5 Must Know Facts For Your Next Test

1. Phosphorus pentachloride has a trigonal bipyramidal molecular geometry, with the phosphorus atom at the center and the five chlorine atoms arranged in a trigonal bipyramid.
2. The phosphorus atom in phosphorus pentachloride exhibits $sp^3d$ hybridization, with the three equatorial chlorine atoms in $sp^2$ hybrid orbitals and the two axial chlorine atoms in $sp^3$ hybrid orbitals.
3. Phosphorus pentachloride is a Lewis acid, meaning it can accept electron pairs from other molecules or ions, and is commonly used as a dehydrating agent and a chlorinating agent in organic synthesis.
4. When phosphorus pentachloride reacts with water, it undergoes hydrolysis to form phosphoric acid (H3PO4) and hydrogen chloride (HCl).
5. The trigonal bipyramidal geometry of phosphorus pentachloride is an example of the VSEPR (Valence Shell Electron Pair Repulsion) theory, which explains the shapes of molecules based on the number of electron pairs around the central atom.

Review Questions

• Explain the hybridization of the phosphorus atom in phosphorus pentachloride and how it relates to the molecule's trigonal bipyramidal geometry.
  • The phosphorus atom in phosphorus pentachloride exhibits $sp^3d$ hybridization, with the three equatorial chlorine atoms occupying $sp^2$ hybrid orbitals and the two axial chlorine atoms occupying $sp^3$ hybrid orbitals. This hybridization pattern allows the phosphorus atom to accommodate the five bonding pairs of electrons and adopt a trigonal bipyramidal molecular geometry, where the chlorine atoms are arranged in a triangular base with two additional chlorine atoms positioned at the apices of the bipyramid.
• Describe the Lewis acid-base behavior of phosphorus pentachloride and how it relates to its use as a dehydrating agent and chlorinating agent in organic synthesis.
  • Phosphorus pentachloride is a Lewis acid, meaning it can accept electron pairs from other molecules or ions. This property allows it to act as a dehydrating agent, where it can remove water from organic compounds by forming a covalent bond with the oxygen atom of water, producing phosphoric acid and hydrogen chloride. Additionally, the Lewis acidic nature of phosphorus pentachloride enables it to be used as a chlorinating agent in organic synthesis, where it can introduce chlorine atoms into organic molecules by replacing other functional groups or atoms.
• Analyze the role of VSEPR theory in understanding the trigonal bipyramidal geometry of phosphorus pentachloride and how this geometry influences the molecule's chemical properties and reactivity.
  • The trigonal bipyramidal geometry of phosphorus pentachloride is a direct consequence of the VSEPR theory, which states that the arrangement of electron pairs around a central atom will adopt a geometry that minimizes the repulsion between these electron pairs. In the case of phosphorus pentachloride, the five bonding pairs of electrons around the phosphorus atom are distributed in a way that results in the trigonal bipyramidal arrangement, with the chlorine atoms occupying the available positions. This specific geometry affects the molecule's chemical properties, such as its Lewis acidic behavior and its reactivity in organic synthesis, where the arrangement of the atoms and the distribution of electron density play a crucial role in determining the molecule's reactivity and the outcomes of its chemical transformations.

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