Is SiCl4 polar or nonpolar? - Polarity of SiCl4

SiCl₄ is the chemical formula of silicon tetrachloride. It is a colorless volatile liquid that fumes in the air. It is used to produce high-purity silicon and silica for commercial applications. SiCl₄ has a molar mass of 169.9 g/mol.

If you have a query regarding the polarity of the silicon tetrachloride (SiCl₄) molecule and want to know whether it is polar or non-polar, you are at the right place.

So, let’s get started.

Is SiCl₄ polar or non-polar?

Silicon tetrachloride (SiCl₄) is a non-polar molecule. It consists of one silicon (Si) atom and four chlorine (Cl) atoms. The silicon is kept at the central position while all four chlorine atoms occupy surrounding positions, making a perfectly symmetrical tetrahedral molecular shape and geometry.

An electronegativity difference of 1.26 units exists between the bonded atoms of silicon and chlorine in each Si-Cl bond in SiCl₄. Thus, each Si-Cl bond is individually polar in SiCl₄ and possesses a specific dipole moment value (symbol µ).

In the SiCl₄ molecule, the highly electronegative chlorine atom more strongly attracts the shared electron cloud from each Si-Cl bond.

However, as no lone pair of electrons is present on the central silicon atom, thus, the charged electron cloud stays uniformly distributed overall.

Due to the symmetrical tetrahedral shape of the SiCl₄ molecule, the dipole moments of individually polar Si-Cl bonds get canceled equally. As a result, the SiCl₄ molecule is overall non-polar (net µ = 0).

Name of molecule	Silicon tetrachloride (SiCl4)
Bond type	Polar covalent
Molecular geometry	Tetrahedral
Polar or Non-polar?	Overall non-polar molecule
Dipole moment	0
Bond angle	∠Cl-Si-Cl= 109.5°

What makes a molecule polar or non-polar?

A molecule is polar if there is a non-uniform charge distribution present in it.

If the charge distribution gets equally balanced in different parts, then that molecule or molecular ion is considered non-polar.

The following three factors mainly influence the polarity of a molecule:

• The electronegativity difference between two or more covalently bonded atoms
• Dipole moment
• Molecular geometry or shape

Now, let us discuss the effect of the above three factors one by one to prove that the silicon tetrachloride (SiCl₄) is overall a non-polar molecule.

Factors affecting the polarity of SiCl₄

Electronegativity

It is defined as the ability of an atom to attract a shared pair of electrons from a covalent chemical bond.  

Electronegativity decreases down the group in the Periodic Table of elements while it increases across a period.

Greater the electronegativity difference between bonded atoms in a molecule, the higher the bond polarity.

Silicon (Si) is present in Group 14 of the Periodic Table. The electronic configuration of silicon is 1s² 2s² 2p⁶ 3s² 3p². As per the electronic configuration, a Si-atom has a total of 4 valence electrons; it is thus short of 4 more electrons that are required so that the silicon atom can achieve a complete octet electronic configuration.

Conversely, chlorine (Cl) is present in Group 17 of the Periodic Table. The electronic configuration of a chlorine atom is 1s² 2s² 2p⁶ 3s² 3p⁵. As per this electronic configuration, a Cl-atom has a total of 7 valence electrons; it is thus short of one valence electron that is required so that the chlorine atom can achieve a complete octet electronic configuration.

The Lewis dot structure of SiCl4 shows that there are four Si-Cl bonds. All four valence electrons of silicon used in covalent bonding denote there is no lone pair of electrons present on the central Si-atom in SiCl4. Contrarily each terminal Cl-atom contains 3 lone pairs of electrons. In this way, all bonded atoms attain a completely stable octet electronic configuration via lone pairs and chemical bonding in SiCl4.

Due to the absence of any lone pair of electrons on the central Si-atom in SiCl₄, there is no distortion in the symmetrical tetrahedral shape or geometry of the molecule.

Atom	Electronic configuration	Valence electrons
Silicon (14Si)	1s2 2s2 2p6 3s2 3p2	4
Chlorine (17Cl)	1s2 2s2 2p6 3s2 3p5	7

The electronegativity difference in SiCl₄ between Si-atom (E.N= 1.90) and Cl-atom (E.N= 3.16) in each of the four Si-Cl bonds is 1.26 units.

Hence, the chlorine atom with relatively higher electronegativity gains a partial negative (Cl^δ-) charge while the silicon atom obtains a partial positive (Si^δ+) charge (as shown below).

As a result, in SiCl₄, all Si-Cl bonds are individually polar with an electronegativity difference of 1.26 units.

Dipole Moment

Dipole moment (μ) is a vector quantity that points from the positive pole to the negative pole of a bond or a molecule.

It is mathematically calculated as a product of the magnitude of charge (Q) and charges separation (r). The dipole moment is expressed in a unit called Debye (D).

The dipole moment of a polar covalent bond conventionally points from the positive center to the center of the negative charge.

So in polar bonds of SiCl₄, the dipole moment of each Si-Cl bond points from Si^δ+ to Cl^δ- (as shown below).

Molecular geometry

According to the valence shell electron pair (VSEPR) theory of chemical bonding, SiCl₄ is an AX₄E₀ or simple AX₄-type molecule. To one Si-atom at the center (A), four bonded atoms (X) are attached (four Cl-atoms), and the central Si-atom contains no lone pair of electrons (E).

The molecular geometry or shape of SiCl₄ is tetrahedral, which is identical to its electron pair geometry. To minimize bond pair-bond pair repulsions and to attain stability in the tetrahedral structure, the bonded atoms of the SiCl₄ molecule possess a mutual bond angle of (∠Cl-Si-Cl) 109.5°.

Due to the absence of any lone pair of electrons on the central Si-atom, SiCl₄ has an identical molecular and electron geometry that is tetrahedral.

Highly electronegative Cl-atoms attract the shared cloud of each Si-Cl to a large extent. Hence, the Si-Cl bonds are individually polar.

 Still, due to the symmetrical tetrahedral shape of SiCl₄, the overall charged electron cloud stays uniformly distributed as the Si-Cl dipole moments get canceled equally in the molecule.

The net dipole moment of three downwards-pointing Si-Cl bonds gets canceled with the dipole moment of an upwards-pointing Si-Cl bond. Consequently, silicon tetrachloride (SiCl₄) is overall a non-polar molecule (net µ = 0).

Difference between polar and nonpolar?

Polar molecule	Non-polar molecule
Atoms must have a difference in electronegativity	Atoms may have the same or different electronegativity values
Unequal charge distribution overall	Equal charge distribution overall
Net dipole moment greater than zero	Net dipole moment equals to zero
Examples include water (H2O), ethanol (CH3CH2OH), ammonia (NH3), sulfur dioxide (SO2), bromine trifluoride (BrF3), nitric oxide (NO), carbonyl sulfide (OCS or COS), etc.	Examples include oxygen (O2), nitrogen (N2), methane (CH4), ethane (C2H6), propane (C3H8), ethyne (C2H2), silicon dioxide (SiO2), silane (SiH4), silicon tetrachloride (SiCl4), etc.

Also, check –

• SiCl₄ lewis structure, molecular geometry, bond angle, hybridization
• How to determine if a molecule is polar or nonpolar?
• Is CH₂Cl₂ polar or nonpolar?
• Is CH₃F polar or nonpolar?
• Is NCl₃ polar or nonpolar?
• Is NO₃^– polar or nonpolar?
• Is BrF₅ polar or nonpolar?
• Is SF₄ polar or nonpolar?
• Is CO₂ polar or nonpolar?
• Is NH₃ polar or nonpolar?
• Is SO₂ polar or nonpolar?
• Is SO₃ polar or nonpolar?
• Is H₂O polar or nonpolar?
• Is H₂S polar or nonpolar?
• Is HCN polar or nonpolar?
• Is CCl₄ polar or nonpolar?
• Is XeF₄ polar or nonpolar?
• Is CH₂O polar or nonpolar?
• Is CHCl₃ polar or nonpolar?
• Is SF₆ polar or nonpolar?
• Is BF₃ polar or nonpolar?
• Is PCl₅ polar or nonpolar?
• Is CH₃Cl polar or nonpolar?

FAQ

Why is SiCl4 a non-polar molecule?

SiCl4 has four Si-Cl bonds. The electronegativity difference between the bonded Si-atom (E. N= 1.90) and Cl-atom (E. N= 3.16) is 1.26 units. Therefore, the Cl-atom gains a partial negative (Clδ-) charge while the central Si-atom obtains a partial positive (Siδ+) charge. Each Si-Cl bond thus possesses a particular dipole moment Hence, each Si-Cl bond in SiCl4 is individually polar. However, it is due to the symmetrical tetrahedral shape of SiCl4 that the individual Si-Cl dipole moments get canceled. The electron cloud stays uniformly distributed in the molecule overall. Thus, SiCl4 is overall a non-polar molecule with µ = 0.

SiCl4 contains polar bonds but is more soluble in a non-polar solvent. Why?

In SiCl4, each Si-Cl bond is polar due to an electronegativity difference of 1.26 units between the bonded Si-atom (E. N= 1.90) and Cl-atom (E. N= 3.16). Still, as it has a symmetrical tetrahedral molecular geometry, the dipole moments of individually polar Si-Cl bonds get canceled, making SiCl4 molecule overall non-polar. Hence, non-polar SiCl4 is soluble in non-polar solvents as per the concept of like dissolves like.

Which one out of these is a polar molecule? i) CCl4 , ii) SiCl4  and iii) SiH4

All the above molecules are non-polar. i) Tetra chloromethane (CCl4) has four polar C-Cl bonds due to an electronegativity difference of 0.61 units between the bonded atoms. ii) Silicon tetrachloride (SiCl4) has an electronegativity difference of 1.26 units between a silicon and chlorine atom. iii) Silicon tetrahydride (SiH4) has a small electronegativity difference of 0.3 units between a silicon and a hydrogen atom. However, all the above three molecules possess a symmetrical tetrahedral shape and geometry. Thus the dipole moments of individually polar bonds get uniformly canceled on each side of the molecule. The overall charged electron cloud stays uniformly spread, leading to a net dipole moment µ = 0.

Why is NH3 polar while SiCl4 is a non-polar molecule?

NH3 is made up of three polar N-H bonds with an electronegativity difference of 0.84 units between the bonded atoms. NH3 possesses an asymmetrical trigonal pyramidal shape. Thus the dipole moments of individually polar N-H bonds do not get canceled uniformly, and NH3 is overall polar (net µ = 1.46 D). Contrarily, SiCl4 has a symmetrical tetrahedral shape and geometry. The dipole moments of individually polar Si-Cl bonds get canceled uniformly on each side of the molecule. It is thus overall non-polar (net µ = 0).

Is there a formal charge on the bonded atoms in the SiCl4 molecule?

Formal charge of an atom = [ valence electrons – non-bonding electrons- ½ (bonding electrons)] For the central Si-atom Valence electrons = 4 Bonding electrons = 8 Non-bonding electrons = 0 ∴ Formal charge on central Si-atom = 4 – 0 – 8/2 = 4 – 0 – 4 = 4 – 4 = 0 For Cl-atoms Valence electrons = 7 Bonding electrons = 2 Non-bonding electrons = 6 ∴ Formal charge on each Cl-atom = 7 – 6 – 2/2 = 7 – 6 – 1 = 7 – 7 = 0 All atoms in the SiCl4 molecule including silicon and chlorine obtain a formal charge equal to zero. Hence, the overall charge present on the silicon tetrachloride molecule is zero.

Summary

• Silicon tetrachloride (SiCl₄) is a non-polar molecule.
• It consists of four Si-Cl bonds.
• Si-Cl bonds are highly polar with an electronegativity difference of 1.26 units between the bonded Si-atom (E.N = 1.90) and Cl-atom (E.N = 3.16).
• SiCl₄ has a tetrahedral molecular and electron geometry with a mutual bond angle of (∠Cl-Si-Cl) 109.5°.
• Due to the absence of any lone pair of electrons on the central Si-atom, the SiCl₄ molecule has a symmetrical tetrahedral molecular shape.
• In SiCl₄, there is a net zero dipole moment in the molecule.
• The net dipole in SiCl₄ is µ = 0, so silicon tetrachloride is overall a non-polar molecule.