Van't Hoff factor

In physical chemistry , the dimensionless Van-'t-Hoff factor i denotes the ratio that forms the sum of the amount of substance of a dissolved substance (solute) in an aqueous solution with the amount of substance of the originally added starting material.

The factor is thus a measure of the extent to which the dissolved substance dissociates and - if it is at least partially dissociated - into how many particles it is divided into during dissociation. The name goes back to Jacobus Henricus van 't Hoff , the first winner of the Nobel Prize in Chemistry .

meaning

The Van-'t-Hoff factor plays an important role in colligative processes in particular , since it is the absolute number and not the type of particles that matter here. For example, the osmotic pressure of a saline solution is almost twice as high as that of a sugar solution with the same amount of substance concentration (see examples).

calculation

The following applies:

{\ displaystyle i = {\ frac {\ Sigma n _ {\ mathrm {solved}}} {n_ {0}}}}

{\ displaystyle \ Leftrightarrow \ Sigma n _ {\ mathrm {solved}} = i \ cdot n_ {0}}

The dissociated part of the original amount of substance ( is the degree of dissociation ; ) may be divided into several particles when going into solution; this is taken into account by the following factor: ${\ displaystyle \ alpha \ cdot n_ {0}}$ ${\ displaystyle \ alpha}$ ${\ displaystyle 0 \ leq \ alpha \ leq 1}$

{\ displaystyle q = {\ frac {\ Sigma n _ {\ mathrm {solved}}} {n_ {0}}}}

( assuming complete dissociation , i.e. ).

{\ displaystyle \ alpha = 1}

In other words, the factor q indicates how many moles 1 mole of the starting material would be divided into in the event of complete dissociation ( ). Due to the partial dissociation, they form in the solution

{\ displaystyle q \ geq 1}

{\ displaystyle n _ {\ mathrm {diss}} = q \ cdot (\ alpha \ cdot n_ {0})}

Particle.

Also, the non- dissociated proportion of the original amount of substance in the solution is counted ( the degree of association): ${\ displaystyle 1- \ alpha}$

{\ displaystyle n _ {\ mathrm {ass}} = (1- \ alpha) \ cdot n_ {0}.}

The following applies:

{\ displaystyle {\ begin {aligned} \ Rightarrow \ Sigma n _ {\ mathrm {solved}} & = n _ {\ mathrm {diss}} + n _ {\ mathrm {ass}} \\\ Leftrightarrow i & = q \ cdot \ alpha + (1- \ alpha) \ end {aligned}}}

{\ displaystyle \ Leftrightarrow i = 1 + \ alpha (q-1).}

Examples

As an example, glucose has a Van't Hoff factor of 1 because it is undissociated and soluble in water:

{\ displaystyle {\ begin {aligned} \ alpha _ {\ mathrm {Glucose}} & = 0 \\\ Rightarrow i _ {\ mathrm {Glucose}} & = 1. \ end {aligned}}}

In contrast, the Van-'t-Hoff factor of sodium chloride is 2, because one mole of NaCl dissociates almost completely into one mole each of Na ⁺ and Cl ^- :

{\ displaystyle {\ begin {aligned} n _ {\ mathrm {Na ^ {+}}} = n _ {\ mathrm {Cl ^ {-}}} = 1 \; \ mathrm {mol} \ Rightarrow q _ {\ mathrm { NaCl}} & = 2 \\\ alpha _ {\ mathrm {NaCl}} & = 1 \\\ Rightarrow i _ {\ mathrm {NaCl}} & = 2. \ end {aligned}}}

Substances such as weak electrolytes , which only partially dissociate, have a broken Van't Hoff factor depending on the dissociation equilibrium .

swell

Entry on Raoult's Laws. In: Römpp Online . Georg Thieme Verlag, accessed on December 18, 2014.