Osmotic pressure is the minimum pressure which needs to be applied to a solution to prevent the inward flow of its pure solvent across a semipermeable membrane.[1] It is also defined as the measure of the tendency of a solution to take in its pure solvent by osmosis. Potential osmotic pressure is the maximum osmotic pressure that could develop in a solution if it were separated from its pure solvent by a semipermeable membrane.
Osmosis occurs when two solutions containing different concentrations of solute are separated by a selectively permeable membrane. Solvent molecules pass preferentially through the membrane from the low-concentration solution to the solution with higher solute concentration. The transfer of solvent molecules will continue until equilibrium is attained.[2]
Jacobus van 't Hoff found a quantitative relationship between osmotic pressure and solute concentration, expressed in the following equation:
\Pi=icRT
\Pi
For more concentrated solutions the van 't Hoff equation can be extended as a power series in solute concentration, c. To a first approximation,
\Pi=\Pi0+Ac2
where
\Pi0
The Pfeffer cell was developed for the measurement of osmotic pressure.
Osmotic pressure measurement may be used for the determination of molecular weights.
Osmotic pressure is an important factor affecting biological cells.[4] Osmoregulation is the homeostasis mechanism of an organism to reach balance in osmotic pressure.
When a biological cell is in a hypotonic environment, the cell interior accumulates water, water flows across the cell membrane into the cell, causing it to expand. In plant cells, the cell wall restricts the expansion, resulting in pressure on the cell wall from within called turgor pressure. Turgor pressure allows herbaceous plants to stand upright. It is also the determining factor for how plants regulate the aperture of their stomata. In animal cells excessive osmotic pressure can result in cytolysis.
Osmotic pressure is the basis of filtering ("reverse osmosis"), a process commonly used in water purification. The water to be purified is placed in a chamber and put under an amount of pressure greater than the osmotic pressure exerted by the water and the solutes dissolved in it. Part of the chamber opens to a differentially permeable membrane that lets water molecules through, but not the solute particles. The osmotic pressure of ocean water is approximately 27 atm. Reverse osmosis desalinates fresh water from ocean salt water.
Consider the system at the point when it has reached equilibrium. The condition for this is that the chemical potential of the solvent (since only it is free to flow toward equilibrium) on both sides of the membrane is equal. The compartment containing the pure solvent has a chemical potential of
\mu0(p)
p
0<xv<1
p'
\muv(xv,p')
p'=p+\Pi
0(p)=\mu | |
\mu | |
v(x |
v,p+\Pi).
Here, the difference in pressure of the two compartments
\Pi\equivp'-p
In order to find
\Pi
\muv(xv,p+\Pi)=
0(p). | |
\mu | |
v |
We can write the left hand side as:
\muv(xv,p+\Pi)=\mu
0(p+\Pi)+RTln(\gamma | |
v |
xv)
\gammav
\gammavxv
aw
p+\Pi | |
\mu | |
p |
Vm(p')dp',
Vm
-RTln(\gammavxv)=\int
p+\Pi | |
p |
Vm(p')dp'.
If the liquid is incompressible the molar volume is constant,
Vm(p')\equivVm
\PiVm
\Pi=-(RT/Vm)ln(\gammavxv).
The activity coefficient is a function of concentration and temperature, but in the case of dilute mixtures, it is often very close to 1.0, so
\Pi=-(RT/Vm)ln(xv).
The mole fraction of solute,
xs
1-xv
ln(xv)
ln(1-xs)
xs
-xs
\Pi=(RT/Vm)xs.
The mole fraction
xs
ns/(ns+nv)
xs
xs=ns/nv
Vm
Vm=V/nv
\Pi=cRT.
For aqueous solutions of salts, ionisation must be taken into account. For example, 1 mole of NaCl ionises to 2 moles of ions.