Glauber's salt is

8.0575xx10^(-2) kg of Glauber's slat is dissolved in water to obtain 1 dm^(3) of a solution of density 1077.2 kg m^(-3) . Calculate the molarity, molality and mole fraction of Na_(2)SO_(4) in solution.

On the basis of its unit cell structure, Glauber's salt (crystal-line solution sulphate, NaSO_(4).10H_(2)O ) belongs to the

40.25g of Glauber's salt (Na_(2)SO_(4).10H_(2)O) is dissolved in water to obtain 500mL of solution of density 1077.5gdm^(-3) . The molality of Na_(2)SO_(4) in solution is about:

Assming complete dissociation, Calculate the expected the expected freezing point of a solution prepared by dissolving 6.0 g of Glauber's salt. Na_(2)SO_(4). 10H_(2)O in 0.1 kg of water. (Given value of K_(f)=1.86 K kg mol^(-1)) .

Define (i) Mole fraction (ii) Molality (iii) Raoult's law (b) Assuming complete dissociation, calculate the expected freezing point of a solution prepared by dissolving 6.00 g of Glauber's salt, Na_(2)SO_(4).10 H_(2)O in 0.100 kg of water. ( K_(f) for water = 1.86 K kg "mol"^(-1) , Atomic massess : Na=23, S=32, O=16 , H=1)

Why the solubility of Glauber,s salt (Na_(2)SO_(4)10 H_(2)O) first increases up to 32.4^(@)C and then decreases ?