NaCl
Boron trifluoride (BF3) is not a resonance structure; it is a stable molecule with a trigonal planar geometry. In BF3, boron has only six electrons in its valence shell, resulting in an incomplete octet, which is characteristic of certain compounds involving elements from the third period and beyond. While BF3 does not have resonance structures, it can act as a Lewis acid by accepting a pair of electrons.
This is a compound, a molecule.
The traditional answer is molecule. However, it is not now usual to refer to a formula unit of an ionic compound in this way.
The smallest unit of a compound is a molecule (MOLL-uh-kule)
BF3 is the ionic compound Boron trifluoride.
It is Boron trifluoride
its a covalent compound bcuz boron is an non - metal
The covalent compound formula of boron trifluoride is BF3.
BF3 forms covalent bonds. In BF3, the boron atom shares its three valence electrons with three fluorine atoms, resulting in a molecule held together by strong covalent bonds. Ionic bonds involve the transfer of electrons from one atom to another, which is not the case in BF3.
BF3 is a common boron compound and is neither a fat or a lipid which are the same thing
BF3 is a nonpolar molecule because the boron atom is surrounded by three fluorine atoms arranged in a trigonal planar geometry, creating a symmetric distribution of charge that cancels out any dipole moment.
NH3 is ammonia, a compound with one nitrogen atom and three hydrogen atoms. BF3 is boron trifluoride, a compound with one boron atom and three fluorine atoms. Together, NH3 and BF3 can react to form a compound called ammonia-borane.
The simplest formula for the compound formed between boron and fluorine would be BF3, which is boron trifluoride. Boron typically forms compounds by sharing 3 electrons with each fluorine atom, resulting in a molecule with a boron atom at the center and three fluorine atoms surrounding it.
The compound is boron trifluoride, with the chemical formula BF3.
The covalent compound formula for boron trifluoride is BF3, where one boron atom is bonded to three fluorine atoms through covalent bonds.
Hybridization in the molecule BF3 is significant because it helps explain the molecular geometry and bonding in the molecule. In BF3, boron undergoes sp2 hybridization, forming three equivalent sp2 hybrid orbitals that overlap with the 2p orbitals of fluorine atoms to create three strong sigma bonds. This hybridization allows for the trigonal planar shape of the molecule, with 120-degree bond angles between the fluorine atoms.