The molecular orbital theory can predict the geometry of a compound.
Therefore you may bond order from the occupation of the molecular orbitals calculate and see whether a molecule paramagnetic or diamagnetic .
The sample of hydrogen fluoride is the simplest example. Connections between elements of the second period are themselves still relatively simple. It becomes difficult when elements from different periods.
If two compounds have the same MO scheme, it is called these two compounds isoelectronic to each other.
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Themolecular orbital theory can predict the geometry of a compound.
Therefore you may bond order from the occupation of the molecular
orbitals calculate and see whether a molecule paramagnetic or
diamagnetic .
The sample of hydrogen fluoride is the simplest example. Connections
between elements of the second period are themselves still relatively
simple. It becomes difficult when elements from different periods.
If two compounds have the same MO scheme, it is called these two compounds isoelectronic to each other.
============================ ===============================================================
Themolecular orbital theory can predict the geometry of a compound.
Therefore you may bond order from the occupation of the molecular
orbitals calculate and see whether a molecule paramagnetic or
diamagnetic .
The sample of hydrogen fluoride is the simplest example. Connections
between elements of the second period are themselves still relatively
simple. It becomes difficult when elements from different periods.
If two compounds have the same MO scheme, it is called these two compounds isoelectronic to each other.