Enantiomeric excess: Difference between revisions
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==Concept== | |||
The enantiomeric excess is used as a numerical value displaying the excess in solution of two enantiomers obtained, after synthesis and/or equilibration. It does'nt provide the ratio of each one, but the percentage of excess versus a racemic mixture. | |||
==From relative concentrations to ee== | ==From relative concentrations to ee== | ||
Revision as of 09:08, 15 September 2009
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Concept
The enantiomeric excess is used as a numerical value displaying the excess in solution of two enantiomers obtained, after synthesis and/or equilibration. It does'nt provide the ratio of each one, but the percentage of excess versus a racemic mixture.
From relative concentrations to ee
A and B are enantiomers, to get an enantiomeric excess (ee) from relative concentration, just do :
ee=|[B]-[A]| || stands for absolue value
example:
we have 70% of A and 30% of B in solution
so also 40%A + 30%A +30%B
[––] [––––––––]
excess racemic part
so the ee in this case is : 40%
From ee to relative concentrations
As enantiomeric says, the ee value is an exces, so do if A is in excess:
%A=100-(100-ee)/2 %B=(100-ee)/2
Best here is an example also:
ee=40%, A is in excess. %A=100-(100-40)/2=70% %B=(100-40)/2=30%
From activation energy to ee
Sometimes, it is interesting to access a theoretical value for the enantiomeric excess. This value can be accessed using the Free Energy of activation, assumed that:
- the pre-exponential factors are equivalent for both pathways leading to enantiomer A and B.
- Starting compound is identical for A and B
exp(-δΔG˜/RT)-1
ee(%)= ––––––––––––––– *100
exp(-δΔG˜/RT)+1
where δΔG˜ is the difference of Free Energy of activation separating the TS leading to A and B
δΔG˜=ΔG˜(favoured)-ΔG˜(unfavoured)
This theoretical value doesn't take into account the Gibbs Free Energy of the compounds, the formula given is derived from reaction rate constants. Thus, after equilibration in solution,depending on the temperature, the observed ee might change in respect to this.
From ee to activation energy
Finally, one can get, under same conditions, a Gibbs Free Energy activation difference :
1+ee
δΔG˜= RT ln ––––
1-ee
/!\ The value of R is often in cal K−1.mol−1 [1], so if your δΔG˜ value is in kcal/mol, choose R=1.9858775*10^-3 Kcal K−1.mol−1