1 / 28

S 4

S 4. C 3. S 6. p z , (d xz , d yz ). s A’ 1 (p x , p y ): E’ p z : A” 2 (d x2 – y2 , d xy ): E’ (d xz , d yz ): E’’ d z2 : A’ 1. -1. 0. 1. 3. 0. -3. f) Now shift to the C 3v point group and obtain the irreducible reps to which the pi bonding NH 2 unit orbitals belong.

lajos
Download Presentation

S 4

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. S4 C3 S6

  2. pz, (dxz, dyz) s A’1 (px , py): E’ pz: A”2 (dx2 – y2, dxy): E’ (dxz, dyz): E’’ dz2: A’1

  3. -1 0 1 3 0 -3

  4. f) Now shift to the C3vpoint group and obtain the irreducible reps to which the pi bonding NH2 unit orbitals belong. G = A1 + E

  5. A1 E1 E2

  6. A1 E1 E2 On going from C3v to D3h maintain same behavior for the C3v operations (E, C3 and sv). Thus A1 in C3v could be either A’1 or A’’2. Choose A2’’ since it is antisym for sh. Likewise, E could be either E’ or E’’ Choose E’’ since it is antisym for sh. Thus A”2 and E’

  7. i) Show bonding between the Si orbitals and the symmetry adapted NH2 orbitals A2” Si Orbitals s A’1 (px , py): E’ Pz: A”2 (x2 – y2, xy): E’ (xz, yz): E’’ z2: A’1 E” (1) E” (2)

  8. E C2(y) sx,z i sx,z i = C2(y) C2(y)

  9. E C2(y) C2’(-xy) sxy,z i C2’(-xy)

  10. E C2(y) C2’(-xy) C4 (z) C2 (z) sx,z sxy,z C4 (z)

  11. E C2(y) C2’(-xy) C4 (z) C2 (z) s-xy,z C2 (z) sxy,z s-xy,z

  12. E C2(y) s-xy,z C2’(-xy) C4 (z) C2 (z) sh s-xy,z C2’(-xy) sh D4h

  13. Coordination number 1 Very rare, bulky ligands, linear structures, no possible isomers

  14. Coordination number 2 Also rare, typical of d10, linear structures, no possible isomers

  15. Coordination number 3 Also typical of d10, trigonal planar structures (rarely T-shaped), no possible isomers

  16. Coordination number 4 Very common Tetrahedral (2 enantiomers if all ligands different) Square planar (2 geometrical isomer for two types of ligands) typical of d8

  17. Tetrahedral Square planar

  18. Coordination number 5 Trigonal bipyramidal (tbp) Square-based pyramidal sbp) Very similar energies, they may easily interconvert in solution (fluxionality)

  19. Coordination number 6 Trigonal prism less common Octahedral most common

  20. Some possible isomers in octahedral complexes cis-MA2B4 trans-MA2B4 fac-MA3B3 mer-MA3B3

  21. Some examples of trigonal prismatic structures

  22. Coordination number 7 Pentagonal bipyramidal Capped trigonal prismatic Capped octahedral

  23. Examples of coordination number 7

More Related