The conductivity of molten `KCl` is due to the movement of `K^(o+)` and `Cl^(c-)` ions.

Molten NaCl conducts electricity due to the presence of :

The conductivity of 0.20M solution of KCl of 298K is 0.0248 S cm^-1 . Calculate its molar conductivity.

In the cubic crystal of CsCl (d = 3.97 g cm^(-3)) , the eight corners are occupied by Cl^(Θ) with a Cs^(o+) at the centre and vice versa. Calculate the distance between the neighbouring Cs^(o+) and Cl^(Θ) ions. What is the radius of the two ions? ( Aw of Cs = 132.91 and Cl = 35.45)

The conductivity of 0.20M solution of KCL at 298K is 0.025 S cm^-1 . Calculate its molar conductivity.

The resistance and conductivity of 0.02 M KCl solution are 82.4 ohm and 0.002768 S cm^(-1) respectively . When filled with 0.005 N K_(2)SO_(4) , the solution had a resistance of 324ohm . Calculate : a. Cell constant b. Conductance of K_(2)SO_(4) solution c. Conductivity of K_(2)SO_(4) solution d. Equivalent conductivity of K_(2)SO_(4) solution e. Molar conductivity of K_(2)SO_(4) solution.

The conductivity (k) of a saturated solution of AgBr at 298K is 8.5xx10^(-7)Scm^(-1) . If lambda^(@)._(Ag^(o+)) and lambda^(@)._(Br^(c-)) are 62 and 78 S cm^(2)mol^(-1) , respectively, then calculate the solubility and K_(sp) of AgBr .

Cesium chloride forms a body-centred cubic lattice. Cesiumm and chloride ions are in contact along the body diagoanl of a cell. The length of the side of the unit cell is 412 pm and Cl^(Θ) ion has a radius of 181 pm. Calculate the radius of Cs^(o+) ion.

Calculate the ionic radii of K^(+) and Cl^(-) ions in KCl crystal. The internuclear distance between K^(+) " an " Cl^(-) ions are found to be 3.14Å.