Predicting the Geometry and Polarity of CS₂ Molecule

What is the geometry of the CS₂ molecule and why is it considered nonpolar?

The CS₂ molecule has a linear geometry, with a carbon atom bonded to two sulfur atoms through double bonds. It is a nonpolar molecule because the symmetric arrangement of the atoms cancels out any dipole moments, resulting in no overall polarity.

Geometry of CS₂ Molecule

The CS₂ molecule, also known as carbon disulfide, consists of a central carbon atom (C) bonded to two sulfur atoms (S) through double bonds. To predict the geometry of CS₂, we can use the VSEPR (Valence Shell Electron Pair Repulsion) theory. In CS₂, the carbon atom is surrounded by two regions of electron density due to the double bonds with sulfur. According to VSEPR theory, this arrangement results in a linear molecular geometry. The two sulfur atoms are positioned on opposite sides of the carbon atom, forming a straight line.

Polarity of CS₂ Molecule

Regarding polarity, the CS₂ molecule is nonpolar. While the sulfur atoms are more electronegative than carbon, the molecule's linear geometry ensures that the bond polarities cancel each other out. The electronegativity difference between carbon and sulfur is not sufficient to create a dipole moment. As a result, CS₂ does not possess a net dipole moment and is considered nonpolar. Therefore, the geometry of CS₂ is linear, and the molecule is nonpolar.
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