Can we separate two liquids A (b.p. 353 K) and B (b.p. 365 K) present in a mixture by simple distillation ?

Can we separate the components of azeotropic mixture by distillation?

(a). If both (A) and (R) are correct and (R) is the correct explanation for (A). (b). If both (A) and (R) are correct and (R) is the correct explanation for (A). (c). If (A) is correct and (R) is incorrect. (d). If (A) is incorrect and (R) is correct. ltbr. (e). If both (A) and (R) are incorrect. Q. Assertion (A): Benzene (boiling point 353K) and methanol (boiling point 338K) are separated by simple distillation. Reason (R): Fractional distillation is used to separate two liquids from their mixture when their boiling points differ by 20^@ or so.

represents the distillation of mixture of liquid A and liquid B which gives both of pure liquid A and B . Represents the azeotropic mixture of HNO_(3) and H_(2)O which distillation gives an azeotropic mixture and either of pure liquid. We cannot separate both the pure liquid, i.e., H_(2)O and HNO_(3) . What is the result of distilling a mixture of 80% HNO_(3) and 20%H_(2)O ? (a)Pure H_(2)O and azeotropic mixture can be separated. (b)Pure H_(2)O and pure HNO_(3) can be separated. (c)Pure HNO_(3) and azeotropic mixture can be separated. (d)None of these

represents the distillation of mixture of liquid A and liquid B which gives both of pure liquid A and B . Represents the azeotropic mixture of HNO_(3) and H_(2)O which distillation gives an azeotropic mixture and either of pure liquid. We cannot separate both the pure liquid, i.e., H_(2)O and HNO_(3) . What is the result of distilling a mixture of 50% HNO_(3) and 50%H(2)O ? a.Pure water and azeotropic mixtue can be separated. b.Pure H_(2)O and pure HNO_(3) can be separated. c.Pure HNO_(3) and azeotropic mixture can be separated. d.None of these

represents the distillation of mixture of liquid A and liquid B which gives both of pure liquid A and B . Represents the azeotropic mixture of HNO_(3) and H_(2)O which distillation gives an azeotropic mixture and either of pure liquid. We cannot separate both the pure liquid, i.e., H_(2)O and HNO_(3) . At temperature T_(1) and composition Q , which of the following is true? a.Vapour phase is richer in B while liquid phase is richer in A . b.Distillation of composition Q gives only pure A . c.Distillation of composition Q gives only pure A and pure B . d.Distillation of composition Q gives higher percentage of B and A .

Assertion : Compounds with difference in their boiling points by about 30^(@)C can be separated by simple distillation. Reason : All liquid mixtures can be separated by distillation method.

Components of a binarey mixture of two liquids A and B were being separted by distillation. After some time separation of components stopped and composition of vapour phase vecame same as that of liquid phase. Both the components stated coming in the distillate. Explain why this happened ?

represents the distillation of mixture of liquid A and liquid B which gives both of pure liquid A and B . Represents the azeotropic mixture of HNO_(3) and H_(2)O which distillation gives an azeotropic mixture and either of pure liquid. We cannot separate both the pure liquid, i.e., H_(2)O and HNO_(3) . a solution of 50% of A and 50% of B on distillation results into Separation of an azeotropic mixture and pure A . Separation of an azeotropic mixture and pure B . Separation of both pure A and pure B . None of these

represents the distillation of mixture of liquid A and liquid B which gives both of pure liquid A and B . Represents the azeotropic mixture of HNO_(3) and H_(2)O which distillation gives an azeotropic mixture and either of pure liquid. We cannot separate both the pure liquid, i.e., H_(2)O and HNO_(3) . Which of the following statements is/are correct? i. HNO_(3) solution is not obeying the Raoult's law. ii. More the difference in vapour pressure of pure compounds forming a mixture, easier to separate them through distillation. iii. T_(2) is less than T_(1) because the liquid of composition Q is richer in more volatile component.

Assertion (A). Simple distillation can help in separating a mixture of propan -1-ol (boiling point 97^(@)C ) and propanone (boiling point 56^(@)C ) Reason (R). Liquids with a difference of more than 20^(@)C in their boiling points can be separated by simple distillation.