`K_(sp)` of AgCl,`Ag_(2)CrO_(4)` and AgBr are `10^(-10),10^(-13)` and `10^(-12)` respectively. If to a solution of 0.1 M each of `Cl^(-), CrO_(4)^(2-)` and `Br^(-)` ions, `AgNO_(3)` is added slowly, which will precipitate first :

The solubility product constant of Ag_(2)CrO_(4) and AgBr are 1.1xx10^(-12) and 5.0xx10^(-13) respectively. Calculate the ratio of the molarities of their saturated solutions.

Consider the cell Ag|AgBr(s)Br^(-)||AgCl(s)Cl^(-)|Ag at 298 K the solubility product of AgCl and AgBr are 1xx10^(-10) and 5xx10^(-13) respectively. What should be the ratio of concentration of Br^(-) and Cl^(-) by which emf of the cell becomes zero?

1.0L of solution which was in equilibrium with solid mixture of AgCI and Ag_(2)CrO_(4) was found to contain 1 xx 10^(-4) moles of Ag^(+) ions, 1.0 xx 10^(-6) moles of CI^(-) ions and 8.0 xx 10^(-4) moles of CrO_(4)^(2-) ions. At constant volume, Ag^(+) ions are added slowly to the above mixture till 8.0 xx 10^(-7) moles of AgCI got precipitated. How many moles of Ag_(2)CrO_(4) were also precipitated ? Given your answer after multiplying with 10^(6) .

1.0L of solution which was in equilibrium with solid mixture of AgC1 and AgC1 and Ag_(2)CrO_(4) was found to contain 1xx 10^(-4) mol of Ag^(o+) ions, 1.0 xx 10^(-6) mol of C1^(Θ) ions and 8.0 xx 10^(-4) moles of CrO_(4)^(2-) ions. Ag^(o+) ions added slowely to the above mixture (keeping volume constant) till 8.0 xx 10^(-7) mol of AgC1 got precipitated. How many moles of Ag_(2)CrO_(4) were also precipitated?