2) is increased the temperature of the system

A gaseous phase reaction taking place in 1 lit at 400K is given N_(2) (g) + 3H_(2) (g) hArr 2NH_(3) (g) starting with 1 mole N_(2) and 3 moles H_(2) equilibrium mixture required 250 ml of 1 M H_(2) SO_(4) . Thus , Ke is

K_(p) for the reaction N_(2) + 3H_(2) hArr 2NH_(3) , is 1.6 xx 10^(-4) atm^(-2) at 400^(@) C. What will be K_(p) at 500^(@) C ? Heat of reaction in this temperature range is-25.14 Kcal.

N_(2(g)) + 3H_(2(g)) hArr 2NH_(3(g)) for the reaction initially the mole ratio was 1: 3 of N_(2). H_(2) . At equilibrium 50% of each has reacted. If the equilibrium pressure is p, the partial pressure of NH_(3) at equilibrium is

For Haber process, N_(2) +3H_(2) harr 2NH_(3)+Q, K_(P) = 10 , find correct statements