Colligative Properties of Solutions PDF

Summary

This document explains colligative properties of solutions. It covers concepts like osmotic pressure, freezing point depression, and boiling point elevation, along with their relationships to the number of solute particles. Formulas for these properties are presented, and the document also has various questions on these. The document is likely part of course material for chemistry.

Full Transcript

## Colligative properties of solutions ### **Chapter 1** **Q.1.1** Derive Vant Hoff equation for osmotic pressure. - We have relation $Π = \frac {RT}{V} * P$ - But $P = \frac {1-N_2}{N_2}$ - Therefore, $Π = \frac {RT}{V} * \frac { 1-N_2}{N_2}$ - And $Π = -RT * \frac {1}{V} ln (1-N_2)$ - Macla...

## Colligative properties of solutions ### **Chapter 1** **Q.1.1** Derive Vant Hoff equation for osmotic pressure. - We have relation $Π = \frac {RT}{V} * P$ - But $P = \frac {1-N_2}{N_2}$ - Therefore, $Π = \frac {RT}{V} * \frac { 1-N_2}{N_2}$ - And $Π = -RT * \frac {1}{V} ln (1-N_2)$ - Maclaurins gives $-ln(1-N_2) = N_2$ - So, $Π = \frac {RT}{V} * N_2$ - For very dilute solution $N_1 >> N_2$, $N_2 ≈ \frac {D_2}{V_1}$ - Therefore $Π = \frac {RT}{V_1} * \frac {D_2}{V_1}$ - But $C = \frac {n_2}{V_1}$ - So, $Π = CRT$ **(Eq. 4) Vant Hoff equation** **Q.2.1** Show that depression in freezing point is a colligative property. **Q.2.2** Show that depression in freezing point depends on molality. **Q.2.3** Show that $ΔT_f = k_f * m$. - In the figure, curve $AB$ - sublimation curve, $EF$ - vapour curve of solution, $CD$ - vapour curve of solvent, $GC$ - Supercooled liquid. - And $ΔT_f = T_o - T = 0$ **Q.3.** Define lowering of v.p and relative lowering in v.p. - When a non-volatile solute is added in solvent then the vapour of solution is decreased, this phenomenon is called **lowering** of v.p. - Relative lowering of v.p = $\frac{ΔP}{P_o}$. ### **Chapter 2** **Q.4.1** Describe Berkeley - Hartley's method to determine osmotic pressure of a solution. - It consist of a porous tube with semipermeable membrane, one side reservoir of solvent, another side calibrated capillary, upper flower side of container with solution, and the solution side has a piston with p-gauge. - The solution enters filled in upper and lower part. - Solvent enters in solution chamber and solution side goes upward. - Mechanical pressure is applied on the piston to stop osmosis, which is osmotic pressure. **Q.5.1** Show that $ΔT_b= k_b * m.$ **Q.5.2** Show that elevation in B.P is a colligative property. - In the figure, $AB$ - for pure solvent, $CD$ - for solution - Where $P_o$ - v.p of pure solvent, $P$ - v.p of solution. - And $ΔT_b = T-T_o$ - Apply Clausius - Clayperon equation to curve $EF$. - $\frac{d ln P}{d p} = \frac{ΔH_v}{R} * \frac {1}{T_o - T}$ - Raoult's law gives: $P = P_o * (1-N_2)$ - And: $T-T_o = ΔT_b$. - For dilute solution $T_o . T ≈ T_o^2$. - So, $-ln(1-N_2) = \frac{ΔH_v * ΔT_b}{R * T_o^2}$ - Maclaurins gives: $N_2 = -ln(1-N_2)$. - Thus, $N_2= \frac{ΔT_b * R * T_o^2}{ΔH_v}$. - $N_2 = \frac{M_2}{M_1}$ - So, $ΔT_b = k_b * m$; where $k_b = \frac{R * T_o^2}{ΔH_v}$. - Eq. 5 shows that $ΔT_b$ is a colliagative property ### **Chapter 3** **Q.6.1** Define abnormal molecular weight. - The unexpected molecular weight of solute obtained in colligative study due to dissociation or association is called abnormal molecular weight. **Q.7.1** Define Vant Hoff factor. - It is defined as: - $i = \frac{Colligative \ effect \ of \ electrolyte}{Colligative \ effect \ of \ non \ electrolyte \ of \ same \ conc.}$ **Q.8.1** Define mole fraction. - Mole fraction $N_2 = \frac{n_2}{n_1 + n_2}$, where $n_2$ - number of moles of solute, $n_1$ - number of moles of solvent. **Q.9.1** Define osmosis and osmotic pressure. - The spontaneous unidirectional flow of solvent molecules through a semipermeable membrane from solvent side to solution side is called osmosis. - The mechanical pressure applied on solution side to stop osmosis is called osmotic pressure. - The membrane which allows only the flow of solvent molecules not solute particles, is called a semipermeable membrane. **Q.10.1** Define colligative properties. Give an example. - These properties depend on the number of solute particles, and are independent of nature of the solute and depend on the nature of the solvent. - E.g., Depression in freezing point. **Q.11.1** Define Normality, Molarity, and Molality. Give their unit. - **Normality:** number of gram equivalents of solute in 1 L of solution. Unit: $gm - equiv * L^{-1}$. - **Molarity:** number of moles of solute in 1 L of solution. Unit: $mol * L^{-1}$. - **Molality:** number of moles of solute in 1 kg of solvent. Unit: $mol * Kg^{-1}$. **Q.12.1** Give the statement of Raoult’s law of partial pressure. - Partial vapour pressure = vapour pressure of pure liquid * mole fraction of solvent. - $P = P_o * x_1$ **Q.13.1** Define ebullioscopic constant / molal elevation in B.P constant. How it is related with molar latent heat of vaporization? - It is defined as the elevation in B.P when 1 mole of solute is dissolved in 1000 gm solvent. - $Unit\ of \ k_b: K * Kg * mol^{-1}$ - $k_b = \frac{R * T_o^2}{ΔH_v * n_1}$ - $k_b = \frac{R * T_o^2}{1000 * L_v}$ - Where $T_o$ - B.P of solvent. - $n_1$ - number of moles of the solvent - $ΔH_v$ - heat of vaporization - $L_v$ - latent heat of vaporization **Q.14.1** Define cryoscopic constant / molal elevation in depression in freezing point constant. How it is related with heat of vaporization? - It is defined as the depression in freezing point when 1 mole of solute is dissolved in 1000 gm of solvent. - $Unit\ of \ k_f: K * Kg * mol^{-1}$ - $k_f = \frac {R * T_o^2}{ΔH_f * n_1} $ - $k_f = \frac {R * T_o^2}{1000 * L_f}$ - Where $T_o$ - freezing point of solvent. - $ΔH_f$ - heat of freezing. - $L_f$ - latent heat. **Q. 15.1** Show that lowering in v.p is a colligative property. Show that relative lowering in v.p. is equal to mole fraction of solute. - $ΔP = P -P’$. - But, $P = P_o * N_1$ - Therefore, $ΔP = P_o * N_2$ - Hence, lowering of v.p is a colligative property. - Relative lowering = $\frac{ΔP}{P_o} = N_2$ - Hence, relative lowering is equal to $N_2$. **Q.16.1** Derive relation between osmotic pressure $Π$ and vapour pressure $P$. - $G - G^o = ΔG$ - And $ΔG = RT * ln * a$ - $a = \frac{P}{P_o}$ - So, $ΔG = RT * ln \frac{P}{P_o}$ - And $ΔG = ΠV$ - $ΠV = RT * ln \frac{P_o}{P}$ - Therefore, $Π = \frac {RT}{V} * ln\frac{P_o}{P}$ - Eq. 15 is relation between Π and P. ## **Exercise** **Multiple Choice Questions:** 1. Colligative properties are mainly dependent on: - **(a) Number of solute particles** - (b) Number of solvent particles - (c) Amount of solvent - (d) Pressure of solute 2. Molality of the solution is number of moles of solute present in: - (a) 100 ml of solvent - (c) 1000 g of solvent - **(b) One lit of solution** - (d) 100 g of solvent 3. Relative lowering of vapour pressure of a solution is directly proportional to mole fraction of: - (a) Solvent - (b) Solute - (c) Solute minus solvent - **(d) Solute plus solvent** 4. Molal depression constant is also known as: - (a) Ebullioscopic constant - **(c) Cryoscopic constant** - (b) Molar gas constant - (d) Boltzmann constant 5. Addition of non-volatile solute _______ the vapour pressure: - (a) Enhances - **(b) Lowers** - (c) Diminishes - (d) Keep constant 6. When non-volatile solute is added in the solvent then its vapour pressure: - (a) Increases - (b) Decreases - **(c) Remains constant** - (d) Become zero 7. The vapour pressure of solvent is always: - **(a) Lesser than** - (b) Twice than - (c) Greater than - (d) Same as that of vapour pressure of solution 8. The term $ΔP$ is known as: - (a) Relative lowering of vapour pressure - (c) Average vapour pressure - **(b) Lowering of vapour pressure** - (d) Saturated vapour pressure 9. The relative lowering of vapour pressure is given by: - **(a) $(P°-P)/P_o$** - (b) $(P°-P)/P$ - (c) $(P°+P)/P_o$ - (d) $(P°-P)/P$ 10. Molal elevation constant $(K_b)$ is: - **(a) Directly proportional to heat of vaporization** - (b) Inversely proportional to heat of vaporization - (c) Equal to - (d) Independent on 11. The derivation of colligative properties are based on: - (a) Avogadro's - **(b) Ostwald law** - (c) Raoult's law - (d) Grahm's law 12. Elevation in boiling point is measured by: - (a) Beckmann's method - (c) Vant Hoff method - (b) Landberger method - (d) Berkley method 13. The elevation in boiling point is given by $ΔT = K_b * m$. The $K_b$ term is called as: - **(a) Molal elevation constant** - (b) Ebullioscopic constant - (c) Elevation in boiling point constant - (d) All of these 14. Molal elevation constant is the elevation in boiling point when the molality of the solution is: - (a) 1 - **(b) 2** - (c) 0.5 - (d) 1.5 15. The colligative effect of an electrolyte is always ______ that of a non-electrolyte of the same molar concentration. - (a) Greater - (b) Smaller - **(c) Equal to** - (d) Independent on 16. When non-volatile solute is added to solvent the freezing point of the solvent: - (a) Remains same - **(b) Decreases** - (c) Increases - (d) Becomes zero 17. An aqueous solution of potassium chloride has a boiling point: - (a) Equal to that of water - **(b) More than that of water** - (c) Less than that of water - (d) 1/10 of boiling point of water 18. Which of the following is not a colligative property? - (a) Relative lowering of vapour pressure - (c) Osmotic pressure - **(b) Depression in freezing point** - (d) Surface tension 19. The molar depression constant is given by: - (a) $ΔT * M$ - (b) $ΔT * m$ - (c) $ΔT / m$ - **(d) $ΔT * N$** 20. The flow of solvent molecules take place from: - (a) Dilute solution to concentrated solution - ** (b) Concentrated solution to dilute solution** - (c) Any solution to other - (d) None of these 21. The osmotic pressure of a solution at a given temperature is directly proportional to: - **(a) Osmotic pressure** - (b) Concentration - (c) Volume of the solution - (d) Internal energy 22. The osmotic pressure at a given concentration is directly proportional to: - (a) Room temperature - (c) Critical temperature - **(b) Atmospheric pressure** - (d) Absolute temperature 23. Semi permeable membrane allows to pass only: - (a) Molecules of solute - (c) Cation - **(b) Molecules of solvent** - (d) Anion 24. The method, which measures osmotic pressure, is: - (a) Beckmann method - (c) Vant Hoff method - **(b) Berkley Hartley method** - (d) Landsbergis method 25. The maximum colligative effect in boiling point is observed in: - (a) 0.1 M Cane sugar - **(b) 0.1 M NaCl** - (c) 0.1 M BaCl2 - (d) 0.1 M Urea 26. Abnormal molecular masses are obtained when there exists: - (a) Dissociation of molecule - (c) Dissociation as well as association - **(b) Association of molecule** - (d) No dissociation of solute 27. Osmotic pressure of the solution increases as: - **(a) Number of solution particles decreased** - (c) Number of solute particles increased - (b) Number of solute particles decreased - (d) Temperature is decreased. 28. An aqueous solution of sodium chloride in water has vapour pressure: - (a) Equal to that of water - (c) Less than that of water - **(b) More than that of water** - (d) 760 mm Hg 29. When solute dissociate in the solvent the molecular weight obtained by colligative studies is: - **(a) Greater than** - (b) Lower than - (c) Same as - (d) Double than formula molecular weight 30. The ratio of colligative effect produced by concentration (m) of electrolyte divided by the effect observed in non-electrolyte for the same concentration is known as: - (a) Depression in freezing point - (c) Abnormal molecular weight - **(b) Van't Hoff factor** - (d) Vapour pressure lowering 31. Properties which depend upon the number rather then the nature of the dissolved particles in a solution are called: - (a) Intensive property - (c) Extensive property - **(b) Colligative property** - (d) Constitutive property 32. A colligative property depends upon: - (a) Chemical nature of the particles - (c) Number of particles - **(b) Size of the particles** - (d) Temperature of the solution 33. The ratio of the cogitative effect produced by an electrolyte solution to the corresponding effect for the same concentration of a non-electrolyte solution is known as: - (a) Mole fraction - (c) Relative lowering of vapour pressure - **(b) Lowering of vapour pressure** - (d) Van't Hoff factor 34. Abnormal molecular masses are obtained when there exists: - **(à) Dissociation of molecules** - (c) Either of the two - (b) Association of molecules - (d) None of these 35. Which one of the following is true for the van't Hoff factor $i$? - (a) $i=ΔT/[ΔT]’$ - (b) $i = ΔT’/[ΔT]$ - (c) $i=ΔP / [ΔP]’$ - **(d) All of the above** 36. The value of van't Hoff factor is ______ for an electrolyte. - (a) Greater than one - **(b) Less than one** - (c) Equal to one - (d) Equal to $z$ 37. Benzoic acid, when dissolved in benzene, undergoes: - (a) Dissociation - (b) Association - (c) No change - **(d) Solvation** 38. Which of the following statements is true? - **(à) Osmosis can be reversed by application of a pressure on the solution.** - (b) Osmosis is not spontaneous - (c) Osmosis and diffusion are same in solutions. - (d) Barometer can be used to measure osmotic pressure 39. Select the one that is a colligative property. - (a) Osmotic pressure. - (b) Boiling point. - (c) Freezing point. - **(d) Sublimation** 40. When a solution is diluted, the colligative effect: - (a) Sometimes increases and some times decreases - **(b) Decreases always** - (c) Increases always - (d) Remains unchanged 41. Which of the following is a colligative property? - (a) Surface tension - (b) Viscosity - **(c) Osmotic pressure** - (d) Optical rotation 42. Which of the following is not a colligative property? - (a) Depression of freezing point - (c) Osmotic pressure - **(b) Elevation of boiling point** - (d) Сhange of refractive index 43. Colligative properties of a solution depend upon: - (a) Nature of solute. - (b) Nature of solvent. - **(c) The relative number of solute and solvent particles.** - (d) None of these 44. Which of the following is a colligative property? - (a) Change in free energy. - (c) Heat of vaporization - **(b) Change in pressure** - (d) Osmotic pressure 45. The order of osmotic pressure of equaimolar solutions, of $BaCl_2$, $NaCl$, and glucose will be: - **(a) $BaCl_2 > NaCl > glucose$** - (b) $NaCl > BaCl_2 > glucose$ - (c) $glucose > BaCl_2 > NaCl$ - (d) $glucose > NaCl > BaCl_2$ **Answer:** 1. A 2. C 3. B 4. C 5. B 6. B 7. C 8. B 9. A 10. A 11. B 12. B 13. D 14. B 15. C 16. D 17. B 18. D 19. D 20. B 21. A 22. B 23. B 24. D 25. B 26. C 27. C 28. B 29. A 30. A 31. B 32. C 33. D 34. A 35. D 36. B 37. D 38. A 39. D 40. B 41. C 42. D 43. C 44. D 45. A

Use Quizgecko on...
Browser
Browser