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Ch 5 Lecture 2 Complex MOs

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New group orbitals are then overlapped with central atom AO's ... H(1s) orbital on central atom only has 2 possibilities to combine with F GO's ... – PowerPoint PPT presentation

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Title: Ch 5 Lecture 2 Complex MOs


1
Ch 5 Lecture 2 Complex MOs
  • MOs from d-orbitals
  • Transition metals and other heavy elements use
    d-orbitals in their bonding interactions
  • d-orbitals may form s, p, or d bonds
  • A s example is
  • the dz2/dz2 interaction
  • b) A p example is
  • the dyz/dyz interaction
  • c) A d example is
  • the dxy/dxy interaction
  • d) d bonds change signs upon
  • C4 rotation around the internuclear axis

2
  • Examples
  • Heteronuclear Diatomics
  • Polar Bonds
  • MO pattern is same as homonuclear
  • One set of AOs will be at a lower energy than
    the other
  • Valence Orbital Potential Energy
  • Negative energies of attraction of e- to the
    nucleus
  • Averaged for all e- on the same level (3p)
  • As Z increases left to right, VOPE becomes larger

3
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4
  • The LCAO for heteronuclear diatomics
  • uses different coefficients because the energies
  • of the 2 atoms are no longer identical
  • Y caYa cbYb (ca ? cb)
  • The AO closest in energy to the MO
  • contributes most to it
  • In CO the 2s MO is mostly O
  • The 2s MO is mostly C
  • The shape and energy of the MO
  • is similar to the major contributing AO
  • If DE gt 12 eV, there can be no interaction
  • For CO, BO 3
  • Mixing is still important

5
  • HOMO and LUMO
  • Molecular reactivity occurs at the Frontier
    Orbitals
  • HOMO Highest Occupied Molecular Orbital
  • LUMO Lowest Unoccupied Molecular Orbital
  • MO Theory helps explain some observations about
    these orbitals
  • In CO, O is the most electronegative
  • We would expect the d- oxygen end to bond to M
  • Bonding MOs are generally concentrated on the
    lower energy atom, but symmetry considerations
    put HOMO on C in this case
  • The HOMO 3s is concentrated on C
  • Carbonyls bind metals through the carbon atom
  • Antibonding MOs are generally on the highest
    energy atom
  • The LUMO 1p is concentrated on C
  • This orbital can receive e- back from M,
    strengthening MC bond

6
  • Ionic Compounds
  • This is the limit of polarity
  • e- completely donated from one atom to another,
    which becomes charged
  • The ion then has higher energy vacant orbitals
  • Example LiF
  • Li 2s donates e- to the F 2pz
  • In the MO description, these are the 2 orbitals
    of correct symmetry to interact
  • The energy difference is gt 12 eV
  • The MO picture looks similar to a covalent
    interaction

7
  • MOs for larger molecules
  • FHF-
  • Consider separately the central atom and its
    outer atoms
  • Group Orbital SALC (symmetry adapted linear
    combination)
  • Combine orbitals of outer atoms with same
    symmetry
  • New group orbitals are then overlapped with
    central atom AOs
  • Same combinations as in F2, but separated by a
    central atom (dot)
  • Each combination produces bonding type and
    antibonding type GOs

8
  • H(1s) orbital on central atom only has 2
    possibilities to combine with F GOs
  • Combine for best overlap to give bonding MOs
  • Must be correct symmetries to overlap
  • Must be correct energies
  • H(1s) cant overlap with GO 1(F2s) right
    symmetry, wrong energy
  • H(1s) can overlap with GO 3 (F2pz) right
    symmetry and energy

9
  • None of the other F GOs are of appropriate
    symmetry to interact with H(1s)
  • Sketching the MO diagram
  • Central atom on left
  • 7 F GOs are nonbonding
  • (lone pairs)
  • GO 3/ H(1s) give bonding
  • and antibonding MOs
  • Bonding Description
  • Lewis
  • MO better
  • 3 center 2 e- bond

10
  • CO2
  • The group orbitals for O O are the same as for
    F F
  • The central C has filled s and p orbitals to use
    in bonding
  • Use symmetry to find out which orbitals will
    interact with O GOs
  • CO2 is in the D8h point group, which is hard to
    work with
  • We will use D2h character table as a
    simplification
  • O O group orbitals
  • with D2h symetry labels

11
  • Carbon AOs with D2h symmetry labels
  • Interactions of C AOs and O GOs
  • O GO 1(2s) interacts with C(1s) in Ag symmetry
  • O GO 2(2s) interacts with C(2pz) in B1u symmetry

12
  • O GO3(2pz) interacts with C(2s) in Ag symmetry

13
  • Energy of interactions
  • Which of the above 4 interactions are
    energetically permissible?
  • Interactions are strongest for orbitals of
    similar energies
  • Energy match for O GO3(2pz)/C(2s)
    -15.9eV/-19.5eV is good
  • Energy match for O GO1(2s)/C(2s)
    -32.4eV/-19.5eV is bad
  • Energy match for O GO4(2pz)/C(2pz) -15.9/-10.7
    is good
  • Energy match for O GO2(2s)/C(2pz)
    -32.4eV/-10.7eV is bad
  • O GOs 1 and 2 will not be involved in MOs

14
  • Additional Favorable Interactions
  • O GO5(2py) and C(2py) interact in B2u symmetry
  • O GO7(2px) and C(2px) interact in B3u symmetry
  • O GO6 (B3g) and O GO8 (B2g) have no C orbitals
    to interact with

15
  • 7) Final CO2 MO Diagram
  • 16 valence e-
  • 2 Bonding s MO
  • 2 nonbonding s MO
  • 2 bonding p MO
  • 2 nonbonding p MO
  • BO 4 (2s, 2p)
  • All Bonding MOs are
  • 3 centered 2 electron bonds
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