Selenium dioxide has a bent molecule.
The bond angle of SeO2 is approximately 120 degrees. This is because the molecule follows a trigonal planar molecular geometry, with the lone pairs of electrons repelling the bonding pairs slightly, decreasing the bond angle from the ideal 120 degrees.
The molecular geometry of a nitrogen molecule is linear.
All molecules have dispersion forces. SeO2, however, is polar, with a 120-degree O-Se-O bond angle (you need only apply VSEPR). So there are dipole-dipole interactions, which are far more powerful than dispersion forces. If ions are present, ion-dipole interactions can occur as well.
The molecular geometry of the CF3H molecule, based on its Lewis structure, is trigonal pyramidal.
A molecule with a tetrahedral geometry has four atoms bonded to a central atom in a symmetrical arrangement, while a molecule with a trigonal pyramidal geometry has three atoms bonded to a central atom in a triangular shape with one lone pair of electrons.
Trigonal Planar
The bond angle of SeO2 is approximately 120 degrees. This is because the molecule follows a trigonal planar molecular geometry, with the lone pairs of electrons repelling the bonding pairs slightly, decreasing the bond angle from the ideal 120 degrees.
Yes, SeO2 has covalent bonds. Selenium dioxide (SeO2) is a chemical compound composed of selenium and oxygen atoms that share electrons in covalent bonds to form a stable molecule.
The molecular geometry of a nitrogen molecule is linear.
The electron geometry of a water molecule is tetrahedral even though the molecular geometry is _____. Bent
All molecules have dispersion forces. SeO2, however, is polar, with a 120-degree O-Se-O bond angle (you need only apply VSEPR). So there are dipole-dipole interactions, which are far more powerful than dispersion forces. If ions are present, ion-dipole interactions can occur as well.
Molecular geometry will be bent, electron geometry will be trigonal planar
electron-pair geometry is octahedral with no LPs and the molecule geometry is octahedral
To determine the structural geometry of a molecule, structural pair geometry must be used. These are the amounts of pairs found surrounding a specific molecule, and they are unique to each type of atom.
tetrahedron
trigonal planar
The molecular geometry of the CF3H molecule, based on its Lewis structure, is trigonal pyramidal.