`SO_(2)CI_(2) harr SO_(2) +Cl_(2)` (gascous): `PCI_(5) harr PCI_(3) + Cl_(2)` (gaseous) of some `SO_(2)` is removed from the above set of equillibria occuring in same closed container

SO_(2) Cl_(2) hArr SO_(2) + Cl_(2) ("gaseous ") , PCl_(5) hArr PCl_(x) + Cl_(2) (gaseous ) of some SO_(2) is removed from the ahove set of equillibria ocuring in same closed container ____

In SOCl_(2) and SO_(2)Cl_(2)

Two systems, PCI_(5(g)) harr PCI_(3(g)) + Cl_(2(g)) and COCl_(2(g)) harr CO_((g)) + Cl_(2(g)) are simultaneously in equilibrium in a vessel at constant volume. If some CO is introduced into the vessel, then at the new equilibrium, the concentration of:

Following two eqilibrium is simultaneously establised in a container PCl_(s(g)) hArr PCl_((3)(g)) + Cl_((2)(g)), CO_((g)) + Cl_(2(g)) hArr COCl_((2)(g)) . If some Ni_((g)) is introduced in the container forming Ni(CO)_(4) then at new equilibrium

Dissociation of PCI_(5) takes place on heating as follows: PCl_(5(g)) harr PCl_(3(g))+Cl_(2(g)) 'D' is the vapour density of PCI_(5) initially and 'd' is the vapour density of the equilibrium mixture. Which of the following graph is correct ( alpha = degree of dissociation).

For the reaction PCl_(5(g)) harr PCl_(3(g)) + Cl_(2(g)) . Which of the graph "is"//"are" correct?

C_(2) H_(5) OH + CH_(3) COOH overset(H_(2) SO_(4)) (hArr) CH_(3) COO C_(2) H_(5) + H_(2) O . Here H_(2) SO_(4) acts as

The degree of dissociation is 0.4 at 400 K and a I atm for the gaseous reaction: PCI_(5(g)) hArr PCl_(3(g)) +Cl_(2(g)) : assuming ideal behaviour of gases, calculate the density of cquilibrium mixture at 400K and latm

How does SO_(2) react with the following ? Cl_(2)