Two liquids A and B form ideal solution. At `300 K`, the vapour pressure of a solution containing 1 mole of A and 3 moles of B is `550 mm` of Hg. At the same temperature, if one more mole of B is added to this solution, the vapour pressure of the solution increases by `10 mm` of Hg. Determine the vapour pressure of a and B in their pure states.A. `p_A^@`=600 mm Hg and `p_B^@`=400 mm HgB. `p_A^@`=550 mm Hg and `p_B^@`=560 mm HgC. `p_A^@`=450 mm Hg and `p_B^@`=650 mm HgD. `p_A^@`=400 mm Hg and `p_B^@`=600 mm Hg

Two liquids A and B form ideal solution. At `300 K`, the vapour pressu

1.	Two liquids A and B form ideal solution. At `300 K`, the vapour pressure of a solution containing 1 mole of A and 3 moles of B is `550 mm` of Hg. At the same temperature, if one more mole of B is added to this solution, the vapour pressure of the solution increases by `10 mm` of Hg. Determine the vapour pressure of a and B in their pure states.A. `p_A^@`=600 mm Hg and `p_B^@`=400 mm HgB. `p_A^@`=550 mm Hg and `p_B^@`=560 mm HgC. `p_A^@`=450 mm Hg and `p_B^@`=650 mm HgD. `p_A^@`=400 mm Hg and `p_B^@`=600 mm Hg
Answer» Correct Answer - D Vapour pressure of solution containing 1 mole of A + 3 moles of B =550 mm Hg Vapour pressure of solution containing 1 mole of A + 4 moles of B = (550+10) = 560 mm Hg `P_"Total"=p_A^(@) xx x_A + p_B^(@) xx x_B` or 550 =`p_A^(@) xx x_A + p_B^(@) xx x_B` `=p_A^@ xx 1/4 + p_B^@xx3/4[because x_A=1/(1+3)=1/4, x_B=3/(1+3)=3/4]` `550=p_A^@/4+3/4xxp_B^@` or 2200=`p_A^@+3p_B^@`...(i) Again , we have 560=`p_A^@xx1/5+p_B^@xx4/5 (because x_A=1/(1+4)=1/5, x_B=4/(1+4)=4/5)` 2800=`p_A^@+4p_B^@`...(ii) Solving equations (i) and (ii) , we get `p_B^@`=600 mm Hg , `p_A^@`=400 mm Hg

Discussion

No Comment Found

Related InterviewSolutions

Define Solutions.
At `27^(@)C`,3.92 gm `H_(2)SO_(4)` is present in 250 ml solution. The osmotic pressure of this solution is 1.5 atm. If the osmotic pressure of solution of NaOH is 2 atm at same temperature, then concentration of NaOH solution isA. 0.32 MB. 12.183 MC. `72.3 gm//lit`D. 1 M `Na_(2)SO_(4)`
If K_(3)[Fe(CN)_(6)]` is completely ionised in a solution, what is the number of paritcles forms when one molecule is completely ionised.
29.2% (W/W) HCI stock solution has a density of 1.25 g `mL^(-1)`. The molecular mass of HCI is 36.5 g `mol^(-1)` Calculate the volume (mL) of stock solution required to prepare 200 mL of 0.4 M HCI
A compound `H_(2)X` with molar mass of `80 g` is dissolved in a solvent having density of `0.4 g mL^(-1)`. Assuming no change in volume upon dissolution, the molality of a `3.2` molar solution isA. `9`B. `6`C. `5`D. `8`
A compound `MX_(2)` with molar mass of 80 g is dissolved in a solvent having density 0.4 g `mL^(-1)`. Assuming that there is no change in volume upon dissociation, what is the molality of a 3.2 molar solution ?
The solubility of a solute in a solvent (that is, the extent of the mixing of the solute and solvent species) depends onA. the natural tendency for the solute and solvent species to mixB. the natural tendency for a system to have the lowest energy possibleC. a balance between (1) and (2)D. neither (1) and (2)
Maximum amount of a solid aolute that can be dissolved in a specified amount of a given liquid solvent does not depend upon………..A. temperatureB. nature of soluteC. pressureD. nature of solvent
Solubility of a substance is its maximum amount that can be dissolved in a specified amount of solvent. It depends upon (i)nature of solute , (ii)nature of solvent , (iii)temperature , (iv)pressureA. only (i),(ii) and (iii)B. only (i), (iii) and (iv)C. only (i) and (iv)D. (i),(ii),(iii) and (iv)
A complex is represented as `CoCl_(3) . XNH_(3)`. Its `0.1` molal solution in aqueous solution shows `Delta T_(f) = 0.558^(circ). (K_(f)` for `H_(2)O` is `1.86 K "molality"^(-1))` Assuming `100%` ionisation of complex and co-ordination number of `Co` as six, calculate formula of complex.

Discussion

No Comment Found

Related InterviewSolutions

Reply to Comment