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.

For the reaction, N_(2) + 3H_2 rarr 2NH_(3) if E_1and E_2 equivalent masses of NH_3 and N_2 respectively then E_1 -E_2 is

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?

When H_2 and I_2 are mixed and equilibrium is attained, then

AT673 K. in the formation of NH_(3) From N_(2) and H_(2) , the partial pressures of N_(2) , H_(2) and and NH_(3) at equilibrium are 0.5 , 1 and 9 xx 10^(-3) atm respectively. (N_(2) + 3H_(2) hArr + Q) Calculate K_(c) for the reaction.

For the formation of NH_(3) from N_(2) and H_(2) at 500 K, the concentration of N_(2), H_(2) and NH_(3) at equilibrium are 1. 5xx10^(-2) M and 1.2xx10^(-2)M, respectively. The equilibrium constant for the reverse reaction is

AT673 K. in the formation of NH_(3) From N_(2) and H_(2) , the partial pressures of N_(2) , H_(2) and and NH_(3) at equilibrium are 0.5 , 1 and 9 xx 10^(-3) atm respectively. (N_(2) + 3H_(2) hArr + Q) Report Delta G^(@) using K_(p) value

AT673 K. in the formation of NH_(3) From N_(2) and H_(2) , the partial pressures of N_(2) , H_(2) and and NH_(3) at equilibrium are 0.5 , 1 and 9 xx 10^(-3) atm respectively. (N_(2) + 3H_(2) hArr + Q) Report Delta K_(C) Value

K_(c) for the reaction N_(2)(g)+3H_(2)(g)hArr2N_(3)(g) is 0.5 at 400K find K_(p)

For N_(2) + 3 H_(2) hArr 2 NH_(3) , continous removal of NH_(3) maintains the following condition

In the equation N_(2)+3H_(2) hArr 2NH_(3) the equality realationship between (d[NH_(3)])/(dt) and -(d[H_(2)])/(dt) is