The colligative properties of electrolytes require a slightly diferent approach than the one used for the colligative properties of non- electrolytes. The electrolytes dissociate into ions in solution. It is the number of solute particles that determine the colligative properties of a solution. The electrolyte solutions, therefore show abnormal colligative properties. To account for this effect we define a quantity; called the van't Hoff factor which is given by [solution] i= ( textActual number of particles in solution after dissociation/ text Number of formula units initially dissolved in solution ) i =1 (for non - electrolytes); i 1 (for electrolytes, undergoing dissociation) i

Question

The colligative properties of electrolytes require a slightly diferent approach than the one used for the colligative properties of non- electrolytes. The electrolytes dissociate into ions in solution. It is the number of solute particles that determine the colligative properties of a solution. The electrolyte solutions, therefore show abnormal colligative properties. To account for this effect we define a quantity; called the van't Hoff factor which is given by [solution] i= ( textActual number of particles in solution after dissociation/ text Number of formula units initially dissolved in solution ) i =1 (for non - electrolytes); i >1 (for electrolytes, undergoing dissociation) i < 1 (for solute, undergoing association) For a solution of a non electrolyte in water, the van't Hoff factor is (A) Always equal to 2 (B) Always equal to 0 (C) > 1 but < 2 (D) ≤ 1

Tardigrade Admin · Accepted Answer

Correct answer is (d) ≤ 1

Always equal to 2

Always equal to 0

$> 1$ but $< 2$

$\leq 1$

Correct answer is (d) $\leq 1$

Always equal to 2

Always equal to 0

>1 but <2

≤1

Correct answer is (d) ≤1

$> 1$ but $< 2$

$\leq 1$

Correct answer is (d) $\leq 1$