There are many phenomena which we observe in nature or at home.
`color{red}("Examples")` : (i) Raw mangoes shrivel when pickled in brine (salt water)
(ii) Wilted flowers revive when placed in fresh water
(iii) Blood cells collapse when suspended in saline water
We find one thing common in all, that is, all these substances are bound by membranes.
`color{green}("Properties of Membrane") :` (i) These membranes can be of animal or vegetable origin and these occur naturally such as pig’s bladder or parchment or can be synthetic such as cellophane.
(ii) These membranes appear to be continuous sheets or films but they contain a network of submicroscopic holes or pores.
(iii) Small solvent molecules, like water, can pass through these holes but the passage of bigger molecules like solute is hindered.
(iv) These membranes are known as semipermeable membranes (SPM).
`color{green}("Osmosis") :` Assume that only solvent molecules can pass through these semipermeable membranes. If this membrane is placed between the solvent and solution as shown in Fig., the solvent molecules will flow through the membrane from pure solvent to the solution. This process of flow of the solvent is called osmosis. The flow will continue till the equilibrium is attained.
`color{green}("Osmotic Pressure") :` The flow of the solvent from its side to solution side across a semipermeable membrane can be stopped if some extra pressure is applied on the solution. This pressure that just stops the flow of solvent is called osmotic pressure of the solution.
`=>` The flow of solvent from dilute solution to the concentrated solution across a semipermeable membrane is due to osmosis.
`color{green}("Note") :` (i) Solvent molecules always flow from lower concentration to higher concentration of solution.
(ii) The osmotic pressure has been found to depend on the concentration of the solution.
Osmotic pressure is a colligative property as it depends on the number of solute molecules and not on their identity. For dilute solutions, it has been found experimentally that osmotic pressure is proportional to the molarity, `C` of the solution at a given temperature `T`. Thus :
`color{red}(pi = CRT)` ..............(5).
Here `pi` is the osmotic pressure and `R` is the gas constant.
`color{red}(pi = ( n_2/V)RT)` .................(6).
Here `V` is volume of a solution in litres containing `n_2` moles of solute. If `w_2` grams of solute, of molar mass, `M_2` is present in the solution, then `color{red}(n_2 = w_2 / M_2)` and we can write, `color{red}(pi V = (w_2 RT)/M_2)` ..........(7).
or `color{red}(M_2 = (w_2 RT)/(pi V))` ...................(8).
Thus, knowing the quantities `w_2, T, pi` and `V` we can calculate the molar mass of the solute.
Measurement of osmotic pressure provides another method of determining molar masses of solutes.
`color{green}("Note") :` This method is widely used to determine molar masses of proteins, polymers and other macromolecules.
`=>` The osmotic pressure method has the advantage over other methods as pressure measurement is around the room temperature and the molarity of the solution is used instead of molality.
As compared to other colligative properties, its magnitude is large even for very dilute solutions.
The technique of osmotic pressure for determination of molar mass of solutes is particularly useful for biomolecules as they are generally not stable at higher temperatures and polymers have poor solubility.
There are many phenomena which we observe in nature or at home.
`color{red}("Examples")` : (i) Raw mangoes shrivel when pickled in brine (salt water)
(ii) Wilted flowers revive when placed in fresh water
(iii) Blood cells collapse when suspended in saline water
We find one thing common in all, that is, all these substances are bound by membranes.
`color{green}("Properties of Membrane") :` (i) These membranes can be of animal or vegetable origin and these occur naturally such as pig’s bladder or parchment or can be synthetic such as cellophane.
(ii) These membranes appear to be continuous sheets or films but they contain a network of submicroscopic holes or pores.
(iii) Small solvent molecules, like water, can pass through these holes but the passage of bigger molecules like solute is hindered.
(iv) These membranes are known as semipermeable membranes (SPM).
`color{green}("Osmosis") :` Assume that only solvent molecules can pass through these semipermeable membranes. If this membrane is placed between the solvent and solution as shown in Fig., the solvent molecules will flow through the membrane from pure solvent to the solution. This process of flow of the solvent is called osmosis. The flow will continue till the equilibrium is attained.
`color{green}("Osmotic Pressure") :` The flow of the solvent from its side to solution side across a semipermeable membrane can be stopped if some extra pressure is applied on the solution. This pressure that just stops the flow of solvent is called osmotic pressure of the solution.
`=>` The flow of solvent from dilute solution to the concentrated solution across a semipermeable membrane is due to osmosis.
`color{green}("Note") :` (i) Solvent molecules always flow from lower concentration to higher concentration of solution.
(ii) The osmotic pressure has been found to depend on the concentration of the solution.
Osmotic pressure is a colligative property as it depends on the number of solute molecules and not on their identity. For dilute solutions, it has been found experimentally that osmotic pressure is proportional to the molarity, `C` of the solution at a given temperature `T`. Thus :
`color{red}(pi = CRT)` ..............(5).
Here `pi` is the osmotic pressure and `R` is the gas constant.
`color{red}(pi = ( n_2/V)RT)` .................(6).
Here `V` is volume of a solution in litres containing `n_2` moles of solute. If `w_2` grams of solute, of molar mass, `M_2` is present in the solution, then `color{red}(n_2 = w_2 / M_2)` and we can write, `color{red}(pi V = (w_2 RT)/M_2)` ..........(7).
or `color{red}(M_2 = (w_2 RT)/(pi V))` ...................(8).
Thus, knowing the quantities `w_2, T, pi` and `V` we can calculate the molar mass of the solute.
Measurement of osmotic pressure provides another method of determining molar masses of solutes.
`color{green}("Note") :` This method is widely used to determine molar masses of proteins, polymers and other macromolecules.
`=>` The osmotic pressure method has the advantage over other methods as pressure measurement is around the room temperature and the molarity of the solution is used instead of molality.
As compared to other colligative properties, its magnitude is large even for very dilute solutions.
The technique of osmotic pressure for determination of molar mass of solutes is particularly useful for biomolecules as they are generally not stable at higher temperatures and polymers have poor solubility.