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Chap 24 Part 2 Color and Magnetism Color Color of a complex depends on; (i) the metal, (ii) its oxidation state & (iii) ligands (i.e., everything) For example, pale blue [Cu(H2O)6]2+ versus dark blue [Cu(NH3)6]2+. Partially filled d orbitals usually give rise to colored complexes because they can absorb light from the visible region of the spectrum. The color of the complex is the sum of the light not absorbed (reflected) by the complex. Color and Magnetism Color Color A plot of absorption intensity of light versus wavelength is called an absorption spectrum for the complex or compound. Color and Magnetism Since the spectrum for [Ti(H2O)6]3+ has a maximum absorption at 510 nm (green & yellow), & transmits all other wavelengths, the complex is purple. Color and Magnetism Magnetism Transition metal complexes that are paramagnetic have unpaired e-’s & those that are diamagnetic have no unpaired e-’s. Consider the d6 Co metal ion: [Co(NH3)6]3+ has no unpaired electrons, but [CoF6]3- has four unpaired electrons per ion. (note, s e-’s are lost first before d e-’s in a metal cation) We need to develop a bonding theory to account for both color and magnetism in transition metal complexes. Crystal-Field Theory Crystal field theory (CFT) describes bonding & can account for many of the color and magnetic properties in transition metal complexes. Lewis A/B model assumes bonding results from ligand e-’s donated into hybridized d metal orbital. Complex has lower E CFT assumes that the interaction between ligand & metal is electrostatic (pos. nuclei & neg. e-’s). Crystal-Field Theory An octehedral array of negative ligands shown as small (blue) dots approaching the five different d orbitals of a metal ion. Crystal-Field Theory Although there is an overall reduction in E, the negative ligands repel d e-’s giving rise to a slight increase in E. The E gap is called D or the CF splitting E. Two of the five d orbitals are higher in E. Crystal-Field Theory [Ti(H2O)6]3+ Crystal-Field Theory A Spectrochemical series is a listing of ligands in order of their ability to increase D: Cl- < F- < H2O < NH3 < en < NO2- (N-bonded) < CN- Weak field ligands (Cl- & F-) lie on the low end of the spectrochemical series. Strong field ligands (CN-) lie on the high end of the spectrochemical series. Crystal-Field Theory 2 As Cr3+ goes from complexes with weak field ligands to strong field ligands, D increases and the color of the complex changes from green to yellow. Crystal-Field Theory Electron Configurations in Octahedral Complexes Recall that the s e-’s are lost first for the metal ion. So, Ti3+ is d1, V3+ is a d?? and Cr3+ is a d?? ion. We apply Hund’s rule to the 2 sets of 5 d-orbitals. The first three e-’s go into different d orbitals with their spins parallel. We have a choice for the placement of the fourth electron: if it goes into a higher energy orbital, then there is an energy cost associated with promotion (D); if it goes into a lower energy orbital, then there is an energy cost associated with e- spin pairing. Crystal-Field Theory Weak-field ligands (which have a small D) tend to favor adding electrons to the higher-energy orbitals (high-spin complexes) because D is less than the spin-pairing energy. Strong-field ligands (which have a large D) tend to favor adding electrons to lower-energy orbitals (low-spin complexes) because D is greater than the spin-pairing energy. Crystal-Field Theory Tetrahedral & Square-Planar In a tetrahedral field the dxy, dyz, & dxz orbitals are of higher E than the dx2-y2 and the dz2 orbitals. Because there are only 4 ligands, D for a tetrahedral field is smaller than D for an octahedral field. This causes all tetrahedral complexes to be high spin (unless told otherwise). Crystal-Field Theory Tetrahedral & Square-Planar Square planar complexes can be thought of as octahedral complexes with the two ligands along the z-axis removed. As a consequence the four planar ligands are drawn in closer towards the metal. Relative to the octahedral field, the dz2 orbital is greatly lowered in energy, the dyz, and dxz orbitals lowered in energy, the dxy, and dx2-y2 orbitals are raised in energy. Crystal-Field Theory Most d8 metal ions form square planar complexes. The majority of complexes are low spin (i.e. diamagnetic). Examples: Pd2+, Pt2+, Ir+, and Au3+. End of Chapter 24 Chemistry of Coordination Compounds Homework: 7, 13, 14, 17, 19-21, 23-26, 28, 31, 38, 30, 42-44, 47