What is the Difference Between Inert and Labile Complexes?
🆚 Go to Comparative Table 🆚The main difference between inert and labile complexes lies in the rate at which they undergo substitution reactions. Inert complexes undergo slow substitution reactions, while labile complexes undergo rapid substitution reactions.
Inert Complexes:
- Undergo slow substitution reactions.
- thermodynamically stable, with a large formation constant.
- often have a smaller activation energy barrier for ligand exchange.
- examples include chelate complexes, which are more inert than complexes with monodentate ligands.
Labile Complexes:
- Undergo rapid substitution reactions.
- thermodynamically unstable, with a small activation energy barrier for ligand exchange.
- can be influenced by factors such as the size of the metal ion, the charge on the metal ion, and the number of d electrons and configuration.
It is important not to confuse the terms "inert" and "labile" with "stable" and "unstable" in a thermodynamic sense. For example, a complex may be thermodynamically stable but still be labile due to its rapid reaction rate.
Comparative Table: Inert vs Labile Complexes
Here is a table summarizing the differences between inert and labile complexes:
Property | Inert Complexes | Labile Complexes |
---|---|---|
Substitution Reaction Rate | Slow | Rapid |
Thermodynamic Stability | Highly stable | Thermodynamically unstable |
Activation Energy Barrier | High | Low |
Half-life Time of Metal-ligand Bond | Greater than 30 s | Less than 30 s |
Examples | Hexaammine cobalt(III) | Pentaaquathiocyanato iron(II) |
Inert complexes undergo slow substitution reactions and are thermodynamically stable, with a high activation energy barrier and a long half-life time of the metal-ligand bond. On the other hand, labile complexes undergo rapid substitution reactions and are thermodynamically unstable, with a low activation energy barrier and a short half-life time of the metal-ligand bond.
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