An aqueous solution of `K_(2)SO_(4)` is diluted by adding water. How the values of `G, k, wedge_(m)` and `wedge_(eq)` vary ?

The product of electrolysis of an aqueous solution of K_(2)SO_(4) using inert electrodes, at anode and cathode respectively are

The boiling point of an aqueous solution of a non-volatile solute is 100.15^(@)C . What is the freezing point of an aqueous solution obtained by dilute the above solution with an equal volume of water. The values of K_(b) and K_(f) for water are 0.512 and 1.86^(@)C mol^(-1) :

The boiling point of an aqueous solution of a non-volatile solute is 100.15^(@)C . What is the freezing point of an aqueous solution obtained by dilute the above solution with an equal volume of water. The values of K_(b) and K_(f) for water are 0.512 and 1.86^(@)C mol^(-1) :

When K_(2)MnO_(4) is added in solution of NH_(4)Cl then

4 L of 0.02 M aqueous solution of NaCl was diluted by adding 1 L of water. The molality of the resultant solution is……..

4 L of 0.02 M aqueous solution of NaCl was diluted by adding 1 L of water. The molality of the resultant solution is……..

A dilute solution of H_(2)SO_(4) is made by adding 5 mL of 3N H_(2)SO_(4) to 245 mL of water. Find the normality and molarity of the diluted solution.

The molar conductivity of KCl solutions at different concentration at 298K are given below : {:(C//"mol L"^(-1),wedge_(m)//S cm^(2)"mol"^(-1)),(0.000198,148.61),(0.000309,148.29),(0.000521,147.81),(0.000987,143.09):} Show that a plot between wedge_(m) and C^(1//2) is a straight line. Determine the values of wedge_(m)^(0) and wedge for KCl.

Calculate the freezing point depression expected for 0.0711 m aqueous solution of Na_(2)SO_(4) . If this solution actually freezes at -0.320 ^(@)C , what would be the value of Van't Hoff factor ? ( K_(f) for water is 1.86 ^(@)C mol^(-1) ) .

K_(2)HgI_(4) is 55% ionized in aqueous solution. The value of Van't Hoff factor is