Given: `Ag(NH_(3))_(2)^(+)hArrAg^(+)2NH_(3), K_(C)=6.2xx10^(-8)` and `K_(SP)` of `AgCI=1.8xx10^(-10)` at 298 K. Calculate the concentration of the complex in `1.0M` aqueous ammonia.

For NH_(3) , K_(b)=1.8xx10^(-5) . K_(a) for NH_(4)^(+) would be

In 1L saturated solution of AgCI[K_(SP)(AgCI)= 1.6xx10^(-10)], 0.1 mole of CuCI [K_(SP)(CuCI)=1.0xx10^(-6)] is added. The resulrant concentration of Ag^(+) in the solution is 1.6xx10^(-x) . The value of "x" is:

Formation constant K_(f) for the two complex ions are: [Ni(en)_(3)]^(2+) , K_(f)=1.1 xx 10^(18) and [Ni(NH_(3))_(6)]^(2+) , K_(f) = 5.3 xx 10^(8) Explain the relative stability of these complexes.

In 1L saturated solution of AgCI [K_(sp) (AgCI) = 1.6 xx 10^(-10)], 0.1 mol of CuCI [K_(sp)(CuCI) = 1.0 xx 10^(-6)] is added. The resultant concentration of Ag^(+) in the solution is 1.6 xx 10^(-x) . The value of "x" is.

Given that K_(a) for acetic acid as 1.8 xx 10^(-5) and K_(b) for NH_(4)OH As 1.8 xx 10^(-5) AT 25^(@)C , predict the nature of aqueous solution of ammonium acetate

How much AgBr could dissolve in 1.0L of 0.4M NH_(3) ? Assume that Ag(NH_(3))_(2)^(o+) is the only complex formed. Given: the dissociation constant for Ag(NH_(3))_(2)^(o+) hArr Ag^(o+) xx 2NH_(3) , K_(d) = 6.0 xx 10^(-8) and K_(sp)(AgBr) =5.0 xx 10^(-13) .

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 :

{:(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 :

Arrange the following solutions in decreasing order of [Ag^(o+)] ion: I. 1M [Ag(CN)_(2)]^(Theta) II. Saturated AgC1 III. 1M [Ag(NH_(3))_(2)]^(o+) in 0.1M NH_(3) IV. Saturated AgI (K_(sp) of AgC1 = 10^(-10), K_(sp) of AgI = 8.3 xx 10^(-17) K_(f) (formation constant) [Ag(CN_(2))]^(Theta) = 10^(21), K_(f) [Ag(NH_(3))_(2)]^(o+) = 10^(8)