1.00 g of water is introduced into a 5.00 L evacuated flask at `50^@C`.
`{:("Vapour","Pressure at " 50^@C),(H_2O,92.5 mmHg):}`
What mass of water is present as liquid when equilibrium is established ?

A simple of thliqid H_(2)O at 18.0 g is inlected into an evacuated 7.6 L flask maintained at 27.0^(@)C . If vapour pressure of H_(0)O at 27.0^(@)C is 24.63 mm Hg, what wight percentage of the water will be vaproueied when the ssystem comes to equilibrium? Assume water vapours behaves as an ideal gas. The volume occupied by the liquid water is negligible compared to the volume of the container:

A simple of thliqid H_(2)O at 18.0 g is inlected into an evacuated 7.6 L flask maintained at 27.0^(@)C . If vapour pressure of H_(0)O at 27.0^(@)C is 24.63 mm Hg, what wight of the water will be vaproueied when the ssystem comes to equilibrium? Assume water vapours behaves as an ideal gas. The volume occupied by the liquid water is negligible compared to the volume of the container:

A sample of liquid H_2O of mass 18.0 g is injected into an evacuated 7.6 L flask maintained at 27^@C. If vapour pressure of H_(2)O at 27^@C is 24.63 mm Hg, what weight percentage of the water will be vapourised when the system comes to equilibrium? Assume water vapours behaves as an ideal gas. The volume occupied by the liquid water is negligible compared to the volume of the container:

A sample of the liquid H_(2)O at 18.0 g is injected into an evacuated 7.6 L flask maintained at 27.0^(@)C . If vapour pressure of H_(2)O at 27.0^(@)C is 24.63 mm Hg, what weight percentage of the water will be vaporised when the system comes to equilibrium? Assume water vapors behaves as an ideal gas. The volume occupied by the liquid water is negligible compared to the volume of the container:

If 10^(-4) dm^(3) of water is introduced into a 1.0 dm^(3) flask to 300K how many moles of water are in the vapour phase when equilibrium is established ? (Given vapour pressure of H_(2)O at 300K is 3170Pa R =8.314 JK^(-1) mol^(-1)) .

If 10^(-4) dm^(3) of water is introduced into a 1.0 dm^(3) flask to 300K how many moles of water are in the vapour phase when equilibrium is established ? (Given vapour pressure of H_(2)O at 300K is 3170Pa R =8.314 JK^(-1) mol^(-1)) .

If 10^(-4) dm^(3) of water is introduced into a 1.0 dm^(3) flask to 300K how many moles of water are in the vapour phase when equilibrium is established ? (Given vapour pressure of H_(2)O at 300K is 3170Pa R =8.314 JK^(-1) mol^(-1)) .