3.2.5.3 Ligand Substitution and Stability

    Cards (58)

    • Transition metal complexes are formed when a transition metal ion binds to one or more ligands
    • The coordination number of a transition metal complex refers to the number of ligands
    • The complex [Cu(NH3)4]2+ is more stable than [Cu(H2O)6]2+ because NH3 is a stronger
    • Match the factors affecting stability with their effects:
      Ligand strength ↔️ Stronger ligands increase stability
      Chelate effect ↔️ Forms multiple bonds, increasing stability
      Coordination number ↔️ Higher coordination number increases stability
    • Arrange the factors affecting the rate of ligand substitution in order of their effect:
      1️⃣ Ligand strength
      2️⃣ Metal ion properties
      3️⃣ Steric effects
      4️⃣ Reaction conditions
    • The rate of ligand substitution is influenced by the nature of the ligands
    • Which metal ion properties affect ligand substitution rates?
      Size, charge, d-electron configuration
    • Stronger ligands displace weaker ligands faster in substitution reactions.

      True
    • What is the central atom in a transition metal complex?
      Transition metal ion
    • Which type of ligands create more stable complexes than monodentate ligands?
      Chelating ligands
    • How does ligand strength affect the rate of substitution?
      Stronger ligands react faster
    • What is the effect of steric effects on ligand substitution rates?
      Bulky ligands slow down substitution
    • In the reaction [Cu(H2O)6]2+ + 4NH3 → [Cu(NH3)4(H2O)2]2+ + 4H2O, the stronger ligand NH3 replaces H2O.
    • Complexes with higher coordination numbers are generally more stable.
    • The chelate effect arises from the increased entropy and enthalpy associated with the formation of chelate rings.
    • What are two factors that contribute to the chelate effect?
      Entropy and enthalpy
    • Stronger ligands like CN- and NH3 form more stable complexes than water.
      True
    • Match the factor with its effect on the substitution rate:
      Ligand Strength ↔️ Stronger ligands react faster
      Metal Ion Properties ↔️ Influence reaction rates
    • Stronger ligands create more stable coordinate covalent bonds in complexes.

      True
    • In which chemical application is the chelate effect particularly significant?
      Selective catalysis
    • Match the properties of transition metal complexes and ligands:
      Transition Metal Complexes ↔️ Compounds formed by a transition metal ion
      Ligands ↔️ Molecules or ions that donate electron pairs
    • Arrange the following factors in order of their effect on the stability of a transition metal complex:
      1️⃣ Ligand strength
      2️⃣ Chelate effect
      3️⃣ Coordination number
    • Ligands form coordinate covalent bonds with the central metal ion in a complex.

      True
    • In ligand substitution, stronger ligands replace weaker ligands to form more stable complexes.

      True
    • What is the driving force for ligand substitution reactions?
      Relative stability
    • Stronger ligands react faster in ligand substitution reactions.

      True
    • What is the role of steric effects in ligand substitution reactions?
      Slows down the reaction
    • Ligands donate electron pairs to the transition metal ion, forming coordinate covalent bonds.
    • The coordination number refers to the number of ligands bonded to the transition metal ion.
    • The driving force for ligand substitution is the relative stability of the initial and final complexes.
    • Match the factors with their effects on ligand substitution reactions:
      Ligand Strength ↔️ Stronger ligands displace weaker ligands
      Metal Ion Properties ↔️ Influence reaction rates
      Steric Effects ↔️ Slows down the reaction
    • Which factor has the greatest effect on ligand substitution rates?
      Ligand Strength
    • What is the chelate effect and why does it enhance stability?
      Multiple bonds increase entropy and enthalpy
    • Chelating ligands create more stable complexes than monodentate ligands.

      True
    • Stronger ligands donate electron pairs to the metal ion to create more stable coordinate covalent bonds.

      True
    • The stability and kinetics of ligand substitution reactions are closely related to the strength of the ligands involved.
    • Stronger ligands displace weaker ligands faster in substitution reactions.

      True
    • Why does NH3 displace H2O faster in ligand substitution reactions?
      NH3 is stronger
    • Match the complex with its stability and application:
      [Cu(H2O)6]2+ ↔️ Low stability, aqueous solutions
      [Cu(NH3)4(H2O)2]2+ ↔️ Moderate stability, controlled catalysis
      [Cu(en)2(H2O)2]2+ ↔️ High stability, selective catalysis
    • Ligands donate electron pairs to the transition metal ion to form coordinate covalent bonds.
      True