Properties such as boiling point, freezing point, and vapour pressure of a pure solvent change when solute molecules are added to get homogenous solution. These are called colligative properties.
Anwer the following questions:
i. `NaNO_(3)` ii.`BaCl_(2)`
iii. `K_(3)[Fe(CN)_(6)]` iv. `C_(6)H_(12)O_(6)`
Increasing order of Van't Hoff factor

Properties such as boiling point, freezing point, and vapour pressure of a pure solvent change when solute molecules are added to get homogenous solution. These are called colligative properties. Anwer the following questions: i.0.1 M ethanol ii. 0.1 m Ba_(3)(PO_(4))_(3) iii. 0.1 m Na_(2)SO_(4) Increasing order of freezing points

Properties such as boiling point, freezing point, and vapour pressure of a pure solvent change when solute molecules are added to get homogenous solution. These are called colligative properties. Anwer the following questions: i. 0.001 m NaCl ii.0.001 m urea iii. 0.001 m MgCl_(2) iv. 0.001 m CH_(3)COOH Increasing order of boiling points

Properties such as boiling point, freezing point, and vapour pressure of a pure solvent change when solute molecules are added to get homogenous solution. These are called colligative properties. Anwer the following questions: i.0.1 M glucose ii.1% urea solution iii.0.1 M common salt Increasing order of osmotic pressure

The electrolyte solutions show abnormal colligative porperties.To account for this effect we define a quantity called the Van't Hoff factor given by i=("Actual number of particles in solution after dissociation")/("Number of formula units initially dissolved in solution") i=1 ("for non-electrolytes") igt1 ("for electrolytes, undergoing dissociation") ilt1 ("for solutes, undergoing association") Answer the following questions: 0.1 M K_(4)[Fe(CN)_(6)] is 60% ionized. What will be its Van't Hoff factor?

Among the following the solution which shows the lowest osmotic pressure is a. 0.14 M NaCl , b. 0.05 M CaCl_(2) , c. 0.04 M K_(3)[Fe(CN)_(6)] , d. 0.03 M FeCl_(3)

a) List any three observation that determine that a chemical reaction has taken place. Also list three in formation that cannot be obtained about a chemical reaction merely by its chemical equation. b) Balance the following chemical equations i) Fe+H_(2)O to Fe_(3)O_(4) +H_(2) ii) CO_(2)+H_(2)O to C_(6)H_(12)O_(6) +O_(2) OR a) Explain the following in terms of gain or lose of oxygen with two examples each. i) Oxidation ii) reduction. b) Balance the following chemical equations. 1) HNO_(3)+Ca(OH)_(2) to Ca(NO_(3))_(2)+H_(2)O ii) NaOH + H_(2)SO_(4) to Na_(2)SO_(4) + H_(2)O

Arrange the following solutions as directed: Increasing order of boiling points. 0.001 m NaCl , 0.001 m urea 0.001 m MgCl_(2) , 0.001 m CH_(3)COOH Increasing order freezing points. 0.1 M ethanol , 0.1 M Ba_(3)(PO_(4)_(2) 0.1 M Na_(2)SO_(4) Increasing order of osmotic pressure. 0.1 M glucose , 1% urea solution 0.1 M common salt Increasing order of Van't Hoff factor. ltBrgt NaNO_(3) , BaCl_(2) K_(3)[Fe(CN)_(6] , C_(6)H_(12)O_(6) CH_(3)COOH

A system of greater disorder of molecules is more probable. The disorder of molecules is reflected by the entropy of the system. A liquid vapourizes to form a more disordered gas. When a solute is present, there is additional contribution to the entropy of the liquid due to increased randomness. As the entropy of solution is higher than that of pure liquid, there is weaker tendency to form the gas. Thus, a solute (non-volatile) lowers the vapour pressure of a liquid, and hence a higher boiling point of the solution. Similarly, the greater randomness of the solution opposes the tendercy to freeze. In consequence, a lower temperature must be reached for achieving the equilibrium between the solid (frozen solvent) and the solution. The elevation in boiling point (DeltaT_(b)) and depression in freezing point (DeltaT_(f)) of a solution are the colligative properties which depend only on the concentration of particles of the solute and not their identity. For dilute solutions, (DeltaT_(b)) and (DeltaT_(f)) are proportional to the molarity of the solute in the solution. To aqueous solution of Nal , increasing amounts of solid Hgl_(2) is added. The vapour pressure of the solution