319484 Benzene and toulene form nearly ideal solutions. At \({\rm{2}}{{\rm{0}}^{\rm{^\circ }}}{\rm{C}}\), the vapour pressure of benzene is 75 torr and that of toulene is 22 torr. The partial vapour pressure of benzene at \({\rm{2}}{{\rm{0}}^{\rm{^\circ }}}{\rm{C}}\) for a solution containing 78 g of benzene and 46 g of toulene in torr is

319485 Vapour pressure of a solution containing 18 g of glucose and 178.2 g of water at \({\mathrm{100^{\circ} \mathrm{C}}}\) is: (Vapour pressure of pure water at\({\mathrm{100^{\circ} \mathrm{C}=760}}\) torr)

319486 Mole fraction of the component A in vapour phase is \({{\rm{X}}_{\rm{1}}}\), and the mole fraction of component A in liquid mixture is \({{\rm{X}}_{\rm{2}}}\), then (\({{\rm{P}}_{{{\rm{A}}^{\rm{o}}}}}{\rm{ = }}\) vapour pressure of pure A; \({{\rm{P}}_{{{\rm{B}}^{\rm{o}}}}}{\rm{ = }}\) vapour pressure of pure B), the total pressure of liquid mixture is

319487 Two liquids \({\text{X}}\) and \({\text{Y}}\) form an ideal solution. The mixture has a vapour pressure of \(400 \mathrm{~mm}\) at \(300 \mathrm{~K}\) when mixed in the molar ratio of \(1: 1\) and a vapour pressure of \(350 \mathrm{~mm}\) when mixed in the molar ratio of \(1: 2\) at the same temperature. The vapour pressures of the two pure liquids \(\mathrm{X}\) and \({\text{Y}}\) respectively are:

319484 Benzene and toulene form nearly ideal solutions. At \({\rm{2}}{{\rm{0}}^{\rm{^\circ }}}{\rm{C}}\), the vapour pressure of benzene is 75 torr and that of toulene is 22 torr. The partial vapour pressure of benzene at \({\rm{2}}{{\rm{0}}^{\rm{^\circ }}}{\rm{C}}\) for a solution containing 78 g of benzene and 46 g of toulene in torr is

319485 Vapour pressure of a solution containing 18 g of glucose and 178.2 g of water at \({\mathrm{100^{\circ} \mathrm{C}}}\) is: (Vapour pressure of pure water at\({\mathrm{100^{\circ} \mathrm{C}=760}}\) torr)

319486 Mole fraction of the component A in vapour phase is \({{\rm{X}}_{\rm{1}}}\), and the mole fraction of component A in liquid mixture is \({{\rm{X}}_{\rm{2}}}\), then (\({{\rm{P}}_{{{\rm{A}}^{\rm{o}}}}}{\rm{ = }}\) vapour pressure of pure A; \({{\rm{P}}_{{{\rm{B}}^{\rm{o}}}}}{\rm{ = }}\) vapour pressure of pure B), the total pressure of liquid mixture is

319487 Two liquids \({\text{X}}\) and \({\text{Y}}\) form an ideal solution. The mixture has a vapour pressure of \(400 \mathrm{~mm}\) at \(300 \mathrm{~K}\) when mixed in the molar ratio of \(1: 1\) and a vapour pressure of \(350 \mathrm{~mm}\) when mixed in the molar ratio of \(1: 2\) at the same temperature. The vapour pressures of the two pure liquids \(\mathrm{X}\) and \({\text{Y}}\) respectively are:

319484 Benzene and toulene form nearly ideal solutions. At \({\rm{2}}{{\rm{0}}^{\rm{^\circ }}}{\rm{C}}\), the vapour pressure of benzene is 75 torr and that of toulene is 22 torr. The partial vapour pressure of benzene at \({\rm{2}}{{\rm{0}}^{\rm{^\circ }}}{\rm{C}}\) for a solution containing 78 g of benzene and 46 g of toulene in torr is

319485 Vapour pressure of a solution containing 18 g of glucose and 178.2 g of water at \({\mathrm{100^{\circ} \mathrm{C}}}\) is: (Vapour pressure of pure water at\({\mathrm{100^{\circ} \mathrm{C}=760}}\) torr)

319486 Mole fraction of the component A in vapour phase is \({{\rm{X}}_{\rm{1}}}\), and the mole fraction of component A in liquid mixture is \({{\rm{X}}_{\rm{2}}}\), then (\({{\rm{P}}_{{{\rm{A}}^{\rm{o}}}}}{\rm{ = }}\) vapour pressure of pure A; \({{\rm{P}}_{{{\rm{B}}^{\rm{o}}}}}{\rm{ = }}\) vapour pressure of pure B), the total pressure of liquid mixture is

319487 Two liquids \({\text{X}}\) and \({\text{Y}}\) form an ideal solution. The mixture has a vapour pressure of \(400 \mathrm{~mm}\) at \(300 \mathrm{~K}\) when mixed in the molar ratio of \(1: 1\) and a vapour pressure of \(350 \mathrm{~mm}\) when mixed in the molar ratio of \(1: 2\) at the same temperature. The vapour pressures of the two pure liquids \(\mathrm{X}\) and \({\text{Y}}\) respectively are:

319484 Benzene and toulene form nearly ideal solutions. At \({\rm{2}}{{\rm{0}}^{\rm{^\circ }}}{\rm{C}}\), the vapour pressure of benzene is 75 torr and that of toulene is 22 torr. The partial vapour pressure of benzene at \({\rm{2}}{{\rm{0}}^{\rm{^\circ }}}{\rm{C}}\) for a solution containing 78 g of benzene and 46 g of toulene in torr is

319485 Vapour pressure of a solution containing 18 g of glucose and 178.2 g of water at \({\mathrm{100^{\circ} \mathrm{C}}}\) is: (Vapour pressure of pure water at\({\mathrm{100^{\circ} \mathrm{C}=760}}\) torr)

319486 Mole fraction of the component A in vapour phase is \({{\rm{X}}_{\rm{1}}}\), and the mole fraction of component A in liquid mixture is \({{\rm{X}}_{\rm{2}}}\), then (\({{\rm{P}}_{{{\rm{A}}^{\rm{o}}}}}{\rm{ = }}\) vapour pressure of pure A; \({{\rm{P}}_{{{\rm{B}}^{\rm{o}}}}}{\rm{ = }}\) vapour pressure of pure B), the total pressure of liquid mixture is

319487 Two liquids \({\text{X}}\) and \({\text{Y}}\) form an ideal solution. The mixture has a vapour pressure of \(400 \mathrm{~mm}\) at \(300 \mathrm{~K}\) when mixed in the molar ratio of \(1: 1\) and a vapour pressure of \(350 \mathrm{~mm}\) when mixed in the molar ratio of \(1: 2\) at the same temperature. The vapour pressures of the two pure liquids \(\mathrm{X}\) and \({\text{Y}}\) respectively are: