tetrahedral
The molecular geometry around a central atom is the same as the electron group geometry when there are no lone pairs of electrons on the central atom. In such cases, all electron groups (bonding pairs) are arranged symmetrically around the atom, leading to identical geometries. This typically occurs in molecules with linear, trigonal planar, or tetrahedral arrangements, depending on the number of bonding pairs.
The central atom in selenium sulfide has a bent molecular geometry due to the presence of two lone pairs on the selenium atom. This results in a distorted tetrahedral arrangement around the selenium atom.
Aluminium chloride (AlCl3) has one aluminium atom (Al) and three chlorine atoms (Cl). The chemical formula AlCl3 indicates that there is one aluminium atom bonded to three chlorine atoms in the compound.
The electron pair geometry of each carbon atom in an alkane is tetrahedral. This is because each carbon atom is bonded to four other atoms, which results in a geometry where the electron pairs are distributed in a tetrahedral arrangement around the carbon atom.
Repulsion affect the geometry of a molecule.
The geometry of Methane (CH4) is tetrahedron or tetrahedral
electron pair geometry: octahedral molecular geometry: octahedral
The molecular geometry around a central atom is the same as the electron group geometry when there are no lone pairs of electrons on the central atom. In such cases, all electron groups (bonding pairs) are arranged symmetrically around the atom, leading to identical geometries. This typically occurs in molecules with linear, trigonal planar, or tetrahedral arrangements, depending on the number of bonding pairs.
Cat.
The central atom in selenium sulfide has a bent molecular geometry due to the presence of two lone pairs on the selenium atom. This results in a distorted tetrahedral arrangement around the selenium atom.
Aluminium chloride (AlCl3) has one aluminium atom (Al) and three chlorine atoms (Cl). The chemical formula AlCl3 indicates that there is one aluminium atom bonded to three chlorine atoms in the compound.
Octahedral
tetrahederal
The electron pair geometry of each carbon atom in an alkane is tetrahedral. This is because each carbon atom is bonded to four other atoms, which results in a geometry where the electron pairs are distributed in a tetrahedral arrangement around the carbon atom.
electron-group geometry
The electronic geometry about the carbon atom is: tetrahedral The orbital hybridization about the carbon atom is: sp^3 The molecular geometry about the carbon atom is: tetrahedral
The molecular geometry of carbon tetrabromide is tetrahedral. The sp3 hybridization of the carbon atom forms four equivalent sp3 hybrid orbitals arranged in a tetrahedral geometry around the central carbon atom.