In coordination compounds, enantiomers are a type of optical isomer—molecules that are non-superimposable mirror images of each other. They have the same composition and connectivity but differ in the spatial arrangement of ligands around the central metal ion in such a way that they cannot be placed on top of each other exactly.
Here’s a simple breakdown:
- Chirality in Coordination Compounds:
- A complex is chiral if it lacks a plane of symmetry.
- The central metal with its attached ligands forms a “handed” arrangement—like left and right hands.
- Common Examples:
- Octahedral complexes with three bidentate ligands (like [Co(en)₃]³⁺) often show enantiomerism.
- Two forms: Δ (delta) → right-handed twist,
- Λ (lambda) → left-handed twist.
- These two forms are mirror images but cannot be superimposed.
- Octahedral complexes with three bidentate ligands (like [Co(en)₃]³⁺) often show enantiomerism.
- Properties of Enantiomers:
- Chemically similar in an achiral environment.
- Rotate plane-polarized light in opposite directions (one is dextrorotatory, the other levorotatory).
- Can react differently with other chiral molecules (important in bioinorganic chemistry).
In short: Enantiomers in coordination compounds are mirror-image forms of a complex that are chiral, giving rise to optical activity.