Presentation is loading. Please wait.

Presentation is loading. Please wait.

Crystal stabilization energy (CFSE) CFSE = Energy lowering in the "crystal field" of the ligands, e.g., in an octahedral or tetrahedral complex Compare.

Published bySydney Rogers Modified over 9 years ago

Similar presentations

Presentation on theme: "Crystal stabilization energy (CFSE) CFSE = Energy lowering in the "crystal field" of the ligands, e.g., in an octahedral or tetrahedral complex Compare."— Presentation transcript:

1 Crystal stabilization energy (CFSE) CFSE = Energy lowering in the "crystal field" of the ligands, e.g., in an octahedral or tetrahedral complex Compare the CFSE for [Cr(CN) 6 ] 4- and [Cr(H 2 O) 6 ] 2+ What are the rules for high spin vs. low spin?

2 Crystal stabilization energy (CFSE) Hydration enthalpies of M 2+ ions Can you explain the trends?

3 Magnetic Susceptibility Molecules and ions that contain unpaired electrons are paramagnetic We can count the number of spins by measuring the susceptibility magnetic moment: µ ≈ µ spin = [n(n+2)] 1/2 µ Bohr What µ s values would you expect for Ni 2+ and Cu 2+ ?

4 When octahedra are distorted, the resulting geometries change the energies of the e g and t 2g orbitals (break degeneracy) Non-octahedral complexes Octahedron Elongated octahedron Square pyramid Square plane

5 d 8 (and d 9 ) are special electron counts for square planar complexes Non-octahedral complexes ΔOΔO dx 2 -y 2 dz 2 dxy dxz dyz Which metals (with which ligands) will form square planar complexes?

6 Square planar complexes are important in homogeneous catalysis Non-octahedral complexes Catalytic hydrogenation of olefins using Wilkinson's catalyst

7 What splitting pattern would you predict for a tetrahedral complex? Non-octahedral complexes

8 Tetrahedral complexes Co[CoCl 4 ] + 12 H2O ---> 2 Co(H 2 O) 6 Cl 2 (deep blue, tetrahedral CoCl 4 2- ) (light pink, octahedral [Co(H 2 O) 6 ] 2+ ) Why are tetrahedral complexes more strongly colored than octahedral ones?

9 Jahn-Teller Effect Complexes with unequal populations of electrons in upper (antibonding) orbitals distort to lower their energy [Cu(OH 2 ) 6 ] 2+ [Cu(OH 2 ) 5 ] 2+

10 Chelate and Macrocyclic Effects Multidentate ("chelating") ligands make very stable complexes What is different about these reactions?? Metal-en complexation [Co(H 2 O) 6 ] 2+ + 6 NH 3 ⇌ [Co(NH 3 ) 6 ] 2+ + 6 H 2 O [Co(H 2 O) 6 ] 2+ + 3 en ⇌ [Co(en) 3 ] 2+ + 6 H 2 O

11 Chelate and Macrocyclic Effects Chelating ligands EDTA 2,2'-bipyridine = bpy acetylacetonate = acac

12 Chelate and Macrocyclic Effects Macrocyclic ligands Valinomycin 18-crown-6 Heme b

Download ppt "Crystal stabilization energy (CFSE) CFSE = Energy lowering in the "crystal field" of the ligands, e.g., in an octahedral or tetrahedral complex Compare."

Similar presentations

Chapter 15 Complex Ions.

Chapter 15 Complex Ions.
Metal Complexes -- Chapter 24

Metal Complexes -- Chapter 24
Mysteries of polarized light Enantiomers have identical properties except in one respect: the rotation of the plane of polarization of light Enantiomers.

Mysteries of polarized light Enantiomers have identical properties except in one respect: the rotation of the plane of polarization of light Enantiomers.
Chemistry 142 Chapter 24: Transition Metals and Coordination Compounds

Chemistry 142 Chapter 24: Transition Metals and Coordination Compounds
Ch 10 Lecture 3 Angular Overlap

Ch 10 Lecture 3 Angular Overlap
Chapter 9 Coordination Chemistry I Structures and Isomers.

Chapter 9 Coordination Chemistry I Structures and Isomers.
Coordination Chemistry II

Coordination Chemistry II
Coordination Chemistry Bonding in transition-metal complexes.

Coordination Chemistry Bonding in transition-metal complexes.
Prentice-Hall © 2002 Complex Ions and Coordination Compounds.

Prentice-Hall © 2002 Complex Ions and Coordination Compounds.
Placing electrons in d orbitals (strong vs weak field)

Placing electrons in d orbitals (strong vs weak field)
1 Electronic (UV-visible) Spectroscopy | Electronic | XPS UPS UV-visible.

1 Electronic (UV-visible) Spectroscopy | Electronic | XPS UPS UV-visible.
Coordination Chemistry Bonding in transition-metal complexes.

Coordination Chemistry Bonding in transition-metal complexes.
Metal-ligand  interactions in an octahedral environment Six ligand orbitals of  symmetry approaching the metal ion along the x,y,z axes We can build.

Metal-ligand  interactions in an octahedral environment Six ligand orbitals of  symmetry approaching the metal ion along the x,y,z axes We can build.
Chemical Bonding II: Molecular Geometry and Hybridization of Atomic Orbitals Chapter 10 Copyright © The McGraw-Hill Companies, Inc.  Permission required.

Chemical Bonding II: Molecular Geometry and Hybridization of Atomic Orbitals Chapter 10 Copyright © The McGraw-Hill Companies, Inc.  Permission required.
Big-picture perspective: The interactions of the d orbitals with their surrounding chemical environment (ligands) influences their energy levels, and this.

Big-picture perspective: The interactions of the d orbitals with their surrounding chemical environment (ligands) influences their energy levels, and this.
Transition Metal Complexes. Transition metal complexes consist of a central Transition metal ion surrounded by a number of ligands. As a result of their.

Transition Metal Complexes. Transition metal complexes consist of a central Transition metal ion surrounded by a number of ligands. As a result of their.
Transition Metals Occupy the d-block of periodic table Have d-electrons in valence shell Some characteristics of Transition Metals and their compounds.

Transition Metals Occupy the d-block of periodic table Have d-electrons in valence shell Some characteristics of Transition Metals and their compounds.
Transition Metals.

Transition Metals.
Crystal Field Theory 400 500 600 800 The relationship between colors and complex metal ions.

Crystal Field Theory The relationship between colors and complex metal ions.
Coordination Chemistry:

Coordination Chemistry:

Similar presentations

Ads by Google