`Ag^(+)+NHP(3)hArr[Ag(NH_(3))]^(+), K_(1)=3.5=10^(-3)`
`[Ag(NH)_(3)]^(+)+NH_(3)hArr[Ag(NH_(3))_(2)]^(+),K_(2)=1.7xx10^(-3)` then the formation constant of `[Ag(NH_(3))_(2)]^(+)` is

If Ag^(+)+NH_(3)hArr[Ag(NH_(3))]^(+) , K_(1)=3.5xx10^(-3) and [Ag(NH_(3))]^(+)+NH_(3)hArr[Ag(NH_(3))_(2)]^(+) , K_(2)=1.74xx10^(-3) . The formation constant of [Ag(NH_(3))_(2)]^(+) is :

Consider the following equilibria along with the respective stability constants : Ag^(+)+NH_(3)hArr [Ag(NH_(2))]^(+),K_(1)=3.5xx10^(3) [Ag(NH_(3))]^(+)+NH_(3)hArr [Ag(NH_(3))_(2)]^(+), K_(2)=1.7xx10^(3) Calculate the overal formiation constant of [Ag(NH_(3))_(2)]^(+) .

Ag^(+)+hArr|Ag(NH_(3))_(2)|^(+), k_(1) = 6.8 xx 10^(-3) [Ag(NH_(3))]^(+) + NH_(3)hArr |Ag(NH_(3))_(2)|, k_(2) = 1.6xx10^(-3) Then the formation constant or |Ag(NH_(3))_(2)|^(+) is

Ag^(+) + NH_3 hArr [Ag(NH_3)]^(+) , K_1=3.5xx10^(-3) , [Ag(NH_3)]^(+) + NH_3 hArr [Ag(NH_3)_2]^(+) , K_2=1.7xx10^(-3) . Calculate the formation constant of [Ag(NH_3)_2]^+ . What is the instability constant ?

Ag^(+) + NH_(3) ltimplies [Ag(NH_(3))]^(+), k_(1)=6.8 xx 10^(-5) [Ag(NH_(3))]^(+) + NH_(3) ltimplies [Ag(NH_(3))_(2)]^(+) , k_(2) = 1.6xx10^(-3) The formation constant of [Ag(NH_(3))_(2)]^(+) is :

Ag^(+) + NH_(3) ltimplies [Ag(NH_(3))]^(+), k_(1)=6.8 xx 10^(-5) [Ag(NH_(3))]^(+) + NH_(3) ltimplies [Ag(NH_(3))_(2)]^(+) , k_(2) = 1.6xx10^(-3) The formation constant of [Ag(NH_(3))_(2)]^(+) is :

{:(Ag^+ +NH_3 hArr[Ag(NH_3)]^+,,K_1=3.5xx10^-3),([Ag(NH_3)]^+ +NH_3 hArr[Ag(NH_3)_2]^+,,K_2=1.8xx10^-3):} then, the overall formation constant of [Ag(NH_3)_2]^+ is :

Ag^+ +NH_3 hArr[Ag(NH_3)]^+ K_1=3.5xx10^-3 [Ag(NH_3)]^+ +NH_3 hArr[Ag(NH_3)_2]^+ K_2=1.8xx10^-3 :} then, the overall formation constant of [Ag(NH_3)_2]^+ is :