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Trigonal Bipyramidal
the electron pair geometry would be trigonal planar because there is a lone pair on the oxygen atom. The molecular pair geometry would be bent
PH3 has 3 bonding pairs and 1 non-bonding pair of electrons. Its electron pair geometry is Tetrahedral and its molecular geometry is Trigonal Pyramidal.
The electron pair geometry for CS2 is Linear.
The molecular geometry of H3O+ is Trigonal Pyramidal because it has 3 bonding pairs and 1 nonbonding pair (lone pair)
I'm unsure what the electron pair geometry is but the molecular geometry is Trigonal Planar.
electron pair geometry: octahedral molecular geometry: octahedral
Check the link, it is a sheet describing the different types of electron and molecular geometry. It helped me a lot. ^^ electron pair geometry and molecular geometry won't be the same if there are lone pairs involved.
Trigonal Bipyramidal
the electron pair geometry would be trigonal planar because there is a lone pair on the oxygen atom. The molecular pair geometry would be bent
Same as its molecular shape; tetrahedral.
VSEPR is valence spin electron pair repulsion, and helps in describing the electron domain geometry and the molecular geometry of a substance.
PH3 has 3 bonding pairs and 1 non-bonding pair of electrons. Its electron pair geometry is Tetrahedral and its molecular geometry is Trigonal Pyramidal.
The electron pair geometry for CS2 is Linear.
It is POLAR because although the electron-domain geometry is octehedral and the molecular geometry is sq. pyrimidal, there is a pair of extra electron on Cl , forcing the actual molecular sketch to have a "bubble-like" appearance to show the extra pair of electrons that are sitting dormant on Cl... Hope this helps!!
The molecular shape is square pyramidal because it has five ligands and one lone pair and the bond angle are 90,<120. Also, it has no dipole moment and the electron group geometry is octahedral.
Trigonal pyramidal. As has 5 valence electrons. It forms single bonds with each of the F atoms, donating one electron to each bond. This leaves 2 unbonded electrons, or a single lone pair. Thus the molecule has 4 different groups attached to As, and the electron configuration is tetrahedral. A tetrahedral configuration with one lone pair results in a trigonal pyramidal molecular geometry.