1 mole of `AgNO_(3)` is added to 10 litre of 1 M `NH_(3)`. What is the concentration of `Ag(NH_(3))^(+)` in solution? [Given : For `Ag(NH_(3))_(2)^(+),K_(f_(1))=2.0xx10^(3),K_(f_(2))=10^(3)`]

How many moles of NH_(3) must be added to 1 litre of 0.1 M AgNO_(3) solution to reduce Ag^(+) concentration to 2xx10^(-7) " M "K_(d) [Ag (NH_(3))_(2)^(+)] = 6.8 xx10^(-8) .

The number of moles of NH_(3) , that must be added to 2L of 0.80M AgNO_(3) in order to reduce the concentration of Ag^(+) ions to 5.0xx10^(-8)M ( K_("formation") for [Ag(NH_(3))_(2)]^(+)=1.0xx10^(8) ) is ______________.(Nearest integer) [Assume no volume change on adding NH_(3) ]

0.00135 mole of NH_(3) dissociates in 1.0 litre solution of 0.10M . Calculate the dissociation constant of NH_(3) .

What is the approximate OH^(-) ion concentration of a 0.150M NH_(3) solution? (K_(b)=1.75xx10^(-5))

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

What is the concentration of Ag^(+) ion in a 1 L solution containing 0.02 mol of AgNO_(3) and 0.14 mol of NH_(3) ? For [Ag(NH_(3))_(2)]^(+), K_(I nstab)=10^(8)

We have taken a saturated solution of AgBr,K_(sp) of AgBr is 12xx10^(-14) . If 10^(-7) "mole" of AgNO_(3) are added to 1 litre of this solution then the conductivity of this solution in terms of 10^(-7) Sm^(-1) units will be: [Given: lambda_((Ag^(+)))^(@)=4xx10^(-3)Sm^(2)"mol"^(-1),lambda_((Br^(-)))^(@)=6xx10^(-3) S m^(2) "mol"^(-1),lambda_((NO_(3)^(-)))^(@)=5xx10^(-3)Sm^(2) "mol"^(-1) ]