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

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.

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

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

Observe the following equations NH_(3) + Ag^(+) hArr (Ag (NH_(3)) ]^(+) , " " K_(1) = 1.6 xx 10^(3) [ Ag(NH_(3) ]^(+) + NH_(3) hArr [ Ag (NH_(3))_(2) ]^(+), K_(2) = 6.8 xx 10^(3) the equilibrium constant for the following reaction, Ag^(+) + 2NH_(3) hArr [ Ag (NH_(3))_(2) ]^(+) is

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 N_(2)+3H_(2)to2NH_(3) rates of disappearance of N_(2) and H_(2) and rate of appearance of NH_(3) respectively, are a,b and c then

For the reaction N_(2)+3H_(2)to2NH_(3) , the rate of disappearance of H_(2) is "0.01 mol lit"^(-1)"min"^(-1) . The rate of appearance of NH_(3) would be