The value of `K_(sp)` is `HgCI_(2)` at room temperature is `4.0 xx 10^(-15)`. The concentration of `CI^(Theta)` ion in its aqueous solution at saturation point is

The value of K_(sp) is HgCl_(2) at room temperature is 4.0 xx 10^(-15) . The concentration of Cl^(-) ion in its aqueous solution at saturation point is

The solubility product of HgCl_(2) at room temperature is 4.0 xx 10^(-5) . The concentration of Cl^(-) ion in the saturated solution will be

K_(sp) of a salt , having the general formula MX_2 in water 4xx10^(-12) The concentration of M^(2+) ions in the aqueous solution of the salt is

The pH an aqueous solution of Ba(OH)_(2) is 10.0 . If the K_(sp) of Ba(OH)_(2) is 1.0xx10^(-9) , the concetration of Ba^(2+) ions in the solution is

K_(sp) of Mg(OH)_2 is 4.0 xx 10^(-12) . The number of moles of Mg^(2+) ions in one litre of its saturated solution in 0.1 M NaOH is

At 298 K , the K_(sp) of M_(2) SO_(4) is 3.2 xx 10^(-5) . The maximum concentration of SO_(4)^(2-) ion that could be attained in a saturated solution of this solid at 298 K is

The P^(H) of saturated aqueous solution of Ba(OH)_(2) is 10 . If the K_(sp) of Ba(OH)_(2) is 5 xx 10^(13) , then the concentration of Ba^(2+) ions in the solution is

The K_(sp) for X_(2) SO_(4) at 25^(@) (X^(+) is a monovalent ion) is 3.2 xx 10^(-5) The maximum concentration of X^(+) that could be attained in a saturated solution of this solid at 25^@C is