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9.S: Chemical Bonding in Diatomic Molecules (Summary)

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    • While not 100% accurate, molecular orbital theory provides intuitive and qualitative picture of bonding.
    • When atomic orbitals overlap, they can do so in-phase (bonding orbitals) or out-of-phase (antibonding orbitals).
    • Net stabilization occurs when atomic orbitals overlap in-phase from an “exchange integral” term– purely quantum-mechanical effect.
    • Many atomic orbitals can be combined to produce bonding, antibonding, and non-bonding orbitals (LCAO–MO); these can be sorted by energy and filled in like atomic orbitals.
    • Antibonding orbitals have nodal planes perpendicular to the internuclear axis.
    • Bond order is estimated as the number of electrons in bonding orbitals minus number of electrons in antibonding orbitals, all divided by two. A bond order of 0 means that the bond is not predicted to be stable.
    • \(\sigma\) orbitals are cylindrically symmetric about the internuclear axis, \(\pi\) orbitals have one nodal plane along the internuclear axis, \(\delta\) orbitals have two nodal planes along the internuclear axis, etc...
    • Molecular term symbols, like atomic term symbols, describe electron configurations. \(L\) is replaced by a Greek letter \(\Lambda\) in a molecular term symbol, and the \(2J+1\) is gone because the total angular momentum now depends on the rotational state of the molecule in addition to the electron angular momentum.
    • For homonuclear diatomics, the parity subscripts \(g\) and \(u\) tell whether the wavefunction is centrosymmetric (\(g\) is, \(u\) is not).
    • For \(\Sigma\) states, a superscript \(+/-\) indicates the symmetry with respect to a plane containing the internuclear axis. This only applies when \(\pi\) or higher MOs are involved. For each set of degenerate \(\pi\) MOs, one is symmetric and the other is not, so the net symmetry can be calculated by looking at the number of singly-occupied \(\pi\) orbitals. Similar logic applies for the \(\delta\) and higher orbitals.

    This page titled 9.S: Chemical Bonding in Diatomic Molecules (Summary) is shared under a not declared license and was authored, remixed, and/or curated by Kyle Crabtree.

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