07-07-2012, 10:37 AM
Crown ethers
[attachment=27041]
Nomenclature
The prefix in brackets indicates the total number of atoms constituting the ring system and the number following the hyphen indicates the number heteroatoms.
[18]-crown-6 has 18 atoms in the ring including the heteroatoms, which is oxygen in this case and has six oxygen atoms, which are the heteroatoms.
If a model of this molecule is made it resembles a crown hence the word crown.
These molecules have a hydrophobic exterior and a hydrophilic interior.
Cations can get into the central cavity of these compounds and are immobilized due to the negative environment of the heteroatoms.
The cavity size determines which cations can be encapsulated inside the cavity.
The interactions between the cation and the crown ethers are purely electrostatic, that is through ion dipole attractions.
Thus each crown ether can selectively capture a cation of a specific size.
The solvating capacity of crown ethers towards metal ions can be termed as
[attachment=27041]
Nomenclature
The prefix in brackets indicates the total number of atoms constituting the ring system and the number following the hyphen indicates the number heteroatoms.
[18]-crown-6 has 18 atoms in the ring including the heteroatoms, which is oxygen in this case and has six oxygen atoms, which are the heteroatoms.
If a model of this molecule is made it resembles a crown hence the word crown.
These molecules have a hydrophobic exterior and a hydrophilic interior.
Cations can get into the central cavity of these compounds and are immobilized due to the negative environment of the heteroatoms.
The cavity size determines which cations can be encapsulated inside the cavity.
The interactions between the cation and the crown ethers are purely electrostatic, that is through ion dipole attractions.
Thus each crown ether can selectively capture a cation of a specific size.
The solvating capacity of crown ethers towards metal ions can be termed as