Molecular NI3 (see below) would be expected to have a small dipole, the inermolecular force would include dipole- dipole interactions along with London dispersion forces which would be expected to be relatively high as the molecule has a lot of electrons, 166 in all
Interestingly NI3 cannot be made pure, it is just too unstable. So the question is really just a theoretical one. Solid NI3 is actually an ammonia adduct and some brave person determined the crystal structure to be polymeric (NI3.NH3)n
LiNO3 is a white crystalline solid.
The intermolecular force in BF3 is London dispersion forces. This is because BF3 is a nonpolar molecule, so the only intermolecular force it experiences is the temporary weak attraction between temporary dipoles.
The chemical symbol for lithium nitrate is LiNO3.
In the case of a covalent bond, the intramolecular force is stronger than the intermolecular force. The covalent bond holds atoms together within a molecule, while intermolecular forces are weaker interactions between molecules.
The intermolecular force between BF3 molecules in liquid state is London dispersion forces. This is because BF3 is a nonpolar molecule and London dispersion forces are the primary intermolecular force among nonpolar molecules.
intermolecular force
This is an intermolecular force.
Boiling point is a property not a force; but a high boiling point indicate a strong intermolecular force.
Gravity!
LiNO3 is a white crystalline solid.
Intermolecular attraction
The intermolecular force in Ar (argon) is London dispersion forces, which are the weakest type of intermolecular force. This force is caused by temporary fluctuations in electron distribution around the atom, leading to temporary dipoles.
Intramolecular forces are not intermolecular forces !
The intermolecular force in BF3 is London dispersion forces. This is because BF3 is a nonpolar molecule, so the only intermolecular force it experiences is the temporary weak attraction between temporary dipoles.
The chemical symbol for lithium nitrate is LiNO3.
Intermolecular forces shown by the dotted lines not by strong covalent bonds.
Hydrogen bonds